ARTIFICIAL SYNAPSES

SEQUENCE LISTING

This application contains a Sequence Listing which has been submitted electronically in XML format and is hereby incorporated by reference in its entirety. Said XML copy, created on Jan. 28, 2025, is named 69749_701_304_SL.xml and is 724,497 bytes in size.

FIELD OF THE INVENTION

This invention relates to the generation of artificial synapses or extracellular vesicles, including features of extracellular vesicles engineered to deliver signaling, for therapeutic use, including treatment of immune diseases and cancer.

BACKGROUND

Extracellular vesicles (EVs) play a critical role in intercellular communication by transferring microRNAs, lipids, and proteins to neighboring cells. The delivery of encapsulated molecules within EVs is a highly promising strategy as a therapeutic platform in many contexts, exploiting the unique biophysical and biochemical characteristics of extracellular vesicles (EVs). However, there remains a great need in the art for a flexible and dynamic platform, where specific biological signals can be reliably targeted without off-target effects and that provide a robust cellular response to achieve a therapeutic effect, such as modulating inflammation.

SUMMARY

The compositions and methods provided herein are based, in part, on the discovery that extracellular vesicles can be used to express engineered fusion polypeptides that can modulate biological signal generation. These engineered vesicles, also termed artificial synapses, adopt the hallmark biophysical and biochemical features of extracellular vesicles, but are further engineered with vesicle targeting domains (e.g., sticky binders) and signaling domains, optionally joined by a linker with specific functions. The fusion polypeptides provided herein are designed and produced as nucleic acid constructs (e.g., vectors) and expressed in cells, such as mammalian cells. In particular, the vesicle targeting domain of each fusion polypeptide anchors the polypeptide to the extracellular vesicle lipid membrane, thereby presenting the signaling domain(s) of the polypeptide. The signaling domains on or within the vesicle membrane can make contact with recipient cells via target polypeptides (e.g., receptors on the extracellular surface of the recipient cell). Importantly, this strategy can allow for kinetically favorable signal generation and signal propagation. This includes, for example, increasing density of agonist presentation to support receptor clustering of a target receptor located on a target cell—an onerous barrier for traditional receptor targeting strategies.

This strategy was applied to alter immune checkpoint signaling, by engineering artificial synapses through genetic constructs with lipid binding glycosylphosphatidylinositol (GPI) sticky binders joined with programmed death-ligand 1 (PD-L1) signaling domain, e.g., human programmed death-ligand 1 (hPD-L1), expressed in cells and capable of attachment to exosomes. Isolation, purification, and analysis of artificial synapses revealed a high density of signaling domains of the hPD-L1-GPI fusion polypeptide. The hPD-L1 artificial synapse exosomes further demonstrated enhanced agonist signaling than soluble PD-L1 ligand alone, supporting receptor clustering on a target cell. When applied to a model of experimental autoimmune uveoretinitis (EAU), a statistically significant reduction in EAU symptoms was observed.

Thus, in one aspect, provided herein is an engineered extracellular vesicle or artificial vesicle comprising: at least one fusion polypeptide comprising: at least one protein of interest (POI) domain; and at least one vesicle targeting domain. In some embodiments of any of the aspects, the engineered extracellular vesicle is an exosome. In some embodiments, of any of the aspects, the fusion protein further comprises at least one linker. In some embodiments of any of the aspects, the POI domain can substantially bind to a target polypeptide.

In another aspect, provided herein is an engineered extracellular vesicle comprising: at least one fusion polypeptide comprising:

- (i) at least one protein of interest (POI) domain or a fragment thereof; and
- (ii) at least one vesicle targeting domain, wherein the POI domain is in an extracellular position relative to a lipid membrane of the extracellular vesicle.

In another aspect, provided herein is an engineered extracellular vesicle comprising:

- (a) a first fusion polypeptide comprising:
  - (i) at least one protein of interest (POI) domain or a fragment thereof; and
  - (ii) at least one vesicle targeting domain, wherein the at least one POI domain is in an extracellular position relative to a lipid membrane of the extracellular vesicle,
- (b) a second fusion polypeptide comprising:
  - (i) at least one protein of interest (POI) domain or a fragment thereof; and
  - (ii) at least one vesicle targeting domain, wherein the POI domain is in an extracellular position relative to a lipid membrane of the extracellular vesicle, and wherein the at least one vesicle targeting domain is within a lipid membrane of the extracellular vesicle.

In another aspect, provided herein is an extracellular vesicle composition comprising: a plurality of artificial synapses,

- wherein each artificial synapse comprises (i) an extracellular vesicle; (ii) one or more sticky binders; and (iii) one or more signaling domains.

In another aspect, provided herein is a composition comprising a plurality of the engineered extracellular vesicles provided herein.

In another aspect, provided herein is a composition comprising two or more of the engineered extracellular vesicles provided herein.

In another aspect, provided herein is a composition comprising three or more of the engineered extracellular vesicles provided herein.

In another aspect, provided herein is a method of producing the engineered extracellular vesicle or the compositions provided herein, comprising:

- (a) providing a population of cells expressing a vector construct encoding one or more sticky binder and one or more signaling domains; and
- (b) isolating a plurality of artificial synapses from the population of cells.

In another aspect, provided herein is a method of producing the engineered extracellular vesicle or the compositions provided herein, comprising:

- (a) providing a population of cells expressing a vector construct encoding one or more sticky binder and one or more signaling domains; and
- (b) isolating a plurality of artificial synapses from the population of cells; and
- (c) purifying the plurality of artificial synapses from the population of cells.

In another aspect, provided herein is a method of modulating inflammation in a subject, the method comprising:

- administering a composition comprising a plurality of engineered extracellular vesicles to a subject in need thereof,
- wherein the engineered extracellular vesicles comprise at least one fusion polypeptide comprising:
  - (i) at least one protein of interest (POI) domain or a fragment thereof; and
  - (ii) at least one vesicle targeting domain.

In another aspect, provided herein is a use of a composition or engineered extracellular vesicle provided herein for the treatment of an inflammatory disease or condition.

In another aspect, provided herein is a use of a composition or engineered extracellular vesicle provided herein for the treatment of an autoimmune disease or condition.

In another aspect, provided herein is a use of a composition or engineered extracellular vesicle provided herein for the treatment of cancer.

In one embodiment of any of the aspects, the engineered extracellular vesicle is an exosome.

In another embodiment of any of the aspects, the protein of interest (POI) domain or a fragment thereof is a N-terminal domain of the fusion polypeptide. In another embodiment of any of the aspects, the POI domain is selected from the group consisting of: Table 1. In another embodiment of any of the aspects, the POI domain is PD-L1 or a fragment thereof. In another embodiment of any of the aspects, the POI domain is PD-L2 or a fragment thereof. In another embodiment of any of the aspects, the POI domain is FGL1 or a fragment thereof. In another embodiment of any of the aspects, the POI domain is 4-1BBL or a fragment thereof. In another embodiment of any of the aspects, the POI domain is CTLA-4 or a fragment thereof. In another embodiment of any of the aspects, the protein of interest (POI) domain is HVEM or a fragment thereof.

In another embodiment of any of the aspects, the vesicle targeting domain is a C-terminal domain of the fusion polypeptide. In another embodiment of any of the aspects, the vesicle targeting domain is in a luminal position relative to the lipid membrane of the extracellular vesicle. In another embodiment of any of the aspects, the vesicle targeting domain in an exterior position relative to the lipid membrane of the extracellular vesicle. In another embodiment of any of the aspects, the vesicle targeting domain is selected from the group consisting of: Table 3. In another embodiment of any of the aspects, the vesicle targeting domain is selected from the group consisting of: a Glycosylphosphatidylinositol (GPI) anchor, a fatty acetylation site, and a prenylation site. In another embodiment of any of the aspects, the vesicle targeting domain is C1C2. In another embodiment of any of the aspects, the vesicle targeting domain is a GPI anchor.

In another embodiment of any of the aspects, the fusion polypeptide comprises at least two POI domains and/or at least two exosome targeting domains.

In another embodiment of any of the aspects, the POI domain substantially binds to one or more of a target polypeptide. In another embodiment of any of the aspects, the target polypeptide is selected from the group consisting of: Table 2.

In another embodiment of any of the aspects, the fusion polypeptide further comprises a peptide linker. In another embodiment of any of the aspects, the fusion polypeptide further comprises a fragment crystallizable region (Fc) domain. In another embodiment of any of the aspects, the linker is in an exterior position relative to the lipid membrane of the extracellular vesicle. In another embodiment of any of the aspects, the linker is a transmembrane linker. In another embodiment of any of the aspects, the linker is in a luminal position relative to the lipid membrane of the extracellular vesicle.

In another embodiment of any of the aspects, the engineered extracellular vesicle does not comprise an endogenous POI polypeptide.

In another embodiment of any of the aspects, the composition further comprises a pharmaceutically acceptable carrier.

In another embodiment of any of the aspects, the one or more sticky binders or the vesicle targeting domain is selected from the group consisting of: a GPI anchor, a fatty acetylation site, and a prenylation site.

In another embodiment of any of the aspects, the signaling domain or the protein of interest comprises one or more of: PD-L1, PD-L2, CTLA-4 (CD152), 4-1BBL (CD137L), HVEM (CD270), FGL1, OX-2 (CD200), Galectin-9, PVR (CD155), Nectin-2 (CD1 12) isoform alpha, Nectin-2 (CD112) isoform beta, Nectin-2 (CD112) isoform delta, IL-10, TSG-6, B7-H3 (CD276), B7-14 (VTCN1), B7-H5 (VISTA), B7-H7 (HHLA2), BTNL1, VSIG8, VSIG3 (TGSF11), VSIG4, TIM-3 (HAVCR2), TIM-4 (TIMD4), CEACAM1, BTN3A1, BTN3A2, BTN2A1, BTNL8, BTN2A2, BTN1A1, TIGIT, CD27L (CD70), CD30L (CD153), GITRL, CD40L (CD154), LIGHT (CD258), TL1, CD80, CD86, LFA-3 (CD58), SLAM (CD150), CD40, CD28, CD28H, CD2, LFA-3 (CD58), CD48, CD226, DR3, DcR3, FasL, TIM-1 (CD365), PD-1, or active fragment thereof.

In another embodiment of any of the aspects, the isolating is via size exclusion chromatography. In another embodiment of any of the aspects, the purifying is via multimodal chromatography. In another embodiment of any of the aspects, the method further comprises performing an assay for POI binding to a target polypeptide.

In another embodiment of any of the aspects, the vector construct further encodes a promoter. In another embodiment of any of the aspects, the promoter is a tissue-specific promoter or an inducible promotor.

In one embodiment of any of the aspects, the method further comprises selecting a subject that has or is suspected of having an autoimmune disease or an inflammatory disease or condition. In another embodiment of any of the aspects, the inflammatory disease and/or condition is acute. In another embodiment of any of the aspects, the inflammatory related disease and/or condition is chronic.

In another embodiment of any of the aspects, administering the composition provided herein comprises injection, topical administration, or inhalation.

A BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows construct representation of fusion polypeptides for labeling an exosome surface with Type I membrane proteins.

FIG. 2A shows nucleic acid and translated protein sequences of full-length Phosphatidylserine binding: Lactadherin (MFGE8) C1C2. Underlined nucleic acid sequence highlights the sequence translated to the C1C2 protein. Bold and underlined text highlights the C1C2 domain used to anchor signaling domains of interest (i.e., PD-L1 extracellular domain) onto the surface of the Inventors' artificial synapses. FIG. 2B shows nucleic acid and translated protein sequences of full length CD55 (DAF) Glycosylphosphatidylinositol (GPI) anchor. Bold and underlined text highlights the GPI anchor domain used to anchor signaling domains of interest (i.e., PD-L1 extracellular domain) onto the surface of the Inventors' artificial synapses engineered from exosomes.

FIG. 3 demonstrates the nucleic acid and translated protein sequence for the Fc linker used in genetically engineered constructs is shown in bold and underlined.

FIG. 4A demonstrates nucleic acid and translated protein sequence of human PD-L1 (CD274). Bold and underlined sequence highlights the PD-L1 extracellular domain used in the Inventors' artificial synapses engineered from exosomes. FIG. 4B demonstrates nucleic acid and protein sequence of human PD-L2. Bold and underlined sequence highlights the PD-L2 extracellular domain used in the Inventors' artificial synapses engineered from exosomes. FIG. 4C shows mRNA and protein sequence of human CTLA-4 (CD152). Bold and underlined sequence highlights the CTLA-4 extracellular domain used in the Inventors' artificial synapses.

FIG. 5A shows an exemplary embodiment of pcDNA5-FRT cloning vector with a gene sequence coding for a fusion polypeptide inserted into a multiple cloning site. FIG. 5B shows an exemplary embodiment of the Gateway® destination vector pEF5-FRT-V5-DEST with a gene sequence coding for a fusion polypeptide inserted into a multiple cloning site. The vectors were used for constitutive high-level expression of fusion polypeptide described herein in mammalian cells. FIG. 5C shows the nucleic acid and protein sequence for the hCTLA4-Fc-GPI fusion polypeptide wherein the text for the signaling domain is bolded, Fc linker is underlined, and sticky binder is italicized. FIG. 5D shows the nucleic acid and protein sequence for the hPDL1-GPI-P2A-hHVEM-GPI fusion polypeptide wherein the text for the signaling domain hPDL1 and hHVEM are bolded, P2A sequence is underlined, and sticky binder GPI is italicized. With P2A included, a self-cleaving peptide sequence, artificial synapses with this feature will have both hPDL1-GPI and hHVEM-GPI loaded onto the surface. FIG. 5E shows the nucleic acid and protein sequence for the hPDL1-GPI-P2A-hFGL1-GPI fusion polypeptide wherein the text for the signaling domain hPDL1 and hFGL1 are bolded, P2A sequence is underlined, and sticky binder GPI is italicized. With P2A included, a self-cleaving peptide sequence, artificial synapses with this feature will have both hPDL1-GPI and FGL1-GPI loaded onto the surface. FIG. 5F shows the nucleic acid and protein sequence for the hPDL1-GPI fusion polypeptide wherein the text for the signaling domain hPDL1 is bolded and sticky binder GPI is italicized. FIG. 5G shows the nucleic acid and protein sequence for the hPDL1-Fc-GPI fusion polypeptide wherein the text for the signaling domain hPDL1 is bolded, Fc is underlined, and sticky binder GPI is italicized. FIG. 5H shows the nucleic acid and protein sequence for the hPDL2-Fc-GPI fusion polypeptide wherein the text for the signaling domain hPDL2 is bolded, Fc is underlined, and sticky binder GPI is italicized. FIG. 5I shows the nucleic acid and protein sequence for the hPDL1-C1C2 fusion polypeptide wherein the text for the signaling domain hPDL1 is bolded and sticky binder C1C2 is italicized. FIG. 5J shows the nucleic acid and protein sequence for the hPDL2-C1C2 fusion polypeptide wherein the text for the signaling domain hPDL2 is bolded and sticky binder C1C2 is italicized. FIG. 5K shows the nucleic acid and protein sequence for the 4F2-h41BBL fusion polypeptide wherein the text for the signaling domain h41BBL is bolded and sticky binder 4F2 is italicized. FIG. 5L shows the nucleic acid and protein sequence for the hPDL1-4Fc-GPI fusion polypeptide wherein the text for the signaling domain hPDL1 is bolded, 4Fc is underlined, and sticky binder GPI is italicized. FIG. 5M shows the nucleic acid and protein sequence for the Myr-NanoLuc Luciferase fusion polypeptide wherein the text for the signaling domain NanoLuc Luciferase is bolded, and sticky binder Myr is italicized. FIG. 5N shows the nucleic acid and protein sequence for the Myr-mScarlet fusion polypeptide wherein the text for the signaling domain mScarlet is bolded, and sticky binder Myr is italicized. FIG. 5O shows the nucleic acid and protein sequence for the secreted isoform of hPDL1 (SecPDL1) fusion polypeptide hSecPDL1-GPI wherein the text for the signaling domain hSecPDL1 is bolded and sticky binder GPI is italicized. FIG. 5P shows the nucleic acid and protein sequence for the Tfr2-h41BBL fusion polypeptide wherein the text for the signaling domain h41BBL is bolded and sticky binder Tfr2 is italicized. FIG. 5Q shows the nucleic acid and protein sequence for the CD9tm3-h41BBL fusion polypeptide wherein the text for the signaling domain h41BBL is bolded and sticky binder CD9tm3 is italicized. FIG. 5R shows the nucleic acid and protein sequence for the Myr/Palm-4F2-h41BBL fusion polypeptide wherein the text for the signaling domain h41BBL is bolded, sticky binder Myr/Palm is underlined, and sticky binder 4F2 is italicized. FIG. 5S shows the nucleic acid and protein sequence for the Myr/Palm-Link-h41BBL fusion polypeptide wherein the text for the signaling domain h41BBL is bolded, sticky binder Myr/Palm is italicized and underlined, and sticky binder Link (in this embodiment a GSSG linker) is in regular text (not underlined and not italicized). FIG. 5T shows the nucleic acid and protein sequence for the hPDL1-Link-GPI fusion polypeptide wherein the text for the signaling domain hPDL1 is bolded, Link is underlined (in this embodiment a GSSG linker), and sticky binder GPI is italicized. FIG. 5U shows the nucleic acid and protein sequence for the secreted isoform of hPDL1 (SecPDL1) fusion polypeptide hSecPDL1-CD9tm2 wherein the text for the signaling domain hSecPDL1 is bolded and sticky binder CD9tm2 is italicized. FIG. 5V shows the nucleic acid and protein sequence for the secreted isoform of hPDL1 (SecPDL1) fusion polypeptide hSecPDL1-CD9tm2-KRAS wherein the text for the signaling domain hSecPDL1 is bolded, sticky binder CD9tm2 is italicized, and sticky binder KRAS is italicized and underlined. FIG. 5W shows the nucleic acid and protein sequence for the secreted isoform of hPDL1 (SecPDL1) fusion polypeptide hSecPDL1-CD9tm4 wherein the text for the signaling domain hSecPDL1 is bolded and sticky binder CD9tm4 is italicized. FIG. 5X shows the nucleic acid and protein sequence for the secreted isoform of hPDL1 (SecPDL1) fusion polypeptide hSecPDL1-CD81 wherein the text for the signaling domain hSecPDL1 is bolded and sticky binder CD81 is italicized. FIG. 5Y shows the nucleic acid and protein sequence for the hCD200-Fc-GPI fusion polypeptide wherein the text for the signaling domain hCD200 is bolded, Fc is underlined, and sticky binder GPI is italicized, a spacer sequence domain (regular text, not underlined and not italicized) separates hCD200 sequence from the Fc domain, a spacer sequence domain (regular text, not underlined and not italicized) separates Fc sequence from the GPI. FIG. 5Z shows the nucleic acid and protein sequence for the hFGL1-GPI fusion polypeptide wherein the text for the signaling domain hFGL1 is bolded, and sticky binder GPI is italicized. FIG. 5AA shows the nucleic acid and protein sequence for the hGal9-Fc-GPI fusion polypeptide wherein the text for the signaling domain hGal9 is bolded, Fc is underlined, and sticky binder GPI is italicized. FIG. 5BB shows the nucleic acid and protein sequence for the hCD200-GPI fusion polypeptide wherein the text for the signaling domain hCD200 is bolded, and sticky binder GPI is italicized. FIG. 5CC shows the nucleic acid and protein sequence for the hGal9-GPI fusion polypeptide wherein the text for the signaling domain hGal9 is bolded, and sticky binder GPI is italicized. FIG. 5DD shows the nucleic acid and protein sequence for the hHVEM-GPI fusion polypeptide wherein the text for the signaling domain hHVEM is bolded, and sticky binder GPI is italicized. FIG. 5EE shows the nucleic acid and protein sequence for the hPDL2-GPI fusion polypeptide wherein the text for the signaling domain hPDL2 is bolded, and sticky binder GPI is italicized. FIG. 5FF shows the nucleic acid and protein sequence for the hTSG6-GPI fusion polypeptide wherein the text for the signaling domain hTSG6 is bolded, and sticky binder GPI is italicized. FIG. 5GG shows the nucleic acid and protein sequence for the hHVEM-Fc-GPI fusion polypeptide wherein the text for the signaling domain hHVEM is bolded, Fc is underlined, and sticky binder GPI is italicized. FIG. 5HH shows the nucleic acid and protein sequence for the mCTLA4-Fc-GPI fusion polypeptide wherein the text for the signaling domain mCTLA4 is bolded, Fc is underlined, and sticky binder GPI is italicized. FIG. 5II shows the nucleic acid and protein sequence for the mPDL1-C1C2 fusion polypeptide wherein the text for the signaling domain mPDL1 is bolded and sticky binder C1C2 is italicized. FIG. 5JJ shows the nucleic acid and protein sequence for the mPDL1-Fc-GPI fusion polypeptide wherein the text for the signaling domain mPDL1 is bolded, Fc is underlined, and sticky binder GPI is italicized. FIG. 5KK shows the nucleic acid and protein sequence for the mPDL1-GPI fusion polypeptide wherein the text for the signaling domain mPDL1 is bolded and sticky binder GPI is italicized. FIG. 5LL shows the nucleic acid and protein sequence for the mPDL2-C1C2 fusion polypeptide wherein the text for the signaling domain mPDL2 is bolded and sticky binder C1C2 is italicized. FIG. 5MM shows the nucleic acid and protein sequence for the mPDL2-Fc-GPI fusion polypeptide wherein the text for the signaling domain mPDL2 is bolded, Fc is underlined, and sticky binder GPI is italicized. FIG. 5NN shows the nucleic acid and protein sequence for the mPDL1-mFc-GPI fusion polypeptide wherein the text for the signaling domain mPDL2 is bolded, mFc is underlined, and sticky binder GPI is italicized. FIG. 5OO shows the nucleic acid and protein sequence for the mPDL2-GPI fusion polypeptide wherein the text for the signaling domain mPDL2 is bolded and sticky binder GPI is italicized. FIG. 5PP shows the nucleic acid and protein sequence for the mPDL1-GPI-P2A-mHVEM-GPI fusion polypeptide wherein the text for the signaling domain mPDL1 and mHVEM are bolded, P2A sequence is underlined, and sticky binder GPI is italicized. With P2A included, a self-cleaving peptide sequence, artificial synapses with this feature will have both mPDL1-GPI and mHVEM-GPI loaded onto the surface. FIG. 5QQ shows the nucleic acid and protein sequence for the hPDL1-ADAM10 fusion polypeptide wherein the text for the signaling domain mPDL1 is bolded and sticky binder ADAM10 is italicized. FIG. 5RR shows the nucleic acid and protein sequence for the hPDL1-4Fc-CD9tm2 fusion polypeptide wherein the text for the signaling domain hPDL1 is bolded, 4Fc is underlined, and sticky binder CD9tm2 is italicized. FIG. 5SS shows the nucleic acid and protein sequence for the fusion polypeptide hPDL1-4Fc-CD9tm2-KRAS wherein the text for the signaling domain hPDL1 is bolded, sticky binder 4Fc is underlined, sticky binder CD9tm2 is italicized, and sticky binder KRAS is italicized and underlined. FIG. 5TT shows the nucleic acid and protein sequence for the hPDL1-Fc-CD9tm2 fusion polypeptide wherein the text for the signaling domain hPDL1 is bolded, Fc is underlined, and sticky binder CD9tm2 is italicized. FIG. 5UU shows the nucleic acid and protein sequence for the fusion polypeptide hPDL1-Fc-CD9tm2-KRAS wherein the text for the signaling domain hPDL1 is bolded, sticky binder Fc is underlined, sticky binder CD9tm2 is italicized, and sticky binder KRAS is italicized and underlined. FIG. 5VV shows the nucleic acid and protein sequence for the mPDL1-mFc-CD9tm2 fusion polypeptide wherein the text for the signaling domain mouse PDL1 (mPDL1) is bolded, mouse mFc (mFc) is underlined, and sticky binder CD9tm2 is italicized. FIG. 5WW shows the nucleic acid and protein sequence for the fusion polypeptide mPDL1-mFc-CD9tm2-KRAS wherein the text for the signaling domain mPDL1 is bolded, sticky binder mFc is underlined, sticky binder CD9tm2 is italicized, and sticky binder KRAS is italicized and underlined. Wherein mPDL1 and mFc are mouse PDL1 and mouse Fc, respectively.

FIG. 6 shows hPD-L1-Fc-GPI artificial synapse purification via a multimodal resin marketed for exosome purification. Large MW artificial synapses elute in the first fraction as shown by the high hPD-L1 concentration and artificial synapse quantity (2.26E9 synapses/ml) in elution 1. Clean in place (CIP) fractions show bound and eliminated proteins from the Inventors' artificial synapse elution.

FIG. 7 shows hPDL1-Fc-GPI exosome purification via size exclusion chromatography using a resin marketed for exosome purification. Artificial synapses engineered from exosomes eluted from via a multimodal resin may be further purified via size exclusion chromatography using a resin marketed for exosome purification as shown here. Using a size exclusion chromatography, artificial synapses elute in fractions 7-9. Total protein (determined by qBit) and hPD-L1 ng/ml (determined by ELISA) of each fraction is shown in the graph. Bars show exosome number per ml (i.e., 1E10 exosomes/ml etc.). Fractions 7-9 contain >99% purified artificial synapses. Fractions 7-9 are pooled and may be concentrated using a filtration device, for example a 10K MWCO Amicon centrifugal filter. Final purified product may be filtered through a low protein binding filter, for example a 0.2 μm or 0.45 μm PES filter.

FIG. 8 shows hPD-L1 Expression on exosomes, quantity and hPD-L1 concentration was determined in size exclusion chromatography fractions 7-9. Knowing the molecular weight of engineered hPD-L1, the Inventors can determine the number of hPD-L1 molecules per exosome to be approximately between 12 and 40 hPD-L1/exosome. This value is consistent between different purification runs and constructs.

FIG. 9 shows the purification of hPD-L2-Fc-GPI artificial synapses engineered from exosomes via multimodal resin marketed for exosome purification. This graph shows Abs 280 of fractions and quantity of hPDL2 in indicated fractions. Exosomes eluted in Elution 1. Clean in place (CIP) fractions show bound and eliminated proteins from the Inventors' artificial synapse elution.

FIG. 10 shows purification of hPD-L2-Fc-GPI labeled exosomes via size exclusion column as shown here using size exclusion resin marketed for exosome purification. Fractions containing large molecular weight exosomes (Fractions 7-9) showed high hPD-L2 concentration indicating that the purified exosomes contain hPD-L2-Fc-GPI. Total protein (determined by qBit) and hPD-L1 ng/ml (determined by ELISA) of each fraction is shown in the graph. Lower molecular weight unbound hPD-L2-Fc-GPI eluted at later fractions.

FIG. 11 shows hCTLA4-Fc-GPI exosome purification via size exclusion column as shown here using size exclusion resin marketed for exosome purification. Using size exclusion chromatography, exosomes elute in fractions 7-9. Total protein (determined by qBit) and hCTLA4 ng/ml (determined by ELISA) of each fraction is shown in the graph. Fractions 7-9 are pooled and contain >99% purified exosomes. Pooled exosome fractions may then be concentrated using a filtration device, for example a 10K MWCO Amicon centrifugal filter. Final purified product may be filtered through a low protein binding filter, for example a 0.2 μm or 0.45 um PES filter. Knowing the molecular weight of engineered hCTLA-4, the Inventors can determine the number of hCTLA-4 molecules per exosome to be approximately 233 hCTLA-4/exosome.

FIG. 12A shows PD-1 Signaling Bioassay Method. The Inventors established a method to validate that PD-L1 and PD-L2 artificial synapses engineered from exosomes can bind to cells expressing PD-1 ligand. To perform this validation method, the Inventors modified the PathHunter PD-1 Signaling Bioassay from DiscoverX Briefly, the PathHunter PD-1 Signaling Bioassay relies on the well-established PathHunter Enzyme Fragment Complementation (EFC) technology to interrogate receptor activity. EFC consists of a split β-galactosidase (β-gal) enzyme: the Enzyme Donor (ED) and Enzyme Acceptor (EA) fragments which independently have no β-gal activity. However, when forced to complement they form an active β-gal enzyme that will hydrolyze substrate to produce a chemiluminescent signal. The PathHunter PD-1 Signaling Bioassay consists of human cells engineered to stably express an ED-tagged PD-1 receptor, while EA is fused to the phosphotyrosine-binding SH2 domain of the intracellular signaling protein, SHP1. Ligand or antibody-induced activation of the receptor results in phosphorylation of the receptor's cytosolic tail. Ligand engagement, through addition of ligand-presenting artificial synapses engineered from exosomes, results in phosphorylation of PD-1, leading to the recruitment of SHP1-EA. This forces complementation of the EFC components to create an active β-gal enzyme. This active enzyme hydrolyzes substrate to create chemiluminescence as a measure of receptor activity. Addition of an antagonist (e.g., antibody to PD-L1) blocks PD-1 signaling, and will prevent complementation, resulting in a loss of signal. FIG. 12B shows that the Inventors obtained approximately 10,000× higher increase in Relative Light Units (RLU) in Jurkat signaling cells treated with PD-L1 or PD-L2 labeled artificial synapses when compared to soluble PD-L1-Fc or PD-L2-Fc ligand, respectively. Meaning, it took 10,000× less ug/ml of PD-L1 or PD-L2 on artificial synapses than solubilized PD-L1-Fc or PD-L2 ligand to achieve the same RLU signaling. Shown is a dose-response curve for the PD-L1 and PD-L2 artificial synapses engineered from exosomes vs soluble PD-L1 and PD-L2 signaling bioassay.

FIG. 13A-13C shows experimental EAU outline Test Agent A—unmodified exosomes, Test Agent B—mPDL1-Fc-GPI artificial synapses engineered from exosomes 40 μg/ml, Test Agent C—mPDL1-Fc-GPI artificial synapses engineered from exosomes 400 μg/ml, IRBP—interphotoreceptor retinoid-binding protein (IRBP) peptide, BID—Bis in die (2× daily) p.o.—Per os (orally) (FIG. 13B) EAU symptoms appear at day 6. 1st intravitreal injection and 2nd intravenous injections are performed on Day 6. There is a statistically significant initial reduction in EAU in mouse PD-L1 (mPD-L1) artificial synapses engineered from exosomes treated rats via either the intravitreal and intravenous delivery modes. 2nd intravitreal and 3rd intravenous injections are performed on Day 12. There appears to be a more rapid rate of resolution in the 1× intravitreal and intravenous groups. (FIG. 13C) Weight of rats was monitored throughout the study. 3rd intravitreal and 4th intravenous injections are performed on Day 16. There does not appear to be any significant change in EAU in any of the test groups. The aforementioned results provide proof of principle of successfully treating an autoimmune condition (i.e., EAU) with human cell derived artificial synapses with PD-L1.

FIG. 14 shows 2 types of ligands displayed on the exosome surface (Type I and Type II membrane proteins). Type I membrane proteins wherein the N-Terminus is on the luminal (interior) side of the exosome membrane and the C-Terminus is on the exterior of the exosome.

Type II membrane proteins wherein the N-Terminus is on the exterior while the C-Terminus is on the interior.

FIG. 15 shows a schematic representation of several embodiments of Type I membrane protein constructs, which include but are not limited to: PD-L1, PD-L2, FGL1, OX40L.

FIG. 16 shows a schematic representation of several embodiments of the surface of an extracellular vesicle engineered with a Type I membrane protein of interest (POI) with a variable membrane anchor. Vesicle targeting sequences such as select sequences from 4F2 (CD98), ADAM10, CD298, TFR2, transmembrane portions of CD9, MARCKS, KRAS, and GPI from CD55. Proteins engineered to include a targeting sequence domain may include one or more linkers between the sticky binder and signaling domain (e.g., an Fc linker or a bond sequence wherein the bond sequence may be dimerization or multimerization sequence).

FIG. 17 shows a schematic representation of the surface of an exosome engineered with an extracellular portion of the Type II membrane protein of interest (POI) with transmembrane/exosome targeting domains.

FIG. 18 shows a schematic representation of an exosome engineered with an extracellular portion of the Type II membrane protein 4-1BB.

FIG. 19 demonstrates a construct design for labeling an exosome surface with Type II membrane proteins.

FIG. 20 shows a schematic representation of a construct design for labeling an exosome surface with multiple POI domains operably linked by a cleavable (e.g., P2A) linker.

FIG. 21 shows a flow chart of purification and analytical processes provided herein.

FIG. 22 shows a PD-L1 labeled exosome constructs.

FIG. 23 shows several embodiments of the surface of an exosome engineered with PD-L1. The PD-L1 can be the membrane-bound PD-L1 isotype or secreted PD-L1 (SecPD-L1).

FIG. 24 demonstrates size exclusion chromatography for purifying human PD-L1-GPI (no Fc) exosomes. Left panel: Protein, RNA and DNA measurements in SEC fractions are shown. Invitrogen Qubit fluorometric assays were used to measure biomolecules from unmodified concentrated cell media SEC fractions or hPD-L1-Exo-Tag concentrated cell media SEC fractions. PD-L1 was measured using an R&D systems PD-L1 ELISA kit. Right panel shows dot-blot immunoblot analysis of SEC fractions. A 96-well dot blot apparatus was used to immobilize 50 ul of each SEC fraction onto PVDF. Right bottom figures: Exosome size and concentration was measured in fraction 7 by tunable resistive pulse sensing (TRPS).

FIG. 25 demonstrates that GPI anchors hPD-L1 on exosomes.

FIG. 26 demonstrates that a multimodal resin marketed for exosome purification purifies and disaggregates exosomes.

FIG. 27 shows the exosome decoration with hPD-L1-Fc-GPI.

FIG. 28A shows the exosome decoration with hPD-L1-Fc-GPI. Fraction 7 contained the purified hPD-L1-Fc-GPI vesicles. FIG. 28B shows size exclusion chromatography (SEC) purification results of various embodiments of human PD-L1 displayed on the surface of extracellular vesicles.

FIG. 29 shows that mouse PD-L1-Fc-GPI exosomes have higher valency than mPD-L1-GPI.

FIG. 30A-30C demonstrates comparison proteomics of transprotein expression and shows that surface labeling on the engineered extracellular vesicles provided herein do not affect the relative expression of native and associated exosome proteins. FIG. 30A shows hPD-L1-Fc-GPI. FIG. 30B shows hPD-L2-FcGPI. FIG. 30C shows hCTLA4-Fc-GPI.

FIG. 31 shows production of mPD-L1-Fc-GPI in STR Bioreactor.

FIG. 32 shows purification of mPD-L1-Fc-GPI (STR) via SEC. Graph shows mPD-L1 ng/ml vs Total Protein ug/ml.

FIG. 33 shows purification mPDL1-Fc-GPI (STR bioreactor).

FIG. 34 shows a schematic representation of the 4-1BBL labeled exosomes. Top: Vector map showing the N-terminal cystolic domain, a transmembrane (TM) domain, and the POI domain at the C-terminus. Bottom: An embodiment of an engineered EV with a type-II membrane display of the fusion protein.

FIG. 35 shows embodiments of a 4-1BBL display exosome.

FIG. 36A-36B show the protein engineering and purification of 4F2-4-1BBL labeled exosomes. FIG. 36B confirms that h4-1BBL is displayed on the engineered exosomes.

FIG. 37 shows internal fusion protein loading of exosomes.

FIG. 38 shows internal loading of exosomes with mScarlet (RFP).

FIG. 39A shows internal loading of exosomes with NanoLuc luciferase. FIG. 39B shows tetraspanin characterization of exosomes internally loaded with NanoLuc luciferase.

FIG. 40A Mechanism of PD-L1 engineered extracellular vesicles induce membrane clustering and receptor agonism on a target cell. An exemplary model of proposed mechanism of extracellular vesicles with a Type I membrane protein signaling domain (PD-L1) promoting receptor clustering on a target cell, wherein receptor clustering promotes increased potency of signal transduction of the target receptor. Antagonist antibodies function well at blocking receptors. Antibodies are poor agonist modalities due to their general inability to cluster receptors. Ligands on a membrane surface are potent agonists, however the cost and cold chain logistics of cell therapies makes commercialization difficult and expensive. Extracellular vesicles engineered with Type I membrane protein are able to induce receptor clustering of target receptors and initiate and propagate a potent signal response on a target cell.

FIG. 40B Mechanism of 4-1BBL engineered extracellular vesicles induce membrane clustering and receptor agonism on a target cell. An exemplary model of proposed mechanism of extracellular vesicles with a Type II membrane protein signaling domain (4-1BBL) promoting receptor clustering on a target cell, wherein receptor clustering promotes increased potency of signal transduction of the target receptor. Soluble ligands are often poor agonist modalities due to their general inability to cluster receptors. Ligands displayed on a membrane surface are potent agonists, however the cost and cold chain logistics of cell therapies makes commercialization difficult and expensive. Extracellular vesicles engineered with Type II membrane protein are able to induce receptor clustering of target receptors and initiate and propagate a potent signal response on a target cell.

DETAILED DESCRIPTION

The compositions and methods provided herein are based, in part, on the discovery that engineered extracellular vesicles (e.g., exosomes) expressing an engineered fusion protein (e.g., PD-L1) reduces inflammation in an animal model of experimental autoimmune uveoretinitis (EAU), an autoimmune disorder. The compositions and methods provided herein are further based, in part, on the discovery that engineered extracellular vesicles produce enhanced signaling compared to an equal quantity of recombinant ligand. Since some cellular receptors, (e.g., PD-1) require clustering or super-clustering to promote a signaling response, it stands to reason that extracellular vesicles engineered to express ligands on their surface wherein the ligands may engage target receptors on target cells and promote clustering of said target receptors thereby promoting a signal response on said target cell.

In one aspect, provided herein is an engineered extracellular vesicle comprising: at least one fusion polypeptide comprising: at least one protein of interest (POI) domain; and at least one vesicle targeting domain. In some embodiments of any of the aspects, the engineered extracellular vesicle is an exosome. In some embodiments, of any of the aspects, the fusion protein further comprises at least one linker. In some embodiments of any of the aspects, the POI domain can substantially bind to a target polypeptide. In some embodiments of any of the aspects provided herein, the engineered extracellular vesicle is an artificial synapse.

Generally, the extracellular vesicles (e.g., exosomes) provided herein are produced by contacting a population of cells with a nucleic acid construct encoding the fusion proteins provided herein and isolating a plurality of extracellular vesicles. The extracellular vesicles can then be purified by methods provided herein and are formulated for therapeutic use, including but not limited to, for the treatment of autoimmune diseases, cancer, or modulating inflammation in a subject.

The compositions and methods provided herein are specifically designed to exploit the membrane trafficking mechanisms of extracellular vesicles and rely on the hallmark biophysical and biochemical properties of extracellular vesicles, such as exosomes. The vesicles/artificial synapses provided herein are specifically engineered to induce/agonize and propagate biological signaling via a target polypeptide (e.g., by activating a receptor or enzyme or agonizing said receptor or enzyme). Alternatively, the engineered extracellular vesicles provided herein can act as cellular decoys or to reduce or antagonize biological signaling, e.g., by blocking an endogenous ligand from binding to a target cellular receptor and preventing activation of the receptor.

Engineering of the extracellular vesicles provided herein extends these capabilities significantly by incorporating sticky binders attaching to extracellular vesicles such as exosomes, further coupled with signaling domains of choice. For example, attachment of sticky binders to exosomes, along with their linked signaling domains, allows for receptor clustering for biological signal induction/agonism and propagation not otherwise possible. In this aspect, the aforementioned design achieves the aim of an engineered extracellular vesicle by inducing the desired biological signaling in a target recipient cell.

Various aspects and embodiments of the compositions and methods are provided herein in detail below.

Engineered Extracellular Vesicle (EV) Compositions

The compositions provided herein comprises at least one extracellular vesicle (also termed artificial synapse or abbrv: EV), wherein the extracellular vesicle comprises at least one fusion polypeptide or a plurality of fusion polypeptides comprising: at least one vesicle targeting domain (e.g., sticky binders); and at least one protein of interest domain or a fragment thereof (also termed signaling domains).

Extracellular vesicles (EVs) are lipid particles that are released from various cell types that function to transfer “cargo” such as nucleic acids and proteins to other cells. EVs are not able to replicate but serve as cell messengers. EV-mediated signals can be transmitted by all the different biomolecule categories—protein, lipids, nucleic acids and sugars—and the unique package of this information provides both protection and the option of simultaneous delivery of multiple different messengers even to sites remote to the vesicular origin. See, e.g., Yáñez-Mó M, Siljander P R, Andreu Z, et al. Biological properties of extracellular vesicles and their physiological functions. J Extracell Vesicles. 2015; 4:27066. Published 2015 May 14. doi:10.3402/jev.v4.27066, which is incorporated herein by reference in its entirety. Furthermore, there is an increasing amount of evidence that shows that EVs can modulate a milieu of cellular signaling processes. See, e.g., Yadid et al. Science Translation Medicine (2020); Cerqueira de Abreu et al. Nature Reviews Cardiology (2020); Zhang W. et al. Protein J. (2019); Zha Q B et al. Tumor Biology. February 2017; Tan et al. (2016) Recent advances of exosomes in immune modulation and autoimmune diseases, Autoimmunity, 49:6, 357-365; Kalluri R, LeBleu V S. The biology, function, and biomedical applications of exosomes. Science. 2020 Feb. 7; 367(6478):eaau6977, which are incorporated herein by reference in their entireties.

There are various types of extracellular vesicles that are named for their site of origin in a cell, size, and structural and/or functional properties. In some embodiments of any of the aspects provided herein, the extracellular vesicle is an exosome, ectosome, macrovesicle, microparticle, apoptotic body, vesicular organelle, oncosome, exosphere, exomeres, or cell derived nanovesicle (CDN) ((e.g., by genesis via grating or shearing cells), liposomes or the like known by one of ordinary skill in the art. In various embodiments, the extracellular vesicle comprises a phospholipid bilayer with an exterior phospholipid layer and an interior phospholipid layer, wherein the exterior phospholipid layer has an external surface and an internal surface, wherein the interior phospholipid layer has an internal surface and an external surface, and the internal surface of the exterior phospholipid layer faces the internal surface of the interior phospholipid layer, and the phospholipid bilayer encloses an internal space, wherein the external surface of the interior phospholipid layer faces the internal space and wherein the external surface of the exterior phospholipid layer faces an extracellular environment, and the external surface of the inner phospholipid layer is the internal surface of the extracellular vesicle.

In various embodiments, the extracellular vesicles range in size from 30 nanometers (nm) to 300 nm. In various embodiments, the plurality of EVs range in size from about 30 nm to about 150 nm. In various embodiments, the plurality of EVs or artificial synapses includes one or more artificial synapses that are about 10 nm to about 250 nm in diameter, including those about 10 nm to about 15 nm, about 15 nm to about 20 nm, about 20 nm to about 25 nm, about 25 nm to about 30 nm, about 30 nm to about 35 nm, about 35 nm to about 40 nm, about 40 nm to about 50 nm, about 50 nm to about 60 nm3 about 60 nm to about 70 nm, about 70 nm to about 80 nm, about 80 nm to about 90 nm, about 90 nm to about 95 nm, about 95 nm to about 100 nm, about 100 nm to about 105 nm, about 105 nm to about 110 nm, about 110 nm to about 115 nm, about 115 nm to about 120 nm, about 120 nm to about 125 nm, about 125 nm to about 130 nm, about 130 nm to about 135 nm, about 135 nm to about 140 nm, about 140 nm to about 145 nm, about 145 nm to about 150 nm, about 150 to about 200 nm, about 200 nm to about 250 nm, about 250 nm or more.

In some embodiments of any of the aspects provided herein, the EV is an exosome. Exosomes are membrane-bound EVs that are produced in the endosomal compartment of most eukaryotic cells. As used herein, the term “exosome” refers to a species of extracellular vesicle between about 20 nm to about 400 m in diameter, e.g, about 30 nm-200 nm in diameter by inward invagination of a portion of a membrane of an endosome (for example an early or late endosome), wherein the endosome is within a cell comprising a plasma membrane, and the exosome is released from the cell upon fusion of another portion of the endosome membrane with the plasma membrane. An exosome may refer to a species of extracellular vesicle between 20 nm-400 μM in diameter, more preferably 30 nm-200 nm in diameter, that originates by budding of a portion of a plasma membrane from a cell wherein the budded portion of the plasma membrane is released to the extracellular environment.

The EVs (e.g., exosomes or cell derived vesicles) provided herein may comprise cargo, for example, peptides, proteins, nucleic acids, lipids, metabolites, carbohydrates, biomolecules, small molecules, large molecules, vesicles, organelles, or fragments thereof. Exosome cargo may be located within the internal space of the exosome. EV cargo may be membrane bound spanning one or both layers of the exosome phospholipid bilayer (for example a transmembrane protein). EV cargo may be in contact with the exterior or interior surface of the exosome, for example through a covalent bond or a non-covalent bond. The phospholipid bilayer of the EV or exosome provided herein may comprise one or more transmembrane proteins, wherein a portion of the one or more transmembrane membrane proteins is located within the internal space of the exosome. The phospholipid bilayer of the EV or exosome provided herein may comprise one or more transmembrane proteins, wherein a portion of the one or more transmembrane membrane proteins traverses the EV phospholipid bilayer. The phospholipid bilayer of the EV may comprise one or more transmembrane proteins, wherein the one or more transmembrane membrane proteins comprises a domain on the exterior of the exosome.

In some embodiments of any of the aspects, the extracellular vesicles or exosomes provided herein endogenously express CD81+, CD82+, CD37+, CD63+, CD9+, CD151+, CD105+, or any combination thereof. In various embodiments, the plurality of artificial synapses includes one or more artificial synapses expressing a biomarker. In certain embodiments, the biomarkers are tetraspanins. In other embodiments, the tetraspanins are one or more selected from the group including CD63, CD81, CD82, CD53, CD151, and CD37. In other embodiments, the artificial synapses express one or more lipid raft associated proteins (e.g., glycosylphosphatidylinositol-anchored proteins and flotillin), cholesterol, sphingolipids such as sphingomyelin, and/or hexosylceramides.

In other embodiments, the biological protein is related to exosome formation and packaging of cytosolic proteins, e.g., Hsp70, Hsp90, 14-3-3 epsilon, PKM2, GW182 and AGO2. In certain embodiments, the artificial synapses express CD63, HSP70, CD105 or combinations thereof. In other embodiments, the artificial synapses do not express CD9 or CD81, or express neither. For example, plurality of artificial synapses can include one or more artificial synapses that are CD63+, HSP+, CD105+, CD9−, and CD81−.

The EVs provided herein are specifically engineered to express fusion polypeptides that elicit biological signaling via a target cell. In some embodiments, the fusion polypeptide is overexpressed to elicit a biological response on a target cell or target polypeptide. The engineered EV comprises at least one fusion polypeptide and can comprise a plurality of the same or different fusion polypeptides provided herein. The fusion polypeptides provided herein comprise a protein of interest domain, also termed the signaling domain.

The fusion polypeptides provided herein can comprise one or more of a protein of interest domain, such that expression of said fusion polypeptide is permitted and that the number of POI domains does not impede protein expression or folding. Furthermore, the EVs provided herein can express more than one fusion protein (e.g., encoded by multiple different nucleic acid constructs). One of skill in the art can appreciate that an engineered EV can include one or more combinations of different signaling domains and/or vesicle targeting domains, or that one can use a plurality of engineered EVs, each including one or more vesicle targeting domains and one or more signaling domains.

In some embodiments, the EVs provided herein comprise one or more, two or more, three or more, four or more, five or more, six or more, seven or more, eight or more, nine or more, or ten or more fusion proteins. The fusion proteins can be encoded by the same vector or separate vectors. In some embodiments of any of the aspects, the engineered extracellular vesicle comprises at least two POI domains and/or at least two vesicle targeting domains.

In some embodiments, the fusion polypeptide comprises one or more, two or more, three or more, four or more, five or more, or six or more POI domains on the same polypeptide or nucleic acid construct encoding said polypeptide. For example, the fusion polypeptides provided herein can express a fusion polypeptide encoding one or more, two or more, three or more, four or more, five or more, or six or more signaling domains. In another example, the fusion polypeptides provided herein can express a fusion polypeptide encoding an immune checkpoint protein or a protein involved in immune or cell synapse or any combination or fragment thereof.

In some embodiments, the EV comprises one or more, two or more, three or more, four or more, five or more, or six or more fusion polypeptides on the same EV. For example, EVs comprising one or more, two or more, three or more, four or more, five or more, or six or more fusion polypeptides wherein the fusion polypeptides encode a signaling domain. In another example, EVs comprising one or more, two or more, three or more, four or more, five or more, or six or more fusion polypeptides wherein the fusion polypeptides encode for one or more immune checkpoint proteins or proteins involved in immune or cell synapse, or any combination or fragment thereof.

In various embodiments, the signaling domain is a protein or peptide of interest, or a fragment thereof. In various embodiments, the protein of interest (signaling domain) is an immune checkpoint protein. The terms “immune checkpoint protein” or “protein involved in immune or cell synapse” can include but are not limited to adenosine A2A receptor (A2AR), Galectin 9, fibrinogen-like protein 1 (FGL-1), platelet endothelial adhesion factor-1 (PECAM-1), tumor necrosis factor gene 6 protein (TSG-6), Stabilin-1 (STAB-1) also known as Clever-1, Neuropilin 1 (NRP1), Neuropilin 2 (NRP2), semaphorin-3A (SEMA3A), semaphorin-3F (SEMA3F), repulsive guidance molecule B (RGMB) also known as DRG11, T-cell immunoglobulin and mucin domain 3 (TIM-3), T cell immunoreceptor with Ig and ITIM domains (TIGIT), human leukocyte antigen (HLA) class I, HLA class II, high mobility group protein B1 (HMGB1), phosphatidylserine, carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM-1), T-cell receptor (TCR), Src homology 2 domain-containing protein tyrosine phosphatase 1 (SHP-1), SHP-2, F-Box protein 38 (FBXO38), signaling lymphocytic activation molecule (SLAM)-associated protein (SAP) also known as SH2D1A, B7RP1, indoleamine 2,3-dioxygenase (IDO), NADH oxidase 2 (NOX2), tumor necrosis factor receptor (TNFR) superfamily member 18 (TNFRSF18) (also known as activation inducible TNFR family receptor (AITR), glucocorticoid-induced TNFR related (GITR) protein, and CD357), B7-H4 also known as V-set domain containing T-cell activator inhibitor (VTCN1), B7-H5 (also known as V-domain Ig suppressor of T-cell activation (VISTA), platelet receptor Gi24, and stress induced secreted protein 1 (SISP1), B7-H6 (also known as NCR3LG1), B7-H7 (also known as human endogenous retrovirus-H (HERV-H) long terminal repeat-associating protein 2 (HHLA2), apelin receptor (APLNR), interferon gamma (IFN γ) receptor, programmed cell death-1 (PD-1), Protein Wnt-5a (WNT5A), serine/threonine-protein kinase PAK4, interleukin 6 (IL-6), interleukin-10 (IL-10), NKG2 family of C-type lectin receptors (for example NKG2A, B, C, D, E, F and H), ligands of NKG2 family, killer cell immunoglobulin-like receptors, CD-2, cluster of differentiation 4 (CD4), CD8, CD27, CD27 ligand (CD27L, also known as CD70), CD28, CD28H (also known as transmembrane and immunoglobulin domain containing 2 (TMIGD2) and Ig containing and proline-rich receptor-1 (IGPR1)), CD39, CD40, CD44, integrin associated protein (CD47), carcinoembryonic antigen related cell adhesion molecule 1 (CEACAM1 also known as CD66a), CD73, B7-1 (also known as CD80), B7-2 (also known as CD86), CD94, CD96, immunoglobulin superfamily member 2 (IGSF2) also known as CD101, nectin cell adhesion molecule 2 (NECTIN2) (also known as herpesvirus entry mediator B (HVEB), poliovirus receptor related 2 (PRR2, PVRL2 and PVRR2) and CD112), poliovirus receptor related immunoglobulin domain containing protein (PVIRG) also known as CD112R, CD122 (also known as IL5RB and P70-75), OX40 (also known as tumor necrosis factor receptor superfamily member 4 (TNFRSF4) and CD134), OX40 ligand (OX40L), 4-1BB (also known as CD137), CD134 (also known as 4-1BB ligand (4-1BBL) and as tumor necrosis factor ligand superfamily member 9 (TNFSF9) and CD137L), cytotoxic T-lymphocyte-associated protein 4 (CTLA-4) also known as CD152, CD154 (also known as CD40L), poliovirus receptor (PVR) also known as CD155, killer-cell immunoglobulin-like receptors (KIRs) (for example but not limited to CD158 family, CD158a, CD158g, CD158h, KIR2DL1, KIR2DS1, KIRDS3, and KIR2DS5), CD160, signal-regulatory protein alpha (SIRPa) also known as CD172a, OX-2 also known as CD200, CD200R, lymphocyte-activation gene 3 (LAG-3) also known as CD223, CD226, OX40L also known as CD252, herpes virus entry mediator (HVEM) also known as tumor necrosis factor receptor superfamily member 14 (TNFRSF14) and CD270, B- and T-lymphocyte attenuator (BTLA) also known as CD272, programmed cell death ligand-2 (PD-L2) (also known as B7-DC, PDCD1LG2, and CD273), programmed cell death-ligand 1 (PD-L1) (also known as B7-H1 and CD274), B7-H2 (also known as inducible T-cell co-stimulator ligand (ICOSLG), B7RP1, and CD275), B7-H3 also known as CD276, inducible T-cell co-stimulator (ICOS) also known as CD278, programed cell death protein 1 (PD-1) also known as CD279, leukocyte-associated Ig-like receptor-1 (LAIR-1) also known as CD305, collagen family of proteins (for example but not limited to collagen I, collagen II, collagen III alpha 1, collagen IV, collagen XXIII alpha 1, collagen XXV alpha 1), sialic acid-binding immunoglobulin-type lectin 7 (SIGLEC7) also known as CD328, sialic acid-binding immunoglobulin-type lectin 7 (SIGLEC9) also known as CD329, natural cytotoxicity triggering receptor 3 (NKp30) also known as CD337, or any isoform, fragment, variation thereof, or a ligand to the aforementioned proteins thereof, or the like known by one of ordinary skill in the art. All variants are encompassed by the present invention.

In some embodiments of any of the aspects provided herein, the protein of interest domain (POI domain) comprises a polypeptide or a fragment thereof or a nucleic acid encoding said polypeptide or fragment thereof selected from the group consisting of. Table 1 (below). Non-limiting examples of nucleic acid sequences that encode the POI domains provided herein are also provided in Table 1.

TABLE 1

Type I Proteins of Interest Amino Acid Sequence

Protein of
Transcript Sequence (SEQ ID NO:)

Interest
Amino Acid Sequence (SEQ ID NO:)

Human
>NM_014143.4 Homo sapiens CD274 molecule (CD274),

Programmed
transcript variant 1, mRNA

death-ligand
AGTTCTGCGCAGCTTCCCGAGGCTCCGCACCAGCCGCGCTTCTGTCCGCCTGCAGGG

1 (PD-L1)
CATTCCAGAAAGATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTG

CTGAACGCATTTACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGC

AATATGACAATTGAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTA

ATTGTCTATTGGGAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAA

GACCTGAAGGTTCAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAG

CTCTCCCTGGGAAATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGG

GTGTACCGCTGCATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAA

GTCAATGCCCCATACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACC

TCTGAACATGAACTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGG

ACAAGCAGTGACCATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGA

GAGGAGAAGCTTTTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAG

ATTTTCTACTGCACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTG

GTCATCCCAGAACTACCTCTGGCACATCCTCCAAATGAAAGGACTCACTTGGTAATT

CTGGGAGCCATCTTATTATGCCTTGGTGTAGCACTGACATTCATCTTCCGTTTAAGA

AAAGGGAGAATGATGGATGTGAAAAAATGTGGCATCCAAGATACAAACTCAAAGAAG

CAAAGTGATACACATTTGGAGGAGACGTAATCCAGCATTGGAACTTCTGATCTTCAA

GCAGGGATTCTCAACCTGTGGTTTAGGGGTTCATCGGGGCTGAGCGTGACAAGAGGA

AGGAATGGGCCCGTGGGATGCAGGCAATGTGGGACTTAAAAGGCCCAAGCACTGAAA

ATGGAACCTGGCGAAAGCAGAGGAGGAGAATGAAGAAAGATGGAGTCAAACAGGGAG

CCTGGAGGGAGACCTTGATACTTTCAAATGCCTGAGGGGCTCATCGACGCCTGTGAC

AGGGAGAAAGGATACTTCTGAACAAGGAGCCTCCAAGCAAATCATCCATTGCTCATC

CTAGGAAGACGGGTTGAGAATCCCTAATTTGAGGGTCAGTTCCTGCAGAAGTGCCCT

TTGCCTCCACTCAATGCCTCAATTTGTTTTCTGCATGACTGAGAGTCTCAGTGTTGG

AACGGGACAGTATTTATGTATGAGTTTTTCCTATTTATTTTGAGTCTGTGAGGTCTT

CTTGTCATGTGAGTGTGGTTGTGAATGATTTCTTTTGAAGATATATTGTAGTAGATG

TTACAATTTTGTCGCCAAACTAAACTTGCTGCTTAATGATTTGCTCACATCTAGTAA

AACATGGAGTATTTGTAAGGTGCTTGGTCTCCTCTATAACTACAAGTATACATTGGA

AGCATAAAGATCAAACCGTTGGTTGCATAGGATGTCACCTTTATTTAACCCATTAAT

ACTCTGGTTGACCTAATCTTATTCTCAGACCTCAAGTGTCTGTGCAGTATCTGTTCC

ATTTAAATATCAGCTTTACAATTATGTGGTAGCCTACACACATAATCTCATTTCATC

GCTGTAACCACCCTGTTGTGATAACCACTATTATTTTACCCATCGTACAGCTGAGGA

AGCAAACAGATTAAGTAACTTGCCCAAACCAGTAAATAGCAGACCTCAGACTGCCAC

CCACTGTCCTTTTATAATACAATTTACAGCTATATTTTACTTTAAGCAATTCTTTTA

TTCAAAAACCATTTATTAAGTGCCCTTGCAATATCAATCGCTGTGCCAGGCATTGAA

TCTACAGATGTGAGCAAGACAAAGTACCTGTCCTCAAGGAGCTCATAGTATAATGAG

GAGATTAACAAGAAAATGTATTATTACAATTTAGTCCAGTGTCATAGCATAAGGATG

ATGCGAGGGGAAAACCCGAGCAGTGTTGCCAAGAGGAGGAAATAGGCCAATGTGGTC

TGGGACGGTTGGATATACTTAAACATCTTAATAATCAGAGTAATTTTCATTTACAAA

GAGAGGTCGGTACTTAAAATAACCCTGAAAAATAACACTGGAATTCCTTTTCTAGCA

TTATATTTATTCCTGATTTGCCTTTGCCATATAATCTAATGCTTGTTTATATAGTGT

CTGGTATTGTTTAACAGTTCTGTCTTTTCTATTTAAATGCCACTAAATTTTAAATTC

ATACCTTTCCATGATTCAAAATTCAAAAGATCCCATGGGAGATGGTTGGAAAATCTC

CACTTCATCCTCCAAGCCATTCAAGTTTCCTTTCCAGAAGCAACTGCTACTGCCTTT

CATTCATATGTTCTTCTAAAGATAGTCTACATTTGGAAATGTATGTTAAAAGCACGT

ATTTTTAAAATTTTTTTCCTAAATAGTAACACATTGTATGTCTGCTGTGTACTTTGC

TATTTTTATTTATTTTAGTGTTTCTTATATAGCAGATGGAATGAATTTGAAGTTCCC

AGGGCTGAGGATCCATGCCTTCTTTGTTTCTAAGTTATCTTTCCCATAGCTTTTCAT

TATCTTTCATATGATCCAGTATATGTTAAATATGTCCTACATATACATTTAGACAAC

CACCATTTGTTAAGTATTTGCTCTAGGACAGAGTTTGGATTTGTTTATGTTTGCTCA

AAAGGAGACCCATGGGCTCTCCAGGGTGCACTGAGTCAATCTAGTCCTAAAAAGCAA

TCTTATTATTAACTCTGTATGACAGAATCATGTCTGGAACTTTTGTTTTCTGCTTTC

TGTCAAGTATAAACTTCACTTTGATGCTGTACTTGCAAAATCACATTTTCTTTCTGG

AAATTCCGGCAGTGTACCTTGACTGCTAGCTACCCTGTGCCAGAAAAGCCTCATTCG

TTGTGCTTGAACCCTTGAATGCCACCAGCTGTCATCACTACACAGCCCTCCTAAGAG

GCTTCCTGGAGGTTTCGAGATTCAGATGCCCTGGGAGATCCCAGAGTTTCCTTTCCC

TCTTGGCCATATTCTGGTGTCAATGACAAGGAGTACCTTGGCTTTGCCACATGTCAA

GGCTGAAGAAACAGTGTCTCCAACAGAGCTCCTTGTGTTATCTGTTTGTACATGTGC

ATTTGTACAGTAATTGGTGTGACAGTGTTCTTTGTGTGAATTACAGGCAAGAATTGT

GGCTGAGCAAGGCACATAGTCTACTCAGTCTATTCCTAAGTCCTAACTCCTCCTTGT

GGTGTTGGATTTGTAAGGCACTTTATCCCTTTTGTCTCATGTTTCATCGTAAATGGC

ATAGGCAGAGATGATACCTAATTCTGCATTTGATTGTCACTTTTTGTACCTGCATTA

ATTTAATAAAATATTCTTATTTATTTTGTTACTTGGTACACCAGCATGTCCATTTTC

TTGTTTATTTTGTGTTTAATAAAATGTTCAGTTTAACATCCCA (SEQ ID NO:

1)

>NP_054862.1 programmed cell death 1 ligand 1 isoform a

precursor [Homo sapiens]

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNERTHLVILGAILLCLGVALTFIFRLRKGRMMDVKKCGIQDTNSKKQSDT

HLEET (SEQ ID NO: 2)

Mouse PD-L1
>NM_021893.3 Mus musculus CD274 antigen (Cd274), mRNA

GAAATCGTGGTCCCCAAGCCTCATGCCAGGCTGCACTTGCACGTCGCGGGCCAGTCT

CCTCGCCTGCAGATAGTTCCCAAAACATGAGGATATTTGCTGGCATTATATTCACAG

CCTGCTGTCACTTGCTACGGGCGTTTACTATCACGGCTCCAAAGGACTTGTACGTGG

TGGAGTATGGCAGCAACGTCACGATGGAGTGCAGATTCCCTGTAGAACGGGAGCTGG

ACCTGCTTGCGTTAGTGGTGTACTGGGAAAAGGAAGATGAGCAAGTGATTCAGTTTG

TGGCAGGAGAGGAGGACCTTAAGCCTCAGCACAGCAACTTCAGGGGGAGAGCCTCGC

TGCCAAAGGACCAGCTTTTGAAGGGAAATGCTGCCCTTCAGATCACAGACGTCAAGC

TGCAGGACGCAGGCGTTTACTGCTGCATAATCAGCTACGGTGGTGCGGACTACAAGC

GAATCACGCTGAAAGTCAATGCCCCATACCGCAAAATCAACCAGAGAATTTCCGTGG

ATCCAGCCACTTCTGAGCATGAACTAATATGTCAGGCCGAGGGTTATCCAGAAGCTG

AGGTAATCTGGACAAACAGTGACCACCAACCCGTGAGTGGGAAGAGAAGTGTCACCA

CTTCCCGGACAGAGGGGATGCTTCTCAATGTGACCAGCAGTCTGAGGGTCAACGCCA

CAGCGAATGATGTTTTCTACTGTACGTTTTGGAGATCACAGCCAGGGCAAAACCACA

CAGCGGAGCTGATCATCCCAGAACTGCCTGCAACACATCCTCCACAGAACAGGACTC

ACTGGGTGCTTCTGGGATCCATCCTGTTGTTCCTCATTGTAGTGTCCACGGTCCTCC

TCTTCTTGAGAAAACAAGTGAGAATGCTAGATGTGGAGAAATGTGGCGTTGAAGATA

CAAGCTCAAAAAACCGAAATGATACACAATTCGAGGAGACGTAAGCAGTGTTGAACC

CTCTGATCGTCGATTGGCAGCTTGTGGTCTGTGAAAGAAAGGGCCCATGGGACATGA

GTCCAAAGACTCAAGATGGAACCTGAGGGAGAGAACCAAGAAAGTGTTGGGAGAGGA

GCCTGGAACAACGGACATTTTTTCCAGGGAGACACTGCTAAGCAAGTTGCCCATCAG

TCGTCTTGGGAAATGGATTGAGGGTTCCTGGCTTAGCAGCTGGTCCTTGCACAGTGA

CCTTTTCCTCTGCTCAGTGCCGGGATGAGAGATGGAGTCATGAGTGTTGAAGAATAA

GTGCCTTCTATTTATTTTGAGTCTGTGTGTTCTCACTTTGGGCATGTAATTATGACT

GGTGAATTCTGACGACATGATAGATCTTAAGATGTAGTCACCAAACTCAACTGCTGC

TTAGCATCCTCCGTAACTACTGATACAAGCAGGGAACACAGAGGTCACCTGCTTGGT

TTGACAGGCTCTTGCTGTCTGACTCAAATAATCTTTATTTTTCAGTCCTCAAGGCTC

TTCGATAGCAGTTGTTCTGTATCAGCCTTATAGGTGTCAGGTATAGCACTCAACATC

TCATCTCATTACAATAGCAACCCTCATCACCATAGCAACAGCTAACCTCTGTTATCC

TCACTTCATAGCCAGGAAGCTGAGCGACTAAGTCACTTGCCCACAGAGTATCAGCTC

TCAGATTTCTGTTCTTCAGCCACTGTCCTTTCAGGATAGAATTTGTCGTTAAGAAAT

TAATTTAAAAACTGATTATTGAGTAGCATTGTATATCAATCACAACATGCCTTGTGC

ACTGTGCTGGCCTCTGAGCATAAAGATGTACGCCGGAGTACCGGTCGGACATGTTTA

TGTGTGTTAAATACTCAGAGAAATGTTCATTAACAAGGAGCTTGCATTTTAGAGACA

CTGGAAAGTAACTCCAGTTCATTGTCTAGCATTACATTTACCTCATTTGCTATCCTT

GCCATACAGTCTCTTGTTCTCCATGAAGTGTCATGAATCTTGTTGAATAGTTCTTTT

ATTTTTTAAATGTTTCTATTTAAATGATATTGACATCTGAGGCGATAGCTCAGTTGG

TAAAACCCTTTCCTCACAAGTGTGAAACCCTGAGTCTTATCCCTAGAACCCACATAA

AAAACAGTTGCGTATGTTTGTGCATGCTTTTGATCCCAGCACTAGGGAGGCAGAGGC

AGGCAGATCCTGAGCTCTCATTGACCACCCAGCCTAGCCTACATGGTTAGCTCCAGG

CCTACAGGAGCTGGCAGAGCCTGAAAAACGATGCCTAGACACACACACACACACACA

CACACACACACACACACACACACACCATGTACTCATAGACCTAAGTGCACCCTCCTA

CACATGCACACACATACAATTCAAACACAAATCAACAGGGAATTGTCTCAGAATGGT

CCCCAAGACAAAGAAGAAGAAAAACACCAAACCAGCTCTATTCCCTCAGCCTATCCT

CTCTACTCCTTCCTAGAAGCAACTACTATTGTTTTTGTATATAAATTTACCCAACGA

CAGTTAATATGTAGAATATATATTAAAGTGTCTGTCAATATATATTATCTCTTTCTT

TCTTTCTTCCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTTCTTT

CTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTTCTTTCTTTCTTTCTTTT

TTTCTGTCTATCTGTACCTAAATGGTTGCTCACTATGCATTTTCTGTGCTCTTCGCC

CTTTTTATTTAATGTATGGATATTTATGCTGCTTCCAGAATGGATCTAAAGCTCTTT

GTTTCTAGGTTTTCTCCCCCATCCTTCTAGGCATCTCTCACACTGTCTAGGCCAGAC

ACCATGTCTGCTGCCTGAATCTGTAGACACCATTTATAAAGCACGTACTCACCGAGT

TTGTATTTGGCTTGTTCTGTGTCTGATTAAAGGGAGACCATGAGTCCCCAGGGTACA

CTGAGTTACCCCAGTACCAAGGGGGAGCCTTGTTTGTGTCTCCATGGCAGAAGCAGG

CCTGGAGCCATTTTGGTTTCTTCCTTGACTTCTCTCAAACACAGACGCCTCACTTGC

TCATTACAGGTTCTCCTTTGGGAATGTCAGCATTGCTCCTTGACTGCTGGCTGCCCT

GGAAGGAGCCCATTAGCTCTGTGTGAGCCCTTGACAGCTACTGCCTCTCCTTACCAC

AGGGGCCTCTAAGATACTGTTACCTAGAGGTCTTGAGGATCTGTGTTCTCTGGGGGG

AGGAAAGGAGGAGGAACCCAGAACTTTCTTACAGTTTTCCTTGTTCTGTCACATGTC

AAGACTGAAGGAACAGGCTGGGCTACGTAGTGAGATCCTGTCTCAAAGGAAAGACGA

GCATAGCCGAACCCCCGGTGGAACCCCCTCTGTTACCTGTTCACACAAGCTTATTGA

TGAGTCTCATGTTAATGTCTTGTTTGTATGAAGTTTAAGAAAATATCGGGTTGGGCA

ACACATTCTATTTATTCATTTTATTTGAAATCTTAATGCCATCTCATGGTGTTGGAT

TGGTGTGGCACTTTATTCTTTTGTGTTGTGTATAACCATAAATTTTATTTTGCATCA

GATTGTCAATGTATTGCATTAATTTAATAAATATTTTTATTTATTAAAAAAAAAAAA

AAAAA (SEQ ID NO: 3)

>NP_068693.1 programmed cell death 1 ligand 1 precursor

[Mus musculus]

MRIFAGIIFTACCHLLRAFTITAPKDLYVVEYGSNVTMECRFPVERELDLLALVVYW

EKEDEQVIQFVAGEEDLKPQHSNFRGRASLPKDQLLKGNAALQITDVKLQDAGVYCC

IISYGGADYKRITLKVNAPYRKINQRISVDPATSEHELICQAEGYPEAEVIWINSDH

QPVSGKRSVTTSRTEGMLLNVTSSLRVNATANDVFYCTFWRSQPGQNHTAELIIPEL

PATHPPQNRTHWVLLGSILLFLIVVSTVLLFLRKQVRMLDVEKCGVEDTSSKNRNDT

QFEET (SEQ ID NO: 4)

Human PD-L2
>NM_025239. 4 Homo sapiens programmed cell death 1 ligand

2 (PDCD1LG2), mRNA

ACTCTCATGTTACGGCAAACCTTAAGCTGAATGAACAACTTTTCTTCTCTTGAATAT

ATCTTAACGCCAAATTTTGAGTGCTTTTTTGTTACCCATCCTCATATGTCCCAGCTA

GAAAGAATCCTGGGTTGGAGCTACTGCATGTTGATTGTTTTGTTTTTCCTTTTGGCT

GTTCATTTTGGTGGCTACTATAAGGAAATCTAACACAAACAGCAACTGTTTTTTGTT

GTTTACTTTTGCATCTTTACTTGTGGAGCTGTGGCAAGTCCTCATATCAAATACAGA

ACATGATCTTCCTCCTGCTAATGTTGAGCCTGGAATTGCAGCTTCACCAGATAGCAG

CTTTATTCACAGTGACAGTCCCTAAGGAACTGTACATAATAGAGCATGGCAGCAATG

TGACCCTGGAATGCAACTTTGACACTGGAAGTCATGTGAACCTTGGAGCAATAACAG

CCAGTTTGCAAAAGGTGGAAAATGATACATCCCCACACCGTGAAAGAGCCACTTTGC

TGGAGGAGCAGCTGCCCCTAGGGAAGGCCTCGTTCCACATACCTCAAGTCCAAGTGA

GGGACGAAGGACAGTACCAATGCATAATCATCTATGGGGTCGCCTGGGACTACAAGT

ACCTGACTCTGAAAGTCAAAGCTTCCTACAGGAAAATAAACACTCACATCCTAAAGG

TTCCAGAAACAGATGAGGTAGAGCTCACCTGCCAGGCTACAGGTTATCCTCTGGCAG

AAGTATCCTGGCCAAACGTCAGCGTTCCTGCCAACACCAGCCACTCCAGGACCCCTG

AAGGCCTCTACCAGGTCACCAGTGTTCTGCGCCTAAAGCCACCCCCTGGCAGAAACT

TCAGCTGTGTGTTCTGGAATACTCACGTGAGGGAACTTACTTTGGCCAGCATTGACC

TTCAAAGTCAGATGGAACCCAGGACCCATCCAACTTGGCTGCTTCACATTTTCATCC

CCTTCTGCATCATTGCTTTCATTTTCATAGCCACAGTGATAGCCCTAAGAAAACAAC

TCTGTCAAAAGCTGTATTCTTCAAAAGACACAACAAAAAGACCTGTCACCACAACAA

AGAGGGAAGTGAACAGTGCTATCTGAACCTGTGGTCTTGGGAGCCAGGGTGACCTGA

TATGACATCTAAAGAAGCTTCTGGACTCTGAACAAGAATTCGGTGGCCTGCAGAGCT

TGCCATTTGCACTTTTCAAATGCCTTTGGATGACCCAGCACTTTAATCTGAAACCTG

CAACAAGACTAGCCAACACCTGGCCATGAAACTTGCCCCTTCACTGATCTGGACTCA

CCTCTGGAGCCTATGGCTTTAAGCAAGCACTACTGCACTTTACAGAATTACCCCACT

GGATCCTGGACCCACAGAATTCCTTCAGGATCCTTCTTGCTGCCAGACTGAAAGCAA

AAGGAATTATTTCCCCTCAAGTTTTCTAAGTGATTTCCAAAAGCAGAGGTGTGTGGA

AATTTCCAGTAACAGAAACAGATGGGTTGCCAATAGAGTTATTTTTTATCTATAGCT

TCCTCTGGGTACTAGAAGAGGCTATTGAGACTATGAGCTCACAGACAGGGCTTCGCA

CAAACTCAAATCATAATTGACATGTTTTATGGATTACTGGAATCTTGATAGCATAAT

GAAGTTGTTCTAATTAACAGAGAGCATTTAAATATACACTAAGTGCACAAATTGTGG

AGTAAAGTCATCAAGCTCTGTTTTTGAGGTCTAAGTCACAAAGCATTTGTTTTAACC

TGTAATGGCACCATGTTTAATGGTGGTTTTTTTTTTGAACTACATCTTTCCTTTAAA

AATTATTGGTTTCTTTTTATTTGTTTTTACCTTAGAAATCAATTATATACAGTCAAA

AATATTTGATATGCTCATACGTTGTATCTGCAGCAATTTCAGATAAGTAGCTAAAAT

GGCCAAAGCCCCAAACTAAGCCTCCTTTTCTGGCCCTCAATATGACTTTAAATTTGA

CTTTTCAGTGCCTCAGTTTGCACATCTGTAATACAGCAATGCTAAGTAGTCAAGGCC

TTTGATAATTGGCACTATGGAAATCCTGCAAGATCCCACTACATATGTGTGGAGCAG

AAGGGTAACTCGGCTACAGTAACAGCTTAATTTTGTTAAATTTGTTCTTTATACTGG

AGCCATGAAGCTCAGAGCATTAGCTGACCCTTGAACTATTCAAATGGGCACATTAGC

TAGTATAACAGACTTACATAGGTGGGCCTAAAGCAAGCTCCTTAACTGAGCAAAATT

TGGGGCTTATGAGAATGAAAGGGTGTGAAATTGACTAACAGACAAATCATACATCTC

AGTTTCTCAATTCTCATGTAAATCAGAGAATGCCTTTAAAGAATAAAACTCAATTGT

TATTCTTCAACGTTCTTTATATATTCTACTTTTGGGTA (SEQ ID NO: 5)

>NP_079515.2 programmed cell death 1 ligand 2 precursor

[Homo sapiens]

MIFLLLMLSLELQLHQIAALFTVTVPKELYIIEHGSNVTLECNFDTGSHVNLGAITA

SLQKVENDTSPHRERATLLEEQLPLGKASFHIPQVQVRDEGQYQCIIIYGVAWDYKY

LTLKVKASYRKINTHILKVPETDEVELTCQATGYPLAEVSWPNVSVPANTSHSRTPE

GLYQVTSVLRLKPPPGRNFSCVFWNTHVRELTLASIDLQSQMEPRTHPTWLLHIFIP

FCIIAFIFIATVIALRKQLCQKLYSSKDTTKRPVTTTKREVNSAI (SEQ ID NO:

6)

Mouse PD-L2
>NM_021396.2 Mus musculus programmed cell death 1 ligand

2 (Pdcd11g2), mRNA

GACCACATCATTTTTGTTCCCTTTGTTGGATATATCCTAATGTCAAATGTGGCATAT

CTTTGTTGTCTCCTTCTGTCTCCCAACTAGAGAGAACACACTTACGGCTCCTGTCCC

GGGCAGGTTTGGTTGTCGGTGTGATTGGCTTCCAGGGAACCTGATACAAGGAGCAAC

TGTGTGCTGCCTTTTCTGTGTCTTTGCTTGAGGAGCTGTGCTGGGTGCTGATATTGA

CACAGACCATGCTGCTCCTGCTGCCGATACTGAACCTGAGCTTACAACTTCATCCTG

TAGCAGCTTTATTCACCGTGACAGCCCCTAAAGAAGTGTACACCGTAGACGTCGGCA

GCAGTGTGAGCCTGGAGTGCGATTTTGACCGCAGAGAATGCACTGAACTGGAAGGGA

TAAGAGCCAGTTTGCAGAAGGTAGAAAATGATACGTCTCTGCAAAGTGAAAGAGCCA

CCCTGCTGGAGGAGCAGCTGCCCCTGGGAAAGGCTTTGTTCCACATCCCTAGTGTCC

AAGTGAGAGATTCCGGGCAGTACCGTTGCCTGGTCATCTGCGGGGCCGCCTGGGACT

ACAAGTACCTGACGGTGAAAGTCAAAGCTTCTTACATGAGGATAGACACTAGGATCC

TGGAGGTTCCAGGTACAGGGGAGGTGCAGCTTACCTGCCAGGCTAGAGGTTATCCCC

TAGCAGAAGTGTCCTGGCAAAATGTCAGTGTTCCTGCCAACACCAGCCACATCAGGA

CCCCCGAAGGCCTCTACCAGGTCACCAGTGTTCTGCGCCTCAAGCCTCAGCCTAGCA

GAAACTTCAGCTGCATGTTCTGGAATGCTCACATGAAGGAGCTGACTTCAGCCATCA

TTGACCCTCTGAGTCGGATGGAACCCAAAGTCCCCAGAACGTGGCCACTTCATGTTT

TCATCCCGGCCTGCACCATCGCTTTGATCTTCCTGGCCATAGTGATAATCCAGAGAA

AGAGGATCTAGGGGAAGCTGTATTACGGAAGAAGATCTGGACCTGCGGTCTTGGGAG

TTGGAAGGATCTGATGGGAAACCCTCAAGAGACTTCTGGACTCAAAGTGAGAATCTT

GCAGGACCTGCCATTTGCACTTTTGAACCCTTTGGACGGTGACCCAGGGCTCCGAAG

AGGAGCTTGTAAGACTGACAATCTTCCCTCTGTCTCAAGACTCTCTGAACAGCAAGA

CCCCAATGGCACTTTAGACTTACCCCTGGGATCCTGGACCCCAGTGAGGGCCTAAGG

CTCCTAATGACTTTCAGGGTGAGAACAAAAGGAATTGCTCTCCGCCCCACCCCCACC

TCCTGCTTTCCGCAGGGAGACATGGAAATTCCCAGTTACTAAAATAGATTGTCAATA

GAGTTATTTATAGCCCTCATTTCCTCCGGGGACTTGGAAGCTTCAGACAGGGTTTTT

CATAAACAAAGTCATAACTGATGTGTTTTACAGCATCCTAGAATCCTGGCAGCCTCT

GAAGTTCTAATTAACTGGAAGCATTTAAGCAACACGTTAAGTACCCCCACTGTGGTA

TTTGTTTCTACTTTTCTGTTTTTAAAGTGTGAGTCACAAGGTAATTGTTGTAACCTG

TGATATCACTGTTTCTTGTGTCTCTTCTTTCAACTACATCTTTTAAAACAAAACGGT

GTGGGGTTTGGTTGTTTTGGTGGTAGTGGTAGTGTTTCTCAGTGGTATCTCCTTAAG

AAAAAAAATCATCATGCCAGTGAATTGTTTCTTCAGCCATTTCAGATGGGAAGCTGG

AATAGCCTGTCCCCCAAGCTAAGCCTTCTTCCCTAGCTTTCTGCGTGATTTTACATT

GAGCATTCCTGTTGCTTTGTTTCTATAACTGTAATGTGGTGATGTCATTGTTAGGGC

ACTTGAGGGTGGGCGTTCTGGAAGTCCTTTCAGGTTAGTGTTTGGGGGCAGGGTTGC

TCAGAATACATAAAGGTGCTAACTTAAACTGCAGCCATGGAGCTCAGTGAATTCACT

AACCTTCGGGCTGTCCAAATGTGCACATTAGCTACTGTGACCCCTGTAGGTTAGGGA

GCCTGAAGCCAGCTCTTTACCTGGTGTTTAGACTCAGCAGAATTTGGAGTCAATGGG

ACCAAATGGTTGTGAAATTAAGATTTGAAGTGTGCATCTTATTTTATCACCATCTGC

CCAACAAAACTTCAGAAAATGCCTTTGAAGCACAAAAATGTAATCGTTTATGTGAAA

TCTCTGAGTTGCATTTAGATGCCCATTGCAGCAAGGTGGCTCTCTCACAGATTCCAC

ACCTTAGCCTAAGATACCAGACAGCAGGACAGAGAGAAAAGTCCTTCCTGGTGTGCA

AACTTCCTTACACTGGACCTCGCCTCTCAGGTGTGTGATTGGTAGGCCAAATCCCGA

TAGCCAATCGGTGTTGGGTGCTTTGTCTGCTCTACTGGGAGTCCAGTGGTACAATGG

ATTCTGGCAAAATGCTGCCATCTTGGCCCTCGCTGGGCTGCTTTCTAGGATATTCAT

AGAGAAAGGGCCGTCCAGATCCAGTATCCTAAAATCCTGAGAGGAGAATATAAGTTA

GTGTGTCTCACTATAACTATCTCTATGATCGGTCACATTACTATCTAACAGTTACCA

AATACTATATGCCTAATACTGGTAAGCATTTTATACACACCATTGGATTGAATCCTC

TCAAAATCCTCAAAAAGGAAGTTATTAATACCTCCATAGGCAAGGAGCCCAGAACCC

AGAGAGGTCAGGCAGTCTAGTTATAGATGCCTGCTTTGTTTAGAAGTGAACAAGAGC

ATCAAATTATTAATGTGCCCTGGTTATTAATGCGCCCTGGTTACCTGCTGGATGGAA

CATCAAGGTGGACTTTTGGCAGTTGCATACACCCAGAGGTATTTTGGCTATTCACGG

ATTAATTTCACACGAAGTGTTTCAGAGACATGTGTAGGGGAAGTCCGGGTTCAGGGG

GCCTAAGATTCAAACTCTAGCTTAGCTACGTCTGACCTCCCTAAGCACTAACTTACT

ATCAAAAGAATGAGCAGTAAAAGAATGGTGTTTACTGCCTGCCTTTATCAGGCAGTG

AACGTGCAGCGGGCAACGAATGCTTGATAAGTGTGTGTCAGTGTGAAGTCCCATGTA

CCAGCCGCTGTCCCCACTGCAAAAGCAGCAGAGCGCTCAGACATCATCAGCTGATTT

ACCAGCAGCAGATTTCTTCTTCTAGTCCCATCCCTGAAGAAGCTTCCAGCCTAGGTA

CATTGCATGGGCTTTGTGCTCCAGGAGTTCCTACACAGCCCTCAACTTCAACACAGG

CAAAGTGCTTACTGATCCTCATGTATCTTACAGGGTCCCCTCTACCCACAATACCTC

ATTGCTGGAACTTCAAATCTTCCTGAATAAAAGCTTGCCCGTGGTTTAATTA (SEQ

ID NO: 7)

>NP_067371.1 programmed cell death 1 ligand 2 precursor

[Mus musculus]

MLLLLPILNLSLQLHPVAALFTVTAPKEVYTVDVGSSVSLECDFDRRECTELEGIRA

SLQKVENDTSLQSERATLLEEQLPLGKALFHIPSVQVRDSGQYRCLVICGAAWDYKY

LTVKVKASYMRIDTRILEVPGTGEVQLTCQARGYPLAEVSWQNVSVPANTSHIRTPE

GLYQVTSVLRLKPQPSRNFSCMFWNAHMKELTSAIIDPLSRMEPKVPRTWPLHVFIP

ACTIALIFLAIVIIQRKRI (SEQ ID NO: 8)

Human
>NM_005214.5 Homo sapiens cytotoxic T-lymphocyte

CTLA-4
associated protein 4 (CTLA4), transcript variant 1, mRNA

(CD152)
GCTTTCTATTCAAGTGCCTTCTGTGTGTGCACATGTGTAATACATATCTGGGATCAA

AGCTATCTATATAAAGTCCTTGATTCTGTGTGGGTTCAAACACATTTCAAAGCTTCA

GGATCCTGAAAGGTTTTGCTCTACTTCCTGAAGACCTGAACACCGCTCCCATAAAGC

CATGGCTTGCCTTGGATTTCAGCGGCACAAGGCTCAGCTGAACCTGGCTACCAGGAC

CTGGCCCTGCACTCTCCTGTTTTTTCTTCTCTTCATCCCTGTCTTCTGCAAAGCAAT

GCACGTGGCCCAGCCTGCTGTGGTACTGGCCAGCAGCCGAGGCATCGCCAGCTTTGT

GTGTGAGTATGCATCTCCAGGCAAAGCCACTGAGGTCCGGGTGACAGTGCTTCGGCA

GGCTGACAGCCAGGTGACTGAAGTCTGTGCGGCAACCTACATGATGGGGAATGAGTT

GACCTTCCTAGATGATTCCATCTGCACGGGCACCTCCAGTGGAAATCAAGTGAACCT

CACTATCCAAGGACTGAGGGCCATGGACACGGGACTCTACATCTGCAAGGTGGAGCT

CATGTACCCACCGCCATACTACCTGGGCATAGGCAACGGAACCCAGATTTATGTAAT

TGATCCAGAACCGTGCCCAGATTCTGACTTCCTCCTCTGGATCCTTGCAGCAGTTAG

TTCGGGGTTGTTTTTTTATAGCTTTCTCCTCACAGCTGTTTCTTTGAGCAAAATGCT

AAAGAAAAGAAGCCCTCTTACAACAGGGGTCTATGTGAAAATGCCCCCAACAGAGCC

AGAATGTGAAAAGCAATTTCAGCCTTATTTTATTCCCATCAATTGAGAAACCATTAT

GAAGAAGAGAGTCCATATTTCAATTTCCAAGAGCTGAGGCAATTCTAACTTTTTTGC

TATCCAGCTATTTTTATTTGTTTGTGCATTTGGGGGGAATTCATCTCTCTTTAATAT

AAAGTTGGATGCGGAACCCAAATTACGTGTACTACAATTTAAAGCAAAGGAGTAGAA

AGACAGAGCTGGGATGTTTCTGTCACATCAGCTCCACTTTCAGTGAAAGCATCACTT

GGGATTAATATGGGGATGCAGCATTATGATGTGGGTCAAGGAATTAAGTTAGGGAAT

GGCACAGCCCAAAGAAGGAAAAGGCAGGGAGCGAGGGAGAAGACTATATTGTACACA

CCTTATATTTACGTATGAGACGTTTATAGCCGAAATGATCTTTTCAAGTTAAATTTT

ATGCCTTTTATTTCTTAAACAAATGTATGATTACATCAAGGCTTCAAAAATACTCAC

ATGGCTATGTTTTAGCCAGTGATGCTAAAGGTTGTATTGCATATATACATATATATA

TATATATATATATATATATATATATATATATATATATATATATATATTTTAATTTGA

TAGTATTGTGCATAGAGCCACGTATGTTTTTGTGTATTTGTTAATGGTTTGAATATA

AACACTATATGGCAGTGTCTTTCCACCTTGGGTCCCAGGGAAGTTTTGTGGAGGAGC

TCAGGACACTAATACACCAGGTAGAACACAAGGTCATTTGCTAACTAGCTTGGAAAC

TGGATGAGGTCATAGCAGTGCTTGATTGCGTGGAATTGTGCTGAGTTGGTGTTGACA

TGTGCTTTGGGGCTTTTACACCAGTTCCTTTCAATGGTTTGCAAGGAAGCCACAGCT

GGTGGTATCTGAGTTGACTTGACAGAACACTGTCTTGAAGACAATGGCTTACTCCAG

GAGACCCACAGGTATGACCTTCTAGGAAGCTCCAGTTCGATGGGCCCAATTCTTACA

AACATGTGGTTAATGCCATGGACAGAAGAAGGCAGCAGGTGGCAGAATGGGGTGCAT

GAAGGTTTCTGAAAATTAACACTGCTTGTGTTTTTAACTCAATATTTTCCATGAAAA

TGCAACAACATGTATAATATTTTTAATTAAATAAAAATCTGTGGTGGTCGTTTTCCG

GA (SEQ ID NO: 9)

>NP_005205.2 cytotoxic T-lymphocyte protein 4 isoform

CTLA4-TM precursor [Homo sapiens]

MACLGFQRHKAQLNLATRTWPCTLLFFLLFIPVFCKAMHVAQPAVVLASSRGIASFV

CEYASPGKATEVRVTVLRQADSQVTEVCAATYMMGNELTFLDDSICTGTSSGNQVNL

TIQGLRAMDTGLYICKVELMYPPPYYLGIGNGTQIYVIDPEPCPDSDFLLWILAAVS

SGLFFYSFLLTAVSLSKMLKKRSPLTTGVYVKMPPTEPECEKQFQPYFIPIN (SEQ

ID NO: 10)

Mouse CTLA-
>NM_009843.4 Mus musculus cytotoxic T-lymphocyte-

4 (CD152)
associated protein 4 (Ctla4), transcript variant 1, mRNA

CTACACATATGTAGCACGTACCTTGGATCAAAGCTGTCTATATAAAGTCCCCGAGTC

TGTGTGGGTTCAAACACATCTCAAGGCTTCTGGATCCTGTTGGGTTTTACTCTGCTC

CCTGAGGACCTCAGCACATTTGCCCCCCAGCCATGGCTTGTCTTGGACTCCGGAGGT

ACAAAGCTCAACTGCAGCTGCCTTCTAGGACTTGGCCTTTTGTAGCCCTGCTCACTC

TTCTTTTCATCCCAGTCTTCTCTGAAGCCATACAGGTGACCCAACCTTCAGTGGTGT

TGGCTAGCAGCCATGGTGTCGCCAGCTTTCCATGTGAATATTCACCATCACACAACA

CTGATGAGGTCCGGGTGACTGTGCTGCGGCAGACAAATGACCAAATGACTGAGGTCT

GTGCCACGACATTCACAGAGAAGAATACAGTGGGCTTCCTAGATTACCCCTTCTGCA

GTGGTACCTTTAATGAAAGCAGAGTGAACCTCACCATCCAAGGACTGAGAGCTGTTG

ACACGGGACTGTACCTCTGCAAGGTGGAACTCATGTACCCACCGCCATACTTTGTGG

GCATGGGCAACGGGACGCAGATTTATGTCATTGATCCAGAACCATGCCCGGATTCTG

ACTTCCTCCTTTGGATCCTTGTCGCAGTTAGCTTGGGGTTGTTTTTTTACAGTTTCC

TGGTCACTGCTGTTTCTTTGAGCAAGATGCTAAAGAAAAGAAGTCCTCTTACAACAG

GGGTCTATGTGAAAATGCCCCCAACAGAGCCAGAATGTGAAAAGCAATTTCAGCCTT

ATTTTATTCCCATCAACTGAAAGGCCGTTTATGAAGAAGAAGGAGCATACTTCAGTC

TCTAAAAGCTGAGGCAATTTCAACTTTCCTTTTCTCTCCAGCTATTTTTACCTGTTT

GTATATTTTAAGGAGAGTATGCCTCTCTTTAATAGAAAGCTGGATGCAAAATTCCAA

TTAAGCATACTACAATTTAAAGCTAAGGAGCATGAACAGAGAGCTGGGATATTTCTG

TTGTGTCAGAACCATTTTACTAAAAGCATCACTTGGAAGCAGCATAAGGATATAGCA

TTATGGTGTGGGGTCAAGGGAACATTAGGGAATGGCACAGCCCAAAGAAAGGAAGGG

GGTGAAGGAAGAGATTATATTGTACACATCTTGTATTTACCTGAGAGATGTTTATGA

CTTAAATAATTTTTAAATTTTTCATGCTGTTATTTTCTTTAACAATGTATAATTACA

CGAAGGTTTAAACATTTATTCACAGAGCTATGTGACATAGCCAGTGGTTCCAAAGGT

TGTAGTGTTCCAAGATGTATTTTTAAGTAATATTGTACATGGGTGTTTCATGTGCTG

TTGTGTATTTGCTGGTGGTTTGAATATAAACACTATGTATCAGTGTCGTCCCACAGT

GGGTCCTGGGGAGGTTTGGCTGGGGAGCTTAGGACACTAATCCATCAGGTTGGACTC

GAGGTCCTGCACCAACTGGCTTGGAAACTAGATGAGGCTGTCACAGGGCTCAGTTGC

ATAAACCGATGGTGATGGAGTGTAAACTGGGTCTTTACACTCATTTTATTTTTTGTT

TCTGCTTTTGTTTTCTTCAATGATTTGCAAGGAAACCAAAAGCTGGCAGTGTTTGTA

TGAACCTGACAGAACACTGTCTTCAAGGAAATGCCTCATTCCTGAGACCAGTAGGTT

TGTTTTTTTAGGAAGTTCCAATACTAGGACCCCCTACAAGTACTATGGCTCCTCGAA

AACACAAAGTTAATGCCACAGGAAGCAGCAGATGGTAGGATGGGATGCACAAGAGTT

CCTGAAAACTAACACTGTTAGTGTTTTTTTTTTAACTCAATATTTTCCATGAAAATG

CAACCACATGTATAATATTTTTAATTAAATAAAAGTTTCTTGTGATTGTTTT (SEQ

ID NO: 11)

>NP_033973.2 cytotoxic T-lymphocyte protein 4 isoform 1

precursor [Mus musculus]

MACLGLRRYKAQLQLPSRTWPFVALLTLLFIPVFSEAIQVTQPSVVLASSHGVASFP

CEYSPSHNTDEVRVTVLRQTNDQMTEVCATTFTEKNTVGFLDYPFCSGTFNESRVNL

TIQGLRAVDTGLYLCKVELMYPPPYFVGMGNGTQIYVIDPEPCPDSDFLLWILVAVS

LGLFFYSFLVTAVSLSKMLKKRSPLTTGVYVKMPPTEPECEKQFQPYFIPIN (SEQ

ID NO: 12)

Human 4-
>NM_003811.4 Homo sapiens TNF superfamily member 9

1BBL
(TNFSF9), mRNA

(CD137L)
AGTCTCTCGTCATGGAATACGCCTCTGACGCTTCACTGGACCCCGAAGCCCCGTGGC

CTCCCGCGCCCCGCGCTCGCGCCTGCCGCGTACTGCCTTGGGCCCTGGTCGCGGGGC

TGCTGCTGCTGCTGCTGCTCGCTGCCGCCTGCGCCGTCTTCCTCGCCTGCCCCTGGG

CCGTGTCCGGGGCTCGCGCCTCGCCCGGCTCCGCGGCCAGCCCGAGACTCCGCGAGG

GTCCCGAGCTTTCGCCCGACGATCCCGCCGGCCTCTTGGACCTGCGGCAGGGCATGT

TTGCGCAGCTGGTGGCCCAAAATGTTCTGCTGATCGATGGGCCCCTGAGCTGGTACA

GTGACCCAGGCCTGGCAGGCGTGTCCCTGACGGGGGGCCTGAGCTACAAAGAGGACA

CGAAGGAGCTGGTGGTGGCCAAGGCTGGAGTCTACTATGTCTTCTTTCAACTAGAGC

TGCGGCGCGTGGTGGCCGGCGAGGGCTCAGGCTCCGTTTCACTTGCGCTGCACCTGC

AGCCACTGCGCTCTGCTGCTGGGGCCGCCGCCCTGGCTTTGACCGTGGACCTGCCAC

CCGCCTCCTCCGAGGCTCGGAACTCGGCCTTCGGTTTCCAGGGCCGCTTGCTGCACC

TGAGTGCCGGCCAGCGCCTGGGCGTCCATCTTCACACTGAGGCCAGGGCACGCCATG

CCTGGCAGCTTACCCAGGGCGCCACAGTCTTGGGACTCTTCCGGGTGACCCCCGAAA

TCCCAGCCGGACTCCCTTCACCGAGGTCGGAATAACGTCCAGCCTGGGTGCAGCCCA

CCTGGACAGAGTCCGAATCCTACTCCATCCTTCATGGAGACCCCTGGTGCTGGGTCC

CTGCTGCTTTCTCTACCTCAAGGGGCTTGGCAGGGGTCCCTGCTGCTGACCTCCCCT

TGAGGACCCTCCTCACCCACTCCTTCCCCAAGTTGGACCTTGATATTTATTCTGAGC

CTGAGCTCAGATAATATATTATATATATTATATATATATATATATTTCTATTTAAAG

AGGATCCTGAGTTTGTGAATGGACTTTTTTAGAGGAGTTGTTTTGGGGGGGGGGGGG

TCTTCGACATTGCCGAGGCTGGTCTTGAACTCCTGGACTTAGACGATCCTCCTGCCT

CAGCCTCCCAAGCAACTGGGATTCATCCTTTCTATTAATTCATTGTACTTATTTGCT

TATTTGTGTGTATTGAGCATCTGTAATGTGCCAGCATTGTGCCCAGGCTAGGGGGCT

ATAGAAACATCTAGAAATAGACTGAAAGAAAATCTGAGTTATGGTAATACGTGAGGA

ATTTAAAGACTCATCCCCAGCCTCCACCTCCTGTGTGATACTTGGGGGCTAGCTTTT

TTCTTTCTTTCTTTTTTTTGAGATGGTCTTGTTCTGTCAACCAGGCTAGAATGCAGC

GGTGCAATCATGAGTCAATGCAGCCTCCAGCCTCGACCTCCCGAGGCTCAGGTGATC

CTCCCATCTCAGCCTCTCGAGTAGCTGGGACCACAGTTGTGTGCCACCACACTTGGC

TAACTTTTTAATTTTTTTGCGGAGACGGTATTGCTATGTTGCCAAGGTTGTTTACAT

GCCAGTACAATTTATAATAAACACTCATTTTTCCTCCC (SEQ ID NO: 13)

>NP_003802.1 tumor necrosis factor ligand superfamily

member 9 [Homo sapiens]

MEYASDASLDPEAPWPPAPRARACRVLPWALVAGLLLLLLLAAACAVFLACPWAVSG

ARASPGSAASPRLREGPELSPDDPAGLLDLRQGMFAQLVAQNVLLIDGPLSWYSDPG

LAGVSLTGGLSYKEDTKELVVAKAGVYYVFFQLELRRVVAGEGSGSVSLALHLQPLR

SAAGAAALALTVDLPPASSEARNSAFGFQGRLLHLSAGQRLGVHLHTEARARHAWQL

TQGATVLGLFRVTPEIPAGLPSPRSE (SEQ ID NO: 14)

Mouse 4-1BBL
>NM_009404. 3 Mus musculus tumor necrosis factor (ligand)

(CD137L)
superfamily, member 9 (Tnfsf9), mRNA

ATAAAGCACGGGCACTGGCGGGAGACGTGCACTGACCGACCGTGGTAATGGACCAGC

ACACACTTGATGTGGAGGATACCGCGGATGCCAGACATCCAGCAGGTACTTCGTGCC

CCTCGGATGCGGCGCTCCTCAGAGATACCGGGCTCCTCGCGGACGCTGCGCTCCTCT

CAGATACTGTGCGCCCCACAAATGCCGCGCTCCCCACGGATGCTGCCTACCCTGCGG

TTAATGTTCGGGATCGCGAGGCCGCGTGGCCGCCTGCACTGAACTTCTGTTCCCGCC

ACCCAAAGCTCTATGGCCTAGTCGCTTTGGTTTTGCTGCTTCTGATCGCCGCCTGTG

TTCCTATCTTCACCCGCACCGAGCCTCGGCCAGCGCTCACAATCACCACCTCGCCCA

ACCTGGGTACCCGAGAGAATAATGCAGACCAGGTCACCCCTGTTTCCCACATTGGCT

GCCCCAACACTACACAACAGGGCTCTCCTGTGTTCGCCAAGCTACTGGCTAAAAACC

AAGCATCGTTGTGCAATACAACTCTGAACTGGCACAGCCAAGATGGAGCTGGGAGCT

CATACCTATCTCAAGGTCTGAGGTACGAAGAAGACAAAAAGGAGTTGGTGGTAGACA

GTCCCGGGCTCTACTACGTATTTTTGGAACTGAAGCTCAGTCCAACATTCACAAACA

CAGGCCACAAGGTGCAGGGCTGGGTCTCTCTTGTTTTGCAAGCAAAGCCTCAGGTAG

ATGACTTTGACAACTTGGCCCTGACAGTGGAACTGTTCCCTTGCTCCATGGAGAACA

AGTTAGTGGACCGTTCCTGGAGTCAACTGTTGCTCCTGAAGGCTGGCCACCGCCTCA

GTGTGGGTCTGAGGGCTTATCTGCATGGAGCCCAGGATGCATACAGAGACTGGGAGC

TGTCTTATCCCAACACCACCAGCTTTGGACTCTTTCTTGTGAAACCCGACAACCCAT

GGGAATGAGAACTATCCTTCTTGTGACTCCTAGTTGCTAAGTCCTCAAGCTGCTATG

TTTTATGGGGTCTGAGCAGGGGTCCCTTCCATGACTTTCTCTTGTCTTTAACTGGAC

TTGGTATTTATTCTGAGCATAGCTCAGACAAGACTTTATATAATTCACTAGATAGCA

TTAGTAAACTGCTGGGCAGCTGCTAGATAAAAAAAAATTTCTAAATCAAAGTTTATA

TTTATATTAATATATAAAAATAAATGTGTTTGT (SEQ ID NO: 15)

>NP_033430.1 tumor necrosis factor ligand superfamily

member 9 [Mus musculus]

MDQHTLDVEDTADARHPAGTSCPSDAALLRDTGLLADAALLSDTVRPTNAALPTDAA

YPAVNVRDREAAWPPALNFCSRHPKLYGLVALVLLLLIAACVPIFTRTEPRPALTIT

TSPNLGTRENNADQVTPVSHIGCPNTTQQGSPVFAKLLAKNQASLCNTTLNWHSQDG

AGSSYLSQGLRYEEDKKELVVDSPGLYYVFLELKLSPTFTNTGHKVQGWVSLVLQAK

PQVDDFDNLALTVELFPCSMENKLVDRSWSQLLLLKAGHRLSVGLRAYLHGAQDAYR

DWELSYPNTTSFGLFLVKPDNPWE (SEQ ID NO: 16)

Human
>NM_003820.4 Homo sapiens TNF receptor superfamily member

HVEM
14 (TNFRSF14), transcript variant 1, DNA

(CD270)
ATACCGGCCCTTCCCCTCGGCTTTGCCTGGACAGCTCCTGCCTCCCGCAGGGCCCAC

CTGTGTCCCCCAGCGCCGCTCCACCCAGCAGGCCTGAGCCCCTCTCTGCTGCCAGAC

ACCCCCTGCTGCCCACTCTCCTGCTGCTCGGGTTCTGAGGCACAGCTTGTCACACCG

AGGCGGATTCTCTTTCTCTTTCTCTTTCTCTTCTGGCCCACAGCCGCAGCAATGGCG

CTGAGTTCCTCTGCTGGAGTTCATCCTGCTAGCTGGGTTCCCGAGCTGCCGGTCTGA

GCCTGAGGCATGGAGCCTCCTGGAGACTGGGGGCCTCCTCCCTGGAGATCCACCCCC

AAAACCGACGTCTTGAGGCTGGTGCTGTATCTCACCTTCCTGGGAGCCCCCTGCTAC

GCCCCAGCTCTGCCGTCCTGCAAGGAGGACGAGTACCCAGTGGGCTCCGAGTGCTGC

CCCAAGTGCAGTCCAGGTTATCGTGTGAAGGAGGCCTGCGGGGAGCTGACGGGCACA

GTGTGTGAACCCTGCCCTCCAGGCACCTACATTGCCCACCTCAATGGCCTAAGCAAG

TGTCTGCAGTGCCAAATGTGTGACCCAGCCATGGGCCTGCGCGCGAGCCGGAACTGC

TCCAGGACAGAGAACGCCGTGTGTGGCTGCAGCCCAGGCCACTTCTGCATCGTCCAG

GACGGGGACCACTGCGCCGCGTGCCGCGCTTACGCCACCTCCAGCCCGGGCCAGAGG

GTGCAGAAGGGAGGCACCGAGAGTCAGGACACCCTGTGTCAGAACTGCCCCCCGGGG

ACCTTCTCTCCCAATGGGACCCTGGAGGAATGTCAGCACCAGACCAAGTGCAGCTGG

CTGGTGACGAAGGCCGGAGCTGGGACCAGCAGCTCCCACTGGGTATGGTGGTTTCTC

TCAGGGAGCCTCGTCATCGTCATTGTTTGCTCCACAGTTGGCCTAATCATATGTGTG

AAAAGAAGAAAGCCAAGGGGTGATGTAGTCAAGGTGATCGTCTCCGTCCAGCGGAAA

AGACAGGAGGCAGAAGGTGAGGCCACAGTCATTGAGGCCCTGCAGGCCCCTCCGGAC

GTCACCACGGTGGCCGTGGAGGAGACAATACCCTCATTCACGGGGAGGAGCCCAAAC

CACTGACCCACAGACTCTGCACCCCGACGCCAGAGATACCTGGAGCGACGGCTGCTG

AAAGAGGCTGTCCACCTGGCGGAACCACCGGAGCCCGGAGGCTTGGGGGCTCCGCCC

TGGGCTGGCTTCCGTCTCCTCCAGTGGAGGGAGAGGTGGGGCCCCTGCTGGGGTAGA

GCTGGGGACGCCACGTGCCATTCCCATGGGCCAGTGAGGGCCTGGGGCCTCTGTTCT

GCTGTGGCCTGAGCTCCCCAGAGTCCTGAGGAGGAGCGCCAGTTGCCCCTCGCTCAC

AGACCACACACCCAGCCCTCCTGGGCCAGCCCAGAGGGCCCTTCAGACCCCAGCTGT

CTGCGCGTCTGACTCTTGTGGCCTCAGCAGGACAGGCCCCGGGCACTGCCTCACAGC

CAAGGCTGGACTGGGTTGGCTGCAGTGTGGTGTTTAGTGGATACCACATCGGAAGTG

ATTTTCTAAATTGGATTTGAATTCGGCTCCTGTTTTCTATTTGTCATGAAACAGTGT

ATTTGGGGAGATGCTGTGGGAGGATGTAAATATCTTGTTTCTCCTCAAA (SEQ ID

NO: 17)

>NP_003811.2 tumor necrosis factor receptor superfamily

member 14 isoform 1 precursor [Homo sapiens]

MEPPGDWGPPPWRSTPKTDVLRLVLYLTFLGAPCYAPALPSCKEDEYPVGSECCPKC

SPGYRVKEACGELTGTVCEPCPPGTYIAHLNGLSKCLQCQMCDPAMGLRASRNCSRT

ENAVCGCSPGHFCIVQDGDHCAACRAYATSSPGQRVQKGGTESQDTLCQNCPPGTFS

PNGTLEECQHQTKCSWLVTKAGAGTSSSHWVWWFLSGSLVIVIVCSTVGLIICVKRR

KPRGDVVKVIVSVQRKRQEAEGEATVIEALQAPPDVTTVAVEETIPSFTGRSPNH

(SEQ ID NO: 18)

Mouse HVEM
>NM_178931.2 Mus musculus tumor necrosis factor receptor

(CD270)
superfamily, member 14 (herpesvirus entry mediator)

(Tnfrsf14), mRNA

GCTCTTGGCCTGAAGTTTCTTGATCAAGAAAATGGAACCTCTCCCAGGATGGGGGTC

GGCACCCTGGAGCCAGGCCCCTACAGACAACACCTTCAGGCTGGTGCCTTGTGTCTT

CCTTTTGAACTTGCTGCAGCGCATCTCTGCCCAGCCCTCATGCAGACAGGAGGAGTT

CCTTGTGGGAGACGAGTGCTGCCCCATGTGCAACCCAGGTTACCATGTGAAGCAGGT

CTGCAGTGAGCATACAGGCACAGTGTGTGCCCCCTGTCCCCCACAGACATATACCGC

CCATGCAAATGGCCTGAGCAAGTGTCTGCCCTGCGGAGTCTGTGATCCAGACATGGG

CCTGCTGACCTGGCAGGAGTGCTCCAGCTGGAAGGACACTGTGTGCAGATGCATCCC

AGGCTACTTCTGTGAGAACCAGGATGGGAGCCACTGTTCCACATGCTTGCAGCACAC

CACCTGCCCTCCAGGGCAGAGGGTAGAGAAGAGAGGGACTCACGACCAGGACACTGT

ATGTGCTGACTGCCTAACAGGGACCTTCTCACTTGGAGGGACTCAGGAGGAATGCCT

GCCCTGGACCAACTGCAGTGCATTTCAACAGGAAGTAAGACGTGGGACCAACAGCAC

AGACACCACCTGCTCCTCCCAGGTCGTCTACTACGTTGTGTCCATCCTTTTGCCACT

TGTGATAGTGGGAGCTGGGATAGCTGGATTCCTCATCTGCACGCGAAGACACCTGCA

CACCAGCTCAGTGGCCAAGGAGCTGGAGCCTTTCCAGGAACAACAGGAGAACACCAT

CAGGTTTCCAGTCACCGAGGTTGGGTTTGCTGAGACCGAGGAGGAGACAGCCTCCAA

CTGAACAAATTCTGGGTGACAAGACACCGAGGAGACGT (SEQ ID NO: 19)

>NP_849262.1 tumor necrosis factor receptor superfamily

member 14 precursor [Mus musculus]

MEPLPGWGSAPWSQAPTDNTFRLVPCVFLLNLLQRISAQPSCRQEEFLVGDECCPMC

NPGYHVKQVCSEHTGTVCAPCPPQTYTAHANGLSKCLPCGVCDPDMGLLTWQECSSW

KDTVCRCIPGYFCENQDGSHCSTCLQHTTCPPGQRVEKRGTHDQDTVCADCLTGTFS

LGGTQEECLPWTNCSAFQQEVRRGTNSTDTTCSSQVVYYVVSILLPLVIVGAGIAGF

LICTRRHLHTSSVAKELEPFQEQQENTIRFPVTEVGFAETEEETASN (SEQ ID

NO: 20)

Human FGL1
>NM_004467.4 Homo sapiens fibrinogen like 1 (FGL1),

transcript variant 1, mRNA

AATGCAGTTACAGGATCCTGGGAAGCAGAGTGTCTGGATGGAACCTGAGCTGGGTCT

CTGACTCACTTCTGACTTTAGTTTTTTCAAGGGGGAACATGGCAAAGGTGTTCAGTT

TCATCCTTGTTACCACCGCTCTGACAATGGGCAGGGAAATTTCGGCGCTCGAGGACT

GTGCCCAGGAGCAGATGCGGCTCAGAGCCCAGGTGCGCCTGCTTGAGACCCGGGTCA

AACAGCAACAGGTCAAGATCAAGCAGCTTTTGCAGGAGAATGAAGTCCAGTTCCTTG

ATAAAGGAGATGAGAATACTGTCATTGATCTTGGAAGCAAGAGGCAGTATGCAGATT

GTTCAGAGATTTTCAATGATGGGTATAAGCTCAGTGGATTTTACAAAATCAAACCTC

TCCAGAGCCCAGCAGAATTTTCTGTTTATTGTGACATGTCCGATGGAGGAGGATGGA

CTGTAATTCAGAGACGATCTGATGGCAGTGAAAACTTTAACAGAGGATGGAAAGACT

ATGAAAATGGCTTTGGAAATTTTGTCCAAAAACATGGTGAATATTGGCTGGGCAATA

AAAATCTTCACTTCTTGACCACTCAAGAAGACTACACTTTAAAAATCGACCTTGCAG

ATTTTGAAAAAAATAGCCGTTATGCACAATATAAGAATTTCAAAGTTGGAGATGAAA

AGAATTTCTACGAGTTGAATATTGGGGAATATTCTGGAACAGCTGGAGATTCCCTTG

CGGGGAATTTTCATCCTGAGGTGCAGTGGTGGGCTAGTCACCAAAGAATGAAATTCA

GCACGTGGGACAGAGATCATGACAACTATGAAGGGAACTGCGCAGAAGAAGATCAGT

CTGGCTGGTGGTTTAACAGGTGTCACTCTGCAAACCTGAATGGTGTATACTACAGCG

GCCCCTACACGGCTAAAACAGACAATGGGATTGTCTGGTACACCTGGCATGGGTGGT

GGTATTCTCTGAAATCTGTGGTTATGAAAATTAGGCCAAATGATTTTATTCCAAATG

TAATTTAATTGCTGCTGTTGGGCTTTCGTTTCTGCAATTCAGCTTTGTTTAAAGTGA

TTTGAAAAATACTCATTCTGAACATATCCATGCGCAATCATGATAACTGTTGTGAGT

AGTGCTTTTCATTCTTCTCACTTGCCTTTGTTACTTAATGTGCTTTCAGTACAGCAG

ATATGCAATATTCACCAAATAAATGTAGACTGTGTTAATA (SEQ ID NO: 21)

>NP_004458.3 fibrinogen-like protein 1 precursor [Homo

sapiens]

MAKVFSFILVTTALTMGREISALEDCAQEQMRLRAQVRLLETRVKQQQVKIKQLLQE

NEVQFLDKGDENTVIDLGSKRQYADCSEIFNDGYKLSGFYKIKPLQSPAEFSVYCDM

SDGGGWTVIQRRSDGSENFNRGWKDYENGFGNFVQKHGEYWLGNKNLHFLTTQEDYT

LKIDLADFEKNSRYAQYKNFKVGDEKNFYELNIGEYSGTAGDSLAGNFHPEVQWWAS

HQRMKFSTWDRDHDNYEGNCAEEDQSGWWFNRCHSANLNGVYYSGPYTAKTDNGIVW

YTWHGWWYSLKSVVMKIRPNDFIPNVI (SEQ ID NO: 22)

Mouse FGL1
>NM_145594.2 Mus musculus fibrinogen-like protein 1

(Fg11), mRNA

GTTAGAAGTTCCTGGGAGGCTCTGTGTGGATGGACTGAGCCTAGCTAAGTCCTGATT

CATTTTGACTTGAGTTCTCTCAGTGGGAAGAATGGGAAAGATTTACAGCTTCGTCCT

GGTCGCCATTGCTCTGATGATGGGAAGGGAAGGTTGGGCCCTCGAGAGTGAGAACTG

CTTGCGGGAGCAGGTGAGGCTCAGGGCTCAGGTGCACCAGCTTGAGACCCGGGTCAA

ACAACAACAGACCATGATTGCACAGCTCTTGCATGAGAAGGAAGTCCAGTTTCTGGA

TAAAGGATCGGAGAACAGTTTCATTGACCTTGGAGGCAAGAAGCAGTATGCAGATTG

TTCAGAGATTTACAATGACGGATTTAAGCAGAGTGGATTTTACAAAATCAAACCTCT

TCAGAGCCTGGCAGAATTCTCTGTTTATTGTGACATGTCTGATGGAGGGGGATGGAC

TGTAATTCAGAGACGATCTGATGGCAGTGAGAACTTTAACAGGGGTTGGAATGACTA

TGAAAATGGCTTTGGAAACTTTGTCCAAAACAATGGCGAATACTGGCTGGGTAACAA

AAACATTAACTTGCTAACTATTCAAGGAGACTACACTTTAAAAATCGACCTGACAGA

TTTTGAGAAAAACAGCAGCTTCGCACAATACCAAAGTTTTAAAGTTGGTGATAAAAA

GTCTTTTTATGAACTAAATATTGGAGAATATTCTGGCACAGCTGGAGATTCCCTGTC

AGGAACTTTTCATCCTGAAGTACAGTGGTGGGCTAGTCACCAAAGGATGAAGTTCAG

CACGTGGGACAGAGATAACGACAATTACCAAGGAAACTGTGCTGAGGAAGAGCAGTC

TGGCTGGTGGTTTAACAGGTGTCACTCTGCAAACCTGAACGGTGTTTACTACCGTGG

TTCCTACAGGGCAGAAACGGATAATGGTGTTGTGTGGTACACCTGGCATGGGTGGTG

GTATTCCTTGAAATCTGTGGTTATGAAAATTAGGCCAAGTGATTTTATTCCAAATAT

TATTTAGTTGCCCTCATTGGGATCTCCTTTCTGTAATTCATCTTGGTTTACTTGAAA

ATAAATATTTGAAAAAGATATAATTCTGAATAACACA (SEQ ID NO: 23)

>NP_663569.2 fibrinogen-like protein 1 precursor [Mus

musculus]

MGKIYSFVLVAIALMMGREGWALESENCLREQVRLRAQVHQLETRVKQQQTMIAQLL

HEKEVQFLDKGSENSFIDLGGKKQYADCSEIYNDGFKQSGFYKIKPLQSLAEFSVYC

DMSDGGGWTVIQRRSDGSENFNRGWNDYENGFGNFVQNNGEYWLGNKNINLLTIQGD

YTLKIDLTDFEKNSSFAQYQSFKVGDKKSFYELNIGEYSGTAGDSLSGTFHPEVQWW

ASHQRMKFSTWDRDNDNYQGNCAEEEQSGWWFNRCHSANLNGVYYRGSYRAETDNGV

VWYTWHGWWYSLKSVVMKIRPSDFIPNII (SEQ ID NO: 24)

Human OX-2
>NM_005944.7 Homo sapiens CD200 molecule (CD200),

(CD200)
transcript variant 1, mRNA

AGAGCTCCAGGCGCACATCCGCAGTCAGCCACCTCGCGCGCGCCTCCAGGAGCAAGG

ATGGAGAGGCTGGTGATCAGGATGCCCTTCTCTCATCTGTCTACCTACAGCCTGGTT

TGGGTCATGGCAGCAGTGGTGCTGTGCACAGCACAAGTGCAAGTGGTGACCCAGGAT

GAAAGAGAGCAGCTGTACACACCTGCTTCCTTAAAATGCTCTCTGCAAAATGCCCAG

GAAGCCCTCATTGTGACATGGCAGAAAAAGAAAGCTGTAAGCCCAGAAAACATGGTC

ACCTTCAGCGAGAACCATGGGGTGGTGATCCAGCCTGCCTATAAGGACAAGATAAAC

ATTACCCAGCTGGGACTCCAAAACTCAACCATCACCTTCTGGAATATCACCCTGGAG

GATGAAGGGTGTTACATGTGTCTCTTCAATACCTTTGGTTTTGGGAAGATCTCAGGA

ACGGCCTGCCTCACCGTCTATGTACAGCCCATAGTATCCCTTCACTACAAATTCTCT

GAAGACCACCTAAATATCACTTGCTCTGCCACTGCCCGCCCAGCCCCCATGGTCTTC

TGGAAGGTCCCTCGGTCAGGGATTGAAAATAGTACAGTGACTCTGTCTCACCCAAAT

GGGACCACGTCTGTTACCAGCATCCTCCATATCAAAGACCCTAAGAATCAGGTGGGG

AAGGAGGTGATCTGCCAGGTGCTGCACCTGGGGACTGTGACCGACTTTAAGCAAACC

GTCAACAAAGGCTATTGGTTTTCAGTTCCGCTATTGCTAAGCATTGTTTCCCTGGTA

ATTCTTCTCGTCCTAATCTCAATCTTACTGTACTGGAAACGTCACCGGAATCAGGAC

CGAGAGCCCTAAATAAGTCACACAGCACCCTGAAAGTGATTCCCTGGTCTACTTGAA

TTTGACACAAGAGAAAAGCAGGAGGAAAAGGGGCCATTCTCCAAAGGACCTGAAAGA

GCAAAAGAGGTGGGAGCGAAAGCCTTAAGGATCCCACGACTTTTTACTGCCATCTGA

GCTACTCAGTGTTTGAATCCCAAGAGGAAGTCAGTTTACCTCTCAGGTCTGTTGTAG

GACTTGATTTTGTAAAGCAATGCCATGTTATGTGGTTGAAAGGGCACTGGACTTAGT

TAGTATCAGGAGCACTGAGCTCACAGACTGACTTGGGCTCCTACTGGTGGGGACCTC

TGTTAGTCACTTTACCTCATCCAAAGTATAAAGGAATTGGACCAAATAATTTACCAC

ATAGCTCTAAAACTTAATTTAAAATGTAATTCCAGAAAAAAAAAGGGAATAAGCAAA

GGGGGAAGAATTGAAAGAGAGAGAGAAGAAAGAATACAGAGAGCTTACCTTTTGCCT

TTCTGTTGATGTTACATCTCTTCTTCCTATGTTCTTAGGTCTATGAGTCTGTTTCCC

CATCATTTGGTATCTAGTCCAGTTCCTGCTTACTGCTTTGCTAATAGCTGGCCTTGC

TAGAATCCTTGGTTTCACTGCTGTTCTTCATGTGCTTCTATGAGATTTACTCCAACA

CAAATAGGACTGAATTTATTGTGAAGTAACATTGGCAATCTTAACTTATTCATTTAA

CTTATTTTTATAGCTAGATAAATATTGTTAGTCTTAGACAATAGCTCACATTTTTTG

AGAAGCATGCCCTCCCTGTCCATTTGTCTTATAACATGACCCAGCCCTATTTTACGT

CATTCTAAATTCAGCCTCATATAATGAAAATACATTATGAAAACAGATGTTTAGGAG

ATTTCCTGTATAGCAGTCAGCCAATTCATATGCTTTGTCTCTGCTGGCTTCTTTTTC

CATGCGTTAACTTTTCCCAATAGCAGAGGAGGCAAATATGAGCATACAATCCCTTTG

TTCTAAAGATATTGTTCCAGCTAGTGGAATGATGTTGAATCTTTAATAACCATAATT

AGTTGCTTTTTCAGTATCTTCTGCTTTGTCTGTGTCTATCCAGTGGCCTAGGAATTA

AAGTGTAAGTTGTTTTCGCTGTTAAATTGGATATTTATATATATATATAGCAAGATT

TTCATGTGTTATTTAATTCTGTATTGTTTCTTATATTTGTAGTAAAATATTGAACAA

TTAAAAGTGTTGACTCCAAA (SEQ ID NO: 25)

>NP_005935.4 OX-2 membrane glycoprotein isoform a

precursor [Homo sapiens]

MERLVIRMPFSHLSTYSLVWVMAAVVLCTAQVQVVTQDEREQLYTPASLKCSLQNAQ

EALIVTWQKKKAVSPENMVTFSENHGVVIQPAYKDKINITQLGLQNSTITFWNITLE

DEGCYMCLFNTFGFGKISGTACLTVYVQPIVSLHYKFSEDHLNITCSATARPAPMVF

WKVPRSGIENSTVTLSHPNGTTSVTSILHIKDPKNQVGKEVICQVLHLGTVTDFKQT

VNKGYWFSVPLLLSIVSLVILLVLISILLYWKRHRNQDREP (SEQ ID NO: 26)

Mouse OX-2
>NM_010818.3 Mus musculus CD200 antigen (Cd200),

(CD200)
transcript variant 1, mRNA

GGGCGTGGTTGGTTGGTCGTCTCTTCCTCCACACTAGAGGAGCTGTAGAGTCTGCCT

GTGCAGTGGAGGGGGCTCTCTCTACGGCGAATAGTAGTGTCCCTGCTCACAGGTGTT

GCGGAGATATCCTCCATCGTGGAAGAGCTCAGACCCCGAGAAGCTGGTGTCTAGCTG

CGGCCCAGAGCAAGGATGGGCAGTCTGGTATTCAGGAGACCTTTCTGCCATCTCTCC

ACCTACAGCCTGATTTGGGGCATGGCAGCAGTAGCGCTGAGCACAGCTCAAGTGGAA

GTGGTGACCCAGGATGAAAGAAAGGCGCTGCACACAACTGCATCCTTACGATGTTCT

CTAAAAACATCCCAGGAACCCTTGATTGTGACATGGCAGAAAAAGAAAGCCGTGAGC

CCAGAAAACATGGTCACCTACAGCAAAACCCATGGGGTTGTAATCCAGCCTGCCTAC

AAAGACAGGATAAATGTCACAGAGCTGGGACTCTGGAACTCAAGCATCACCTTCTGG

AACACAACATTGGAAGATGAGGGCTGCTACATGTGTCTCTTCAACACGTTTGGTTCT

CAGAAGGTCTCAGGAACAGCTTGCCTTACCCTCTATGTACAGCCCATAGTACACCTT

CACTACAACTATTTTGAAGACCACCTAAACATCACTTGCTCTGCGACTGCCCGTCCA

GCCCCTGCCATCTCCTGGAAGGGTACTGGGACAGGAATTGAGAATAGTACCGAGAGT

CACTTCCATTCAAATGGGACTACATCTGTCACCAGCATCCTCCGGGTCAAAGACCCC

AAAACTCAAGTTGGGAAGGAAGTGATCTGCCAGGTTTTATACCTGGGGAATGTGATT

GACTACAAGCAGAGTCTGGACAAAGGATTTTGGTTTTCAGTTCCACTGTTGCTAAGC

ATTGTTTCTCTGGTAATTCTTCTGATCTTGATCTCCATCTTACTATACTGGAAACGT

CACCGAAATCAGGAGCGGGGTGAATCATCACAGGGGATGCAAAGAATGAAATAAGAG

CTCTAAAGAAATTATACAGAACCCTGAACGTGTTTCCCTGGTCTACTTGAATCTGAT

GTGAAAGAAAAGCAGGAGGGAAAAGGCCATTCTCCATAGGACCTAAGGAGAGCAAAA

GACCAGACACGAGCCTGTGAGGGATTTGACTTTTTGCTGTTGTCCCAGGTCCTCGGT

GTTTGCATTCCAAGAGGAAGTCGAGTGCCTCGGGTCTGTTGTAGGACTTGATTTTTT

TTTTTTTTGTAGAGCAATGCAGTGCCATGCTGTTAGAAAGGCTCCAGACTTAGAACC

ACCAGTGCCAAGCCAGCTCTCAGACCGACTAGGGCTCCCATCGGAGGAACAAATCGT

AGTCAACTTACCTCACAGAGCTCTCTGGTCCTTACACAAAGTAGAAAGGAGTGGGAC

CAGAAAATTGGCCATGTCTGAAATCTGATGGAATTTTTAGGAAGAAAACTGAAGAAT

AAGCAAAAGAAGAAAGAACACAGAAGGGTCCAAAGAGCTTCTGAGAGTACCTTTTGC

CTTTCTGTTGGTGTCCCAGCTCTGGTTTTGTTCTTAGGTCCGCCAGTGTGTTTCCCT

GTTGTTTGAGTATCTAGTTGACTACCTGCTACTGTTCTGCTGATGGTTGGCCTTGCT

AGAATCCCTGACTCCCCTGCCGTTCTCTATGTGCTTCTATGAGGGTTACTATGATGA

AAATAGAGCAGAAGATAGTGTGAAGTAACATTGGCAACTGTAATGTGTCCATTTAAC

TTATTTTTATAGCACTTAGGCAATATTGTTAGTCTTAGTGAGTAGTTCACATCTTTA

CAAAAGCATGCTCTCCCTATCCATTGGGCCCACAATAACACTCTCTTTGAGGCCATT

CTGAATCCTGTCTCGTGTAATGATAATATATTATGAAAACAGATACTTTAAGAATTT

CCTGTACAGCAGTCAGTTGTTTATTCTCTCTCTCTCTCTCTCTCTCTCTCTCCCTCC

CCCACCCCAGCTTCTTTTTCTGTGACTTTGTTTTTCATAAAGAGAAGGCATCTCCTG

AATACAATCGCTTTGTTCTGAAGACATCGTGAACTATTAATTCTTAACCCTTTGACA

AAACTAGTGAAGTTGTTTTCTGTATCTTTTGCTTCATCTGTCTTTATAGAGTGACCT

AGGAATTCAAGTGTAAGTTGTTTCCATTGTTGAACTGGATATTTATATACTTGGTAT

GCTTTTCACGTGTTATTTAATTCTGTATAATTTCCTATATTTGTATTAAAATATTGA

GCAATTAAAAGTGTCAACTAAATATTTGATGTGGCATTCCCTTGAGAAATATAGAAA

TAAAGAATAAAAAAAAAAAAAAAAAA (SEQ ID NO: 27)

>NP_034948.3 OX-2 membrane glycoprotein isoform 1

precursor [Mus musculus]

MGSLVFRRPFCHLSTYSLIWGMAAVALSTAQVEVVTQDERKALHTTASLRCSLKTSQ

EPLIVTWQKKKAVSPENMVTYSKTHGVVIQPAYKDRINVTELGLWNSSITFWNTTLE

DEGCYMCLFNTFGSQKVSGTACLTLYVQPIVHLHYNYFEDHLNITCSATARPAPAIS

WKGTGTGIENSTESHFHSNGTTSVTSILRVKDPKTQVGKEVICQVLYLGNVIDYKQS

LDKGFWFSVPLLLSIVSLVILLILISILLYWKRHRNQERGESSQGMQRMK

(SEQ ID NO: 28)

Human
>NM_009587.3 Homo sapiens galectin 9 (LGALS9), transcript

Galectin-9
variant 1, mRNA

CTTTGTTAAGTCGTTCCCTCTACAAAGGACTTCCTAGTGGGTGTGAAAGGCAGCGGT

GGCCACAGAGGCGGCGGAGAGATGGCCTTCAGCGGTTCCCAGGCTCCCTACCTGAGT

CCAGCTGTCCCCTTTTCTGGGACTATTCAAGGAGGTCTCCAGGACGGACTTCAGATC

ACTGTCAATGGGACCGTTCTCAGCTCCAGTGGAACCAGGTTTGCTGTGAACTTTCAG

ACTGGCTTCAGTGGAAATGACATTGCCTTCCACTTCAACCCTCGGTTTGAAGATGGA

GGGTACGTGGTGTGCAACACGAGGCAGAACGGAAGCTGGGGGCCCGAGGAGAGGAAG

ACACACATGCCTTTCCAGAAGGGGATGCCCTTTGACCTCTGCTTCCTGGTGCAGAGC

TCAGATTTCAAGGTGATGGTGAACGGGATCCTCTTCGTGCAGTACTTCCACCGCGTG

CCCTTCCACCGTGTGGACACCATCTCCGTCAATGGCTCTGTGCAGCTGTCCTACATC

AGCTTCCAGAACCCCCGCACAGTCCCTGTTCAGCCTGCCTTCTCCACGGTGCCGTTC

TCCCAGCCTGTCTGTTTCCCACCCAGGCCCAGGGGGCGCAGACAAAAACCTCCCGGC

GTGTGGCCTGCCAACCCGGCTCCCATTACCCAGACAGTCATCCACACAGTGCAGAGC

GCCCCTGGACAGATGTTCTCTACTCCCGCCATCCCACCTATGATGTACCCCCACCCC

GCCTATCCGATGCCTTTCATCACCACCATTCTGGGAGGGCTGTACCCATCCAAGTCC

ATCCTCCTGTCAGGCACTGTCCTGCCCAGTGCTCAGAGGTTCCACATCAACCTGTGC

TCTGGGAACCACATCGCCTTCCACCTGAACCCCCGTTTTGATGAGAATGCTGTGGTC

CGCAACACCCAGATCGACAACTCCTGGGGGTCTGAGGAGCGAAGTCTGCCCCGAAAA

ATGCCCTTCGTCCGTGGCCAGAGCTTCTCAGTGTGGATCTTGTGTGAAGCTCACTGC

CTCAAGGTGGCCGTGGATGGTCAGCACCTGTTTGAATACTACCATCGCCTGAGGAAC

CTGCCCACCATCAACAGACTGGAAGTGGGGGGCGACATCCAGCTGACCCATGTGCAG

ACATAGGCGGCTTCCTGGCCCTGGGGCCGGGGGCTGGGGTGTGGGGCAGTCTGGGTC

CTCTCATCATCCCCACTTCCCAGGCCCAGCCTTTCCAACCCTGCCTGGGATCTGGGC

TTTAATGCAGAGGCCATGTCCTTGTCTGGTCCTGCTTCTGGCTACAGCCACCCTGGA

ACGGAGAAGGCAGCTGACGGGGATTGCCTTCCTCAGCCGCAGCAGCACCTGGGGCTC

CAGCTGCTGGAATCCTACCATCCCAGGAGGCAGGCACAGCCAGGGAGAGGGGAGGAG

TGGGCAGTGAAGATGAAGCCCCATGCTCAGTCCCCTCCCATCCCCCACGCAGCTCCA

CCCCAGTCCCAAGCCACCAGCTGTCTGCTCCTGGTGGGAGGTGGCCTCCTCAGCCCC

TCCTCTCTGACCTTTAACCTCACTCTCACCTTGCACCGTGCACCAACCCTTCACCCC

TCCTGGAAAGCAGGCCTGATGGCTTCCCACTGGCCTCCACCACCTGACCAGAGTGTT

CTCTTCAGAGGACTGGCTCCTTTCCCAGTGTCCTTAAAATAAAGAAATGAAAATGCT

TGTTGGCACATTCA (SEQ ID NO: 29)

>NP_033665.1 galectin-9 isoform long [Homo sapiens]

MAFSGSQAPYLSPAVPFSGTIQGGLQDGLQITVNGTVLSSSGTRFAVNFQTGFSGND

IAFHFNPRFEDGGYVVCNTRQNGSWGPEERKTHMPFQKGMPFDLCFLVQSSDFKVMV

NGILFVQYFHRVPFHRVDTISVNGSVQLSYISFQNPRTVPVQPAFSTVPFSQPVCFP

PRPRGRRQKPPGVWPANPAPITQTVIHTVQSAPGQMESTPAIPPMMYPHPAYPMPFI

TTILGGLYPSKSILLSGTVLPSAQRFHINLCSGNHIAFHLNPRFDENAVVRNTQIDN

SWGSEERSLPRKMPFVRGQSFSVWILCEAHCLKVAVDGQHLFEYYHRLRNLPTINRL

EVGGDIQLTHVQT (SEQ ID NO: 30)

Mouse
>NM_010708.2 Mus musculus lectin, galactose binding,

Galectin-9
soluble 9 (Lgals9), transcript variant 1, mRNA

GCCAAATAGCTGTGGTTTCTGTTTCCTAGCTCAGCCCTGCCCTGCGCAGAGTTCTGT

CGTCCACCATCGAGTGAGGAAGAGAGCATTGGTTCCCCTGAGATAGAAGAGATGGCT

CTCTTCAGTGCCCAGTCTCCATACATTAACCCGATCATCCCCTTTACTGGACCAATC

CAAGGAGGGCTGCAGGAGGGACTTCAGGTGACCCTCCAGGGGACTACCAAGAGTTTT

GCACAAAGGTTTGTGGTGAACTTTCAGAACAGCTTCAATGGAAATGACATTGCCTTC

CACTTCAACCCCCGGTTTGAGGAAGGAGGGTATGTGGTTTGCAACACGAAGCAGAAC

GGACAGTGGGGTCCTGAGGAGAGAAAGATGCAGATGCCCTTCCAGAAGGGGATGCCC

TTTGAGCTTTGCTTCCTGGTGCAGAGGTCAGAGTTCAAGGTGATGGTGAACAAGAAA

TTCTTTGTGCAGTACCAACACCGCGTACCCTACCACCTCGTGGACACCATCGCTGTC

TCCGGCTGCTTGAAGCTGTCCTTTATCACCTTCCAGAACTCTGCAGCCCCTGTCCAG

CATGTCTTCTCCACAGTGCAGTTCTCTCAGCCAGTCCAGTTCCCACGGACCCCTAAG

GGGCGCAAACAGAAAACTCAGAACTTTCGTCCTGCCCACCAGGCACCCATGGCTCAA

ACTACCATCCATATGGTTCACAGCACCCCTGGACAGATGTTCTCTACTCCTGGAATC

CCTCCTGTGGTGTACCCCACCCCAGCCTATACCATACCTTTCTACACCCCCATTCCA

AATGGGCTTTACCCGTCCAAGTCCATCATGATATCAGGCAATGTCTTGCCAGATGCT

ACGAGGTTCCATATCAACCTTCGCTGTGGAGGTGACATTGCTTTCCACCTGAACCCC

CGTTTCAATGAGAATGCTGTTGTCCGAAACACTCAGATCAACAACTCCTGGGGGCAG

GAAGAGCGAAGTCTGCTTGGGAGGATGCCCTTCAGTCGAGGCCAGAGCTTCTCGGTG

TGGATCATATGTGAAGGTCACTGCTTCAAGGTAGCTGTGAATGGTCAACACATGTGT

GAATATTACCACCGCCTGAAGAACTTGCAGGATATCAACACTCTAGAAGTGGCGGGT

GATATCCAGCTGACCCACGTGCAGACATAGGCAAGGTCTCTGGCCTAGGGATAAGGG

CTGGAGCACTCTGCCTGTGTCTTATCTTTCCCCTGTCTCAGCCCTGGCACCATCAGA

AGAGATCATCACTTATAGGAATTCCAGGAAGGTGAAATTCCCAATTGACTCCCTCCA

CAAAGGGGGTTTTCTAGGCTGTGTGGCACATGGCTGTCAGCCCATAGTCTGAGCCAT

TGCCCCCAAGCTAGCTATATACTGAGGGAAGTGACCCTCCTGGGTTTGCTCAGATCT

CTGATCGTTCCCCCCTCTGTGGCCCTTTTCTTTCACCCCTCCAGGAGAGCCACCCTG

ATATCATCCCACTGGCCTCCAACTGACCCACAATGTCCACAGTAACTTTCCCCCATT

CTCACCCAGTATCCATAAAATAAAGAAATAATATTGCTTGTCTACAC (SEQ ID

NO: 31)

>NP_034838.2 galectin-9 isoform 1 [Mus musculus]

MALFSAQSPYINPIIPFTGPIQGGLQEGLQVTLQGTTKSFAQRFVVNFQNSFNGNDI

AFHFNPRFEEGGYVVCNTKQNGQWGPEERKMQMPFQKGMPFELCFLVQRSEFKVMVN

KKFFVQYQHRVPYHLVDTIAVSGCLKLSFITFQNSAAPVQHVFSTVQFSQPVQFPRT

PKGRKQKTQNFRPAHQAPMAQTTIHMVHSTPGQMFSTPGIPPVVYPTPAYTIPFYTP

IPNGLYPSKSIMISGNVLPDATRFHINLRCGGDIAFHLNPRFNENAVVRNTQINNSW

GQEERSLLGRMPFSRGQSFSVWIICEGHCFKVAVNGQHMCEYYHRLKNLQDINTLEV

AGDIQLTHVQT (SEQ ID NO: 32)

Human PVR
>NM_006505.5 Homo sapiens PVR cell adhesion molecule

(CD155)
(PVR), transcript variant 1, mRNA

AGTCACTTGTCTGGAGCTTGAAGAAGTGGGTATTCCCCTTCCCACCCCAGGCACTGG

AGGAGCGGCCCCCCGGGGATTCCAGGACCTGAGCTCCGGGAGCTGGACTCGCAGCGA

CCGCGGCAGAGCGAGCGGGCGCCGGGAAGCGAGGAGACGCCCGCGGGAGGCCCAGCT

GCTCGGAGCAACTGGCATGGCCCGAGCCATGGCCGCCGCGTGGCCGCTGCTGCTGGT

GGCGCTACTGGTGCTGTCCTGGCCACCCCCAGGAACCGGGGACGTCGTCGTGCAGGC

GCCCACCCAGGTGCCCGGCTTCTTGGGCGACTCCGTGACGCTGCCCTGCTACCTACA

GGTGCCCAACATGGAGGTGACGCATGTGTCACAGCTGACTTGGGCGCGGCATGGTGA

ATCTGGCAGCATGGCCGTCTTCCACCAAACGCAGGGCCCCAGCTATTCGGAGTCCAA

ACGGCTGGAATTCGTGGCAGCCAGACTGGGCGCGGAGCTGCGGAATGCCTCGCTGAG

GATGTTCGGGTTGCGCGTAGAGGATGAAGGCAACTACACCTGCCTGTTCGTCACGTT

CCCGCAGGGCAGCAGGAGCGTGGATATCTGGCTCCGAGTGCTTGCCAAGCCCCAGAA

CACAGCTGAGGTTCAGAAGGTCCAGCTCACTGGAGAGCCAGTGCCCATGGCCCGCTG

CGTCTCCACAGGGGGTCGCCCGCCAGCCCAAATCACCTGGCACTCAGACCTGGGCGG

GATGCCCAATACGAGCCAGGTGCCAGGGTTCCTGTCTGGCACAGTCACTGTCACCAG

CCTCTGGATATTGGTGCCCTCAAGCCAGGTGGACGGCAAGAATGTGACCTGCAAGGT

GGAGCACGAGAGCTTTGAGAAGCCTCAGCTGCTGACTGTGAACCTCACCGTGTACTA

CCCCCCAGAGGTATCCATCTCTGGCTATGATAACAACTGGTACCTTGGCCAGAATGA

GGCCACCCTGACCTGCGATGCTCGCAGCAACCCAGAGCCCACAGGCTATAATTGGAG

CACGACCATGGGTCCCCTGCCACCCTTTGCTGTGGCCCAGGGCGCCCAGCTCCTGAT

CCGTCCTGTGGACAAACCAATCAACACAACTTTAATCTGCAACGTCACCAATGCCCT

AGGAGCTCGCCAGGCAGAACTGACCGTCCAGGTCAAAGAGGGACCTCCCAGTGAGCA

CTCAGGCATGTCCCGTAACGCCATCATCTTCCTGGTTCTGGGAATCCTGGTTTTTCT

GATCCTGCTGGGGATCGGGATTTATTTCTATTGGTCCAAATGTTCCCGTGAGGTCCT

TTGGCACTGTCATCTGTGTCCCTCGAGTACAGAGCATGCCAGCGCCTCAGCTAATGG

GCATGTCTCCTATTCAGCTGTGAGCAGAGAGAACAGCTCTTCCCAGGATCCACAGAC

AGAGGGCACAAGGTGACAGCGTCGGGACTGAGAGGGGAGAGAGACTGGAGCTGGCAA

GGACGTGGGCCTCCAGAGTTGGACCCGACCCCAATGGATGAAGACCCCCTCCAAAGA

GACCAGCCTCCCTCCCTGTGCCAGACCTCAAAACGACGGGGGCAGGTGCAAGTTCAT

AGGTCTCCAAGACCACCCTCCTTTCATTTGCTAGAAGGACTCACTAGACTCAGGAAA

GCTGTTAGGCTCACAGTTACAGTTTATTACAGTAAAAGGACAGAGATTAAGATCAGC

AAAGGGAGGAGGTGCACAGCACACGTTCCACGACAGATGAGGCGACGGCTTCCATCT

GCCCTCTCCCAGTGGAGCCATATAGGCAGCACCTGATTCTCACAGCAACATGTGACA

ACATGCAAGAAGTACTGCCAATACTGCCAACCAGAGCAGCTCACTCGAGATCTTTGT

GTCCAGAGTTTTTTGTTTGTCTTGAGACAGGGTCTGGCTCTGTTGGCAGACTAGAGT

ACAGTGGTGAGATCACAGTTCATTGCAGCCTTGACTTCTCAACGCCAAGTCATCCTC

CCACCTCAGCCTCCTGAGTAGCTATGACTACAGGTATGTGCCACCACGTCTGGCTAA

TCTTTTTATTATTTGTAAAGTCGAGGTTTCCCTGTGTTGCCCAGGCTGGTCTTGAAC

TCTTGGCTCCAAGTGATACTTCTGCCTTGGCCTCCCAAAGTGCTGAATTAAGCAGCT

CACCATCCACACGGCTGACCTCATACATCAAGCCAATACCGTGTGGCCCAAGACCCC

CACCATAAATCACATCATTAGCATGAACCACCCAGAGTGGCCCAAGACTCCAAGATC

AGCTACCAGGCAGGATATTCCAAGGGCTTAGAGATGAATGCCCAGGAGCTGAGGATA

AAGGGCCCGATCTTTCTTTGGGCAAGGTTAAGCCTTTACTGCATAGCAGACCACACA

GAAGGGTGTGGGCCACCAGAGAATTTTGGTAAAAATTTGGCCTCTGGCCTTGAGCTT

CTAAATCTCTGTATCCGTCAGATCTCTGTGGTTACAAGAAACAGCCACTGACCCTGG

TCACCAGAGGCTGCAATTCAGGCCGCAAGCAGCTGCCTGGGGGGTGTCCAAGGAGCA

GAGAAAACTACTAGATGTGAACTTGAAGAAGGTTGTCAGCTGCAGCCACTTTCTGCC

AGCATCTGCAGCCACTTTCTGCCAGCATCTGCAGCCAGCAAGCTGGGACTGGCAGGA

AATAACCCACAAAAGAAGCAAATGCAATTTCCAACACAAGGGGGAAGGGATGCAGGG

GGAGGCAGCGCTGCAGTTGCTCAGGACACGCTCCTATAGGACCAAGATGGATGCGAC

CCAAGACCCAGGAGGCCCAGCTGCTCAGTGCAACTGACAAGTTAAAAAGGTCTATGA

TCTTGAGGGCAGACAGCAGAATTCCTCTTATAAAGAAAACTGTTTGGGAAAATACGT

TGAGGGAGAGAAGACCTTGGGCCAAGATGCTAAATGGGAATGCAAAGCTTGAGCTGC

TCTGCAAGAGAAAATAAGCAGGACAGAGGATTTGCTCTGGACAGAGATGGAAGAGCC

GGGAACAGAGAAGTGTGGGGAAGAGATAGGAACCAGCAGGATGGCAGGGGCAAAGGG

CTCAAGGGTGAGGAGGCCAGTGGGACCCCACAGAGTTGGGGAGATAAAGGAACATTG

GTTGCTTTGGTGGCACGTAAGCTCCTTGTCTGTCTCCAGCACCCAGAATCTCATTAA

AGCTTATTTATTGTACCTCCAGCGGCTGTGTGCAATGGGGTCTTTTGTGGAAATCAA

GGAGCAGACAGGTTTCATGTGTACTGTCACCACGTGGGATGGAACCAGAGGCATGGA

AGCAAGACGCTAAATGAAGAGGGCCATAAGGGCTGGGATTCCCAGGCACCTTAGGAA

CAGCTTGTCTTTTTTTTTTTCCTCTCCAAAAAAAATGTTTAAGGGACGGTGTCTCCT

GTCACCCAGGCTGGAGTGCAATGGCACGATCATAGCTCATTGCAGCCTCTAACTCCG

GGGCTCAAGCAATCCTCCCACCTCAGCCTACCAAGTAGCTGTGACCACAGCTGCCCC

TCACCATGCTAAGCTAATTTTTTTAATTAGATAGTACATAAACGTCCCAAAATTAGA

AGATAAAAAGACATGAGGGATCCATTCTAATTTGTGTTTGGAGTGTAATGGTCCAGC

TCCATTCTTCTGCACATGGATATCCAGTTTTACACAACACTGTGAATGTAATGAATG

CCACTGAATCATACACTCAAAAATAGCTAAAATGGCAAATTGTCTGTTATCTCTTTT

TAACCACCATTTTTGAAAATTAATTATACCAAAAAACCATTGAATAGTGCACTTTAT

TTATTTATTTATTTGTTTATTTATTTATTTATTTTAGAAATAAGAGTCTCACTTTGT

TGCCCAGGCTGGAGTGCAGTGGCGTGATCATGGCTCATTGCAGCCTCGACCTGCTGG

GCTCGGGCTATCCTTCCATCTCAGCCTCCCGAGTAGCTGGGACTATAGGTGGGCGCC

ACCCCACCTGGCTAAATCTCTTTTTAACTTTTGTAGAGATAGGCATCTCGCTATGTT

GCCTAGGCTGGGCTGGAACTCCTGGGCTCAAGTGCTCCTCCTGCCTTGGCCTCCCAA

AGCGCTAGGATTACAGATGTGAGCCACCGCGCCCACCCTGAACCTTACTTTTTTTGC

TCAGTTTCTGGTAATTCAGAGAATGCCTCCTGAGTTGTTCTACACCCACCTCATATT

CCATGGGAGGGCTGTACAGGGCTTTTTTAACGAGGCCTCTAAGGACAGGCATTTGTA

TCCTTTCCAGCCTTTCACTATTACAATGTTGTAGTGAATAACTTTACACACTGTCAT

TTATTTTACTTTTTTTTTTTTTTATTTTAGAGAAAGGAATCTTGCCATCTTGCCCAG

GCTGGTCTCAAATTCCTGGGCCCAAACAATCCTCCCGCCTTGGCCTCCTAAAGTACT

GGGATTTATAGGCATAAGCCACCGTGCCTGGCCAATGCACACTGTCATTTAGCTCAT

GTTAACACCTGAGTGTAGGACACACTCCTGGAGGTGGAATTGCTGGGCCAAAGAGTA

TGTTTCTTGTCATTGTGATAGATATTGACAAATGAACCCTCACAGAAGTTGTGCTGA

GTTCTGTTCCCACCAGCGACGTAGGCGATGACCTTTTTCTGGAGGGAGGGGGCATCC

TTGGAGTCCACAGAGCCAGGAATGGAGAGTGGGCCCAGAATTTTGGTATAGGTGTTG

TATAAACTTATAGTAAGGTTAAGAAAACCGCAACTATCCTTATCAGAGACTTGGCGG

GGGGCAGGGTATGATGGAGATCATAAGGAGGCTAAAACACTCCACACCCTCCCTCTG

CATTGCTCCTGCACGGGAGTCGGGAATCTTTTCAGGTTGATACGATCTCACCTTGAG

GAGCTGTGAGGTCCCAGAAGCCTCTGGGTTGCAGATTGCTTGGGGTGAAAATGTCTG

TGCTACTGAAATCTAACTTTTTACAAAAAATTACGGGCTGGGCGCAGTGGCTCACGC

CTGTAATCCCAGCACTTTGGGAGGCTGCAGCGGGTGGATCACTTGAGGTAAGGAGTT

CAAGACCAGACCATAGTGAAACCGTGTCTCTACAAAAAAAATTAGCCAGGTGTGGTG

GTGCATGCTTGTAATCCCAGCTACTCAGAAGGCTGAGGTGGGAGAATCCCTTGAACC

CGGGAAGTGGAGGCTGGAGTAAACCATGATCGAGTTACTGCACTCCAGCCTGGGTGA

CAAGAGTGAGACTCTGTCTCCAAAAAAAAAAAAAAAAAAAAAAAAACTGGATTGCCT

GGCTCTACTCCGGGCACAGCATGCAGGCCCAGTTCTGCTGCTCTGCTGTTTGTTCTG

CTTTCCTCCACATATTGGCATCACCCTCTGGTGCCAAGATGGCTGCTGCATTCCAGG

CATCACATCCAGACTCAGACCCAGAGAAGCTGCCCATCCCTACCTGGGTGAGCCTTT

GTAGGAACGAGAAACCGCATCCAGCAGCAGAAACCTCACCCAGCAGCGTCTTTTCCG

GTCTCATTCACCAGCGCCGCCCACCGCTCAACCAATCCCTGGCCAAAAGAATGGGAC

CGCCTGGAAGGCTGGACCAAACAGGACCTGCCCTCTGGGGCTGGGGAGAGGCCCAGA

TGAAGGCTGCAGGACAGGATGGACTCCTAGACCTCTGTTACCAGCAGTGACTACCTC

TGTCTGGGTGGTTGGAACATGTTTGAATTTTATTCTAAGTACTGTCTACAAGTTCTG

CAATAAACCTTGACTCTTCTTTTAATAATGCAAAA (SEQ ID NO: 33)

>NP_006496.4 poliovirus receptor isoform alpha precursor

[Homo sapiens]

MARAMAAAWPLLLVALLVLSWPPPGTGDVVVQAPTQVPGFLGDSVTLPCYLQVPNME

VTHVSQLTWARHGESGSMAVFHQTQGPSYSESKRLEFVAARLGAELRNASLRMFGLR

VEDEGNYTCLFVTFPQGSRSVDIWLRVLAKPQNTAEVQKVQLTGEPVPMARCVSTGG

RPPAQITWHSDLGGMPNTSQVPGFLSGTVTVTSLWILVPSSQVDGKNVTCKVEHESF

EKPQLLTVNLTVYYPPEVSISGYDNNWYLGQNEATLTCDARSNPEPTGYNWSTTMGP

LPPFAVAQGAQLLIRPVDKPINTTLICNVTNALGARQAELTVQVKEGPPSEHSGMSR

NAIIFLVLGILVFLILLGIGIYFYWSKCSREVLWHCHLCPSSTEHASASANGHVSYS

AVSRENSSSQDPQTEGTR (SEQ ID NO: 34)

Mouse PVR
>NM_027514.2 Mus musculus poliovirus receptor (Pvr), mRNA

(CD155)
AGGCGGCACCCGCTTAGCTGAGATTCCAGCACTTGACTTCAGGGTTTCGGAGAGATA

AGGCGCTTGGCCGTTACTAACTGGACTACAAAGAGCTGGATCGGACCGGAACCACAT

GGCTCAACTCGCCCGAGCCACCCGCTCCCCGCTGTCATGGCTGCTGCTGCTGTTCTG

CTATGCACTCCGGAAAGCGGGTGGGGATATACGTGTGCTGGTGCCCTACAATTCGAC

AGGCGTCTTGGGAGGGTCGACCACCTTGCACTGTAGTCTGACTTCTAATGAGAATGT

GACTATCACTCAAATAACCTGGATGAAGAAGGATTCAGGTGGATCCCACGCTCTTGT

GGCTGTCTTCCACCCCAAGAAGGGGCCCAACATCAAAGAGCCAGAGAGGGTGAAATT

CTTGGCTGCCCAACAGGATCTGAGGAACGCATCTCTGGCCATCTCGAACTTAAGTGT

AGAAGACGAAGGCATCTATGAATGTCAGATTGCCACATTCCCCAGAGGCAGTAGAAG

CACCAATGCCTGGCTGAAGGTGCAAGCCCGACCTAAGAACACTGCAGAGGCCCTGGA

GCCCTCTCCCACCTTGATACTGCAGGATGTGGCTAAATGCATCTCTGCCAATGGTCA

CCCTCCTGGACGAATCTCTTGGCCCTCGAATGTGAATGGAAGTCACCGTGAAATGAA

GGAACCAGGGTCCCAGCCGGGCACCACCACAGTTACCAGCTACCTCTCCATGGTACC

TTCTCGCCAGGCAGACGGCAAGAACATCACCTGCACGGTGGAGCATGAAAGCTTACA

GGAGCTGGACCAGCTGCTGGTGACCCTTTCCCAACCCTATCCACCTGAAAACGTGTC

CATCTCTGGCTATGACGGCAACTGGTATGTTGGCCTCACTAACTTGACCCTGACCTG

TGAAGCTCACAGCAAACCAGCGCCTGACATGGCTGGATATAACTGGAGCACGAACAC

GGGTGACTTTCCCAACTCTGTTAAGCGCCAGGGCAATATGCTTCTAATCTCCACCGT

AGAGGATGGTCTCAATAACACGGTCATTGTGTGCGAAGTCACCAATGCCCTAGGGTC

TGGGCAGGGCCAAGTGCACATCATTGTTAAAGAGAAACCTGAGAATATGCAGCAAAA

TACAAGATTACACCTAGGCTACATCTTTCTTATCGTCTTTGTCCTCGCTGTAGTCAT

CATCATCGCAGCACTATACACTATACGAAGATGCAGGCATGGTCGTGCTCTGCAGTC

CAATCCCTCAGAGAGGGAGAACGTCCAGTATTCATCTGTGAACGGCGACTGTAGACT

GAACATGGAGCCAAACAGCACAAGGTGACGGTGCTGGGTAGACAGAACTAAGGAACT

TGAAGGCATAGCAACTGGAACCCTACTCTCATAAATGAAGAAGCCTCCAGAGAGACT

GGCTGCTCAGTGTGATGAGCATAGCAAGTTTGGGGGGTCTCCCAGGATGCTGCCGAA

TTCCACGTTGTCAAAAGGACCCATGGAGGCCAGTGTGTTGGCTCACTCTTGACATCT

CAGCAAGCTGGGGGGGGGGGGGGGAGCATAAAGCAAGGTTGAGTCTAGCTTGGGCTA

TAGAGCAAAGCCCTGTCCATACACAAACAAGCTAAGGGGCTTTGAGACGGTCAGAAA

CTGAAGTCTTGCTTTGGGTAAGGTAAATCCTCTACCGCATGTATGTGCTAGACTTGA

AAGACTTCCACACAGACCTCTTTATAAGTTGACTCCATTGGGGCTATCCCCTCCTCT

CTGGACAAGGTCTCTGTATGTAGCCAAGGCTAGGCTCAAACTCACAGAGATATGTCT

GCTTCTACCTCCCCAGTGCTAGAGTTGAAAGTATTTGTGCCACTGCACTTTTCTAGG

TCTTCTTTTAATGAAGTAAAGTATATATTTATAAAAAGCTATTTAGTTATATATATA

TATATTTTTGAGACTATTTCATAGAGCCCAAGCTAACCTCAAACTTACTATGTAGCC

AAGAGTGATGGTAAACTAATTTATTTTAATTTATTTGTCTTCAATTTTAACCATCAC

CCAACCCCTGCTCCCTTCCATATCTTCTTTCAATCCATTTCATTGTCTTTTTCTTCC

CAGACACTATTCTGACTTACGTCTCCATTACAAACATTTTATTGAACTACATAAAAA

TGTGTGAACCACAAAAAAAAAATGTATTTGTCAAAATTGTAGTTGTCTTTCTGAGGC

TGACCTGAGTTCTCTGATACCATTCTCTCCAGTTGTATCCAGTTTCCTGTAAACAAT

GTGACTTTGTTTTTCTCAGTAGCTAAAACATCCCAATTATGTGAGTGTACACTTTCT

TTACTCATTCCTCTGTGGGCCACCAGCTGGGTTGGTTCCATATCTGAGCTATTGTGC

ATGGAATTGTCTCTGTGGTGGGTTTAGTAAACTCCCAGGAATGCCTGTACATGTTTG

TAGAGGCCAGAAGAAGGCACAAAATCTTGAGCCAGGCTTACATGCACTTGTGAGTAG

CCCCACATAGGTGCTAAGAACCCAGTTCAGGTCCTCTGCTGTGGGATGGTGGGCTGT

GCACAGAAAGCCTGGTCCCGGTCTAGCAAAGGTCTGGAACTCCGGAGCCGGTGGGCT

GTGATTTACACCAGCATGGGATGGAAGGAGTTGGACCTCGCCTCCTGGGCACCTGGC

TCCTGTCACATAGCTACAGCCTCCCACAGCCCCCCTATAGGGAGGTATGCAGCATCA

ATCACATAGTAGCTGCACTAAGCCCTCCCACATGCAAATAAGGTTTCCCCAAACTCT

CAGTCCAAGCCAATGAAAAGTACCTGCTGTCAAACCCTAAATCATCCCCAAAACTCT

GTAAGTCCTATCAGGGAATAAAATGTGTGTGAAAACTAAAAAAAAAAAAAAA (SEQ

ID NO: 35)

>NP_081790.1 poliovirus receptor precursor [Mus musculus]

MAQLARATRSPLSWLLLLFCYALRKAGGDIRVLVPYNSTGVLGGSTTLHCSLTSNEN

VTITQITWMKKDSGGSHALVAVFHPKKGPNIKEPERVKFLAAQQDLRNASLAISNLS

VEDEGIYECQIATFPRGSRSTNAWLKVQARPKNTAEALEPSPTLILQDVAKCISANG

HPPGRISWPSNVNGSHREMKEPGSQPGTTTVTSYLSMVPSRQADGKNITCTVEHESL

QELDQLLVTLSQPYPPENVSISGYDGNWYVGLTNLTLTCEAHSKPAPDMAGYNWSTN

TGDFPNSVKRQGNMLLISTVEDGLNNTVIVCEVTNALGSGQGQVHIIVKEKPENMQQ

NTRLHLGYIFLIVFVLAVVIIIAALYTIRRCRHGRALQSNPSERENVQYSSVNGDCR

LNMEPNSTR (SEQ ID NO: 36)

Human
>NM_002856.3 Homo sapiens nectin cell adhesion molecule 2

Nectin-2
(NECTIN2), transcript variant alpha, mRNA

(CD112)
GTGACGTCAGCGGGTTCGAACCGCCGGAGCTGAGCGAGAGGCCGGGGGTGCCGAGCC

isoform alpha
GGGCGGGGAGAGCTGGGCCGGGAGAGCAGAACAGGGAGGCTAGAGCGCAGCGGGAAC

CGGCCCGGAGCCGGAGCCGGAGCCCCACAGGCACCTACTAAACCGCCCAGCCGATCG

GCCCCCACAGAGTGGCCCGCGGGCCTCCGGCCGGGCCCAGTCCCCTCCCGGGCCCTC

CATGGCCCGGGCCGCTGCCCTCCTGCCGTCGAGATCGCCGCCGACGCCGCTGCTGTG

GCCGCTGCTGCTGCTGCTGCTCCTGGAAACCGGAGCCCAGGATGTGCGAGTTCAAGT

GCTACCCGAGGTGCGAGGCCAGCTCGGGGGCACCGTGGAGCTGCCGTGCCACCTGCT

GCCACCTGTTCCTGGACTGTACATCTCCCTGGTGACCTGGCAGCGCCCAGATGCACC

TGCGAACCACCAGAATGTGGCCGCCTTCCACCCTAAGATGGGTCCCAGCTTCCCCAG

CCCGAAGCCTGGCAGCGAGCGGCTGTCCTTCGTCTCTGCCAAGCAGAGCACTGGGCA

AGACACAGAGGCAGAGCTCCAGGACGCCACGCTGGCCCTCCACGGGCTCACGGTGGA

GGACGAGGGCAACTACACTTGCGAGTTTGCCACCTTCCCCAAGGGGTCCGTCCGAGG

GATGACCTGGCTCAGAGTCATAGCCAAGCCCAAGAACCAAGCTGAGGCCCAGAAGGT

CACGTTCAGCCAGGACCCTACGACAGTGGCCCTCTGCATCTCCAAAGAGGGCCGCCC

ACCTGCCCGGATCTCCTGGCTCTCATCCCTGGACTGGGAAGCCAAAGAGACTCAGGT

GTCAGGGACCCTGGCCGGAACTGTCACTGTCACCAGCCGCTTCACCTTGGTGCCCTC

GGGCCGAGCAGATGGTGTCACGGTCACCTGCAAAGTGGAGCATGAGAGCTTCGAGGA

ACCAGCCCTGATACCTGTGACCCTCTCTGTACGCTACCCTCCTGAAGTGTCCATCTC

CGGCTATGATGACAACTGGTACCTCGGCCGTACTGATGCCACCCTGAGCTGTGACGT

CCGCAGCAACCCAGAGCCCACGGGCTATGACTGGAGCACGACCTCAGGCACCTTCCC

GACCTCCGCAGTGGCCCAGGGCTCCCAGCTGGTCATCCACGCAGTGGACAGTCTGTT

CAATACCACCTTCGTCTGCACAGTCACCAATGCCGTGGGCATGGGCCGCGCTGAGCA

GGTCATCTTTGTCCGAGAAACCCCCAGGGCCTCGCCCCGAGATGTGGGCCCGCTGGT

GTGGGGGGCCGTGGGGGGGACACTGCTGGTGCTGCTGCTTCTGGCTGGGGGGTCCTT

GGCCTTCATCCTGCTGAGGGTGAGGAGGAGGAGGAAGAGCCCTGGAGGAGCAGGAGG

AGGAGCCAGTGGCGACGGGGGATTCTACGATCCGAAAGCTCAGGTGTTGGGAAATGG

GGACCCCGTCTTCTGGACACCAGTAGTCCCTGGTCCCATGGAACCAGATGGCAAGGA

TGAGGAGGAGGAGGAGGAGGAAGAGAAGGCAGAGAAAGGCCTCATGTTGCCTCCACC

CCCAGCACTCGAGGATGACATGGAGTCCCAGCTGGACGGCTCCCTCATCTCACGGCG

GGCAGTTTATGTGTGACCTGGACACAGACAGAGACAGAGCCAGGCCCGGCCCTCCCG

CCCCCGACCTGACCACGCCGGCCTAGGGTTCCAGACTGGTTGGACTTGTTCGTCTGG

ACGACACTGGAGTGGAACACTGCCTCCCACTTTCTTGGGACTTGGAGGGAGGTGGAA

CAGCACACTGGACTTCTCCCGTCTCTAGGGCTGCATGGGGAGCCCGGGGAGCTGAGT

AGTGGGGATCCAGAGAGGACCCCCGCCCCCAGAGACTTGGTTTTGGCTCCAGCCTTC

CCCTGGCCCCGTGACACTCAGGAGTTAATAAATGCCTTGGAGGAAAACA (SEQ ID

NO: 37)

>NP_002847.1 nectin-2 isoform alpha precursor [Homo

sapiens]

MARAAALLPSRSPPTPLLWPLLLLLLLETGAQDVRVQVLPEVRGQLGGTVELPCHLL

PPVPGLYISLVTWQRPDAPANHQNVAAFHPKMGPSFPSPKPGSERLSFVSAKQSTGQ

DTEAELQDATLALHGLTVEDEGNYTCEFATFPKGSVRGMTWLRVIAKPKNQAEAQKV

TFSQDPTTVALCISKEGRPPARISWLSSLDWEAKETQVSGTLAGTVTVTSRFTLVPS

GRADGVTVTCKVEHESFEEPALIPVTLSVRYPPEVSISGYDDNWYLGRTDATLSCDV

RSNPEPTGYDWSTTSGTFPTSAVAQGSQLVIHAVDSLFNTTFVCTVTNAVGMGRAEQ

VIFVRETPRASPRDVGPLVWGAVGGTLLVLLLLAGGSLAFILLRVRRRRKSPGGAGG

GASGDGGFYDPKAQVLGNGDPVFWTPVVPGPMEPDGKDEEEEEEEEKAEKGLMLPPP

PALEDDMESQLDGSLISRRAVYV (SEQ ID NO: 38)

Mouse Nectin-
>NM_001159724.1 Mus musculus nectin cell adhesion

2 (CD112)
molecule 2 (Nectin2), transcript variant 2, mRNA

isoform alpha
GAGCCCTAGGATCGGCTTGGCGAAGAGGGGCGGGGCCTGTGACGTCATGAGTCCGGC

CCGCTGGAGCTAAGCGAGGGGCCGGGGGGCGCGGATCCTGAGAGCCAGGCGAGGGAA

AGCTGGGCCGAACGAACTGATCCGGGGAGCCGTGAGCGGCGGAAGCCGGCCTGGAGC

CGGACACTTCAGACCCCTGACTGCCCTCCCAGCCGATCGGTACACGAAGAGTGGTCC

CTAGGCACCCCCTGCCCGGGCCCAGTCCCTCCCCGGGCCCCCCATGGCCCGGGCCGC

AGTCCTCCCGCCGTCCAGATTGTCACCGACGCTGCCGTTGTTGCCGCTGCTACTGCT

CCTGCTTCAGGAAACAGGAGCCCAAGATGTGCGGGTACGAGTGCTTCCCGAGGTCCG

GGGCCGCTTGGGAGGCACCGTGGAGTTACCGTGCCACCTGCTCCCACCCACGACGGA

GCGCGTCTCTCAGGTGACCTGGCAGCGCCTGGATGGCACAGTTGTGGCTGCTTTCCA

CCCATCCTTCGGAGTGGATTTCCCCAACTCTCAGTTCAGCAAGGACCGTCTGTCCTT

TGTCAGAGCGAGACCAGAAACAAACGCAGACCTGCGGGATGCCACACTGGCCTTCCG

GGGACTGAGGGTAGAGGACGAGGGCAATTACACCTGCGAGTTTGCCACGTTTCCCAA

CGGTACCCGCAGGGGGGTGACCTGGCTCAGAGTCATAGCCCAGCCTGAGAACCACGC

TGAAGCCCAGGAGGTCACAATTGGCCCCCAGTCGGTGGCTGTAGCCCGCTGTGTCTC

CACTGGGGGCCGCCCCCCTGCCCGAATCACCTGGATCTCATCTCTGGGTGGAGAGGC

CAAAGATACTCAGGAGCCAGGGATACAGGCTGGCACCGTCACTATCATCAGCCGATA

CTCCTTGGTGCCCGTGGGCCGAGCGGATGGCGTCAAGGTCACGTGTAGAGTGGAACA

CGAGAGCTTCGAAGAGCCGATCCTGCTGCCAGTGACCCTCTCTGTGCGCTACCCTCC

AGAAGTATCCATCTCCGGCTATGATGACAACTGGTACCTTGGCCGCAGTGAGGCCAT

ACTGACCTGTGATGTACGAAGCAACCCAGAGCCCACAGACTATGACTGGAGCACGAC

CTCGGGCGTCTTCCCAGCCTCTGCAGTGGCCCAGGGCTCTCAGCTGCTTGTCCACTC

TGTGGATCGAATGGTCAACACTACCTTCATCTGTACAGCCACCAACGCTGTGGGGAC

AGGCCGTGCTGAGCAGGTCATCCTGGTGCGAGACACCCCCCAGGCCTCCCGAGATGT

GGGTCCGCTGGTGTGGGGGGCCGTGGGGGGAACATTGCTGGTGCTACTCCTGGCTGG

GGGGTTCCTGGCCTTGATCCTGCTGAGGGGGAGGAGGAGGCGGAAGAGCCCTGGAGG

AGGAGGAAATGATGGCGACAGAGGATCCTACGATCCAAAGACTCAGGTGTTTGGGAA

CGGGGGTCCTGTCTTCTGGAGGTCAGCATCCCCTGAGCCCATGAGGCCAGATGGCAG

GGAGGAAGATGAGGAGGAGGAGGAAGAAATGAAGGCAGAGGAAGGTCTCATGCTACC

TCCACACGAGTCACCTAAGGACGACATGGAGTCCCATCTGGATGGCTCCCTCATCTC

TCGGCGGGCAGTTTACGTGTGACCCTACGATATAGACACTGGACACATGGAAACACC

AAGTTCCACCCTCACTGCCAACCACACCAATGCCAGCCAGCAACGATGGCTAGGGAC

CGGTTGGACTGGTTCTTCTGGGGCACACTGGAGTTGGAAGGGCACCGCCCCTGCTTT

CAGGATAGAGGACAAGTGGAACCACACAGACTCCTATCTTTAGGGCCTCATGGAGTA

GGGGACCCCAGGAGCGCCATGGTGCACACTCAGGACTCCTCAGAGCTTGCTTTCGGC

CCCAGCCTAGCCCTGGCCCCGAAACACTCAGGAGCTAATAAATGCCTTGTCGGAAAA

AAAAAAAAAAAAAA (SEQ ID NO: 39)

>NP_001153196.1 nectin-2 isoform 2 precursor [Mus

musculus]

MARAAVLPPSRLSPTLPLLPLLLLLLQETGAQDVRVRVLPEVRGRLGGTVELPCHLL

PPTTERVSQVTWQRLDGTVVAAFHPSFGVDFPNSQFSKDRLSFVRARPETNADLRDA

TLAFRGLRVEDEGNYTCEFATFPNGTRRGVTWLRVIAQPENHAEAQEVTIGPQSVAV

ARCVSTGGRPPARITWISSLGGEAKDTQEPGIQAGTVTIISRYSLVPVGRADGVKVT

CRVEHESFEEPILLPVTLSVRYPPEVSISGYDDNWYLGRSEAILTCDVRSNPEPTDY

DWSTTSGVFPASAVAQGSQLLVHSVDRMVNTTFICTATNAVGTGRAEQVILVRDTPQ

ASRDVGPLVWGAVGGTLLVLLLAGGFLALILLRGRRRRKSPGGGGNDGDRGSYDPKT

QVFGNGGPVFWRSASPEPMRPDGREEDEEEEEEMKAEEGLMLPPHESPKDDMESHLD

GSLISRRAVYV (SEQ ID NO: 40)

Human
>NM_001042724.2 Homo sapiens nectin cell adhesion

Nectin-2
molecule 2 (NECTIN2), transcript variant delta, mRNA

(CD112)
GTGACGTCAGCGGGTTCGAACCGCCGGAGCTGAGCGAGAGGCCGGGGGTGCCGAGCC

isoform delta
GGGCGGGGAGAGCTGGGCCGGGAGAGCAGAACAGGGAGGCTAGAGCGCAGCGGGAAC

CGGCCCGGAGCCGGAGCCGGAGCCCCACAGGCACCTACTAAACCGCCCAGCCGATCG

GCCCCCACAGAGTGGCCCGCGGGCCTCCGGCCGGGCCCAGTCCCCTCCCGGGCCCTC

CATGGCCCGGGCCGCTGCCCTCCTGCCGTCGAGATCGCCGCCGACGCCGCTGCTGTG

GCCGCTGCTGCTGCTGCTGCTCCTGGAAACCGGAGCCCAGGATGTGCGAGTTCAAGT

GCTACCCGAGGTGCGAGGCCAGCTCGGGGGCACCGTGGAGCTGCCGTGCCACCTGCT

GCCACCTGTTCCTGGACTGTACATCTCCCTGGTGACCTGGCAGCGCCCAGATGCACC

TGCGAACCACCAGAATGTGGCCGCCTTCCACCCTAAGATGGGTCCCAGCTTCCCCAG

CCCGAAGCCTGGCAGCGAGCGGCTGTCCTTCGTCTCTGCCAAGCAGAGCACTGGGCA

AGACACAGAGGCAGAGCTCCAGGACGCCACGCTGGCCCTCCACGGGCTCACGGTGGA

GGACGAGGGCAACTACACTTGCGAGTTTGCCACCTTCCCCAAGGGGTCCGTCCGAGG

GATGACCTGGCTCAGAGTCATAGCCAAGCCCAAGAACCAAGCTGAGGCCCAGAAGGT

CACGTTCAGCCAGGACCCTACGACAGTGGCCCTCTGCATCTCCAAAGAGGGCCGCCC

ACCTGCCCGGATCTCCTGGCTCTCATCCCTGGACTGGGAAGCCAAAGAGACTCAGGT

GTCAGGGACCCTGGCCGGAACTGTCACTGTCACCAGCCGCTTCACCTTGGTGCCCTC

GGGCCGAGCAGATGGTGTCACGGTCACCTGCAAAGTGGAGCATGAGAGCTTCGAGGA

ACCAGCCCTGATACCTGTGACCCTCTCTGTACGCTACCCTCCTGAAGTGTCCATCTC

CGGCTATGATGACAACTGGTACCTCGGCCGTACTGATGCCACCCTGAGCTGTGACGT

CCGCAGCAACCCAGAGCCCACGGGCTATGACTGGAGCACGACCTCAGGCACCTTCCC

GACCTCCGCAGTGGCCCAGGGCTCCCAGCTGGTCATCCACGCAGTGGACAGTCTGTT

CAATACCACCTTCGTCTGCACAGTCACCAATGCCGTGGGCATGGGCCGCGCTGAGCA

GGTCATCTTTGTCCGAGAGACCCCCAACACAGCAGGCGCAGGGGCCACAGGCGGCAT

CATCGGGGGCATCATCGCCGCCATCATTGCTACTGCTGTGGCTGCCACGGGCATCCT

TATCTGCCGGCAGCAGCGGAAGGAGCAGACGCTGCAGGGGGCAGAGGAGGACGAAGA

CCTGGAGGGACCTCCCTCCTACAAGCCACCGACCCCAAAAGCGAAGCTGGAGGCACA

GGAGATGCCCTCCCAGCTCTTCACTCTGGGGGCCTCGGAGCACAGCCCACTCAAGAC

CCCCTACTTTGATGCTGGCGCCTCATGCACTGAGCAGGAAATGCCTCGATACCATGA

GCTGCCCACCTTGGAAGAACGGTCAGGACCCTTGCACCCTGGAGCCACAAGCCTGGG

GTCCCCCATCCCGGTGCCTCCAGGGCCACCTGCTGTGGAAGACGTTTCCCTGGATCT

AGAGGATGAGGAGGGGGAGGAGGAGGAAGAGTATCTGGACAAGATCAACCCCATCTA

TGATGCTCTGTCCTATAGCAGCCCCTCTGATTCCTACCAGGGCAAAGGCTTTGTCAT

GTCCCGGGCCATGTATGTGTGAGCTGCCATGCGCCTGGCGTCTCACATCTCACCTGT

TGATCCCTTAGCTTTCTTGCCAAGGATCTAGTGCCCCCTGACCTCTGGCCAGGCCAC

TGTCAGTTAACACATATGCATTCCATTTGTGATGTCTACCTTGGTGGCTCCACTATG

ACCCCTAACCCATGAGCCCAGAGAAATTCACCGTGATAATGGAATCCTGGCAACCTT

ATCTCATGAGGCAGGAGGTGGGGAAGGTGCTTCTGCACAACCTCTGATCCCAAGGAC

TCCTCTCCCAGACTGTGACCTTAGACCATACCTCTCACCCCCCAATGCCTCGACTCC

CCCAAAATCACAAAGAAGACCCTAGACCTATAATTTGTCTTCAGGTAGTAAATTCCC

AATAGGTCTGCTGGAGTGGGCGCTGAGGGCTCCCTGCTGCTCAGACCTGAGCCCTCC

AGGCAGCAGGGTCCCACTTACCCCCTCCCCACCCTGTTCCCCAAAGGTGGGAAAGAG

GGGATTCCCCAGCCCAAGGCAGGGTTTTCCCAGCACCCTCCTGTAAGCAGAAGTCTC

AGGGTCCAGACCCTTCCCTGAGCCCCCACCCCCACCCCAATTCCTGCCTACCAAGCA

AGCAGCCCCAGCCTAGGGTCAGACAGGGTGAGCCTCATACAGACTGTGCCTTGATGG

CCCCAGCCTTGGGAGAAGAATTTACTGTTAACCTGGAAGACTACTGAATCATTTTAC

CCTTGCCCAGTGGAATAGGACCTAAACATCCCCCTTCCGGGGAAAGTGGGTCATCTG

AATTGGGGGTAGCAATTGATACTGTTTTGTAAACTACATTTCCTACAAAATATGAAT

TTATACTTTGA (SEQ ID NO: 41)

>NP_001036189.1 nectin-2 isoform delta precursor [Homo

sapiens]

MARAAALLPSRSPPTPLLWPLLLLLLLETGAQDVRVQVLPEVRGQLGGTVELPCHLL

PPVPGLYISLVTWQRPDAPANHQNVAAFHPKMGPSFPSPKPGSERLSFVSAKQSTGQ

DTEAELQDATLALHGLTVEDEGNYTCEFATFPKGSVRGMTWLRVIAKPKNQAEAQKV

TFSQDPTTVALCISKEGRPPARISWLSSLDWEAKETQVSGTLAGTVTVTSRFTLVPS

GRADGVTVTCKVEHESFEEPALIPVTLSVRYPPEVSISGYDDNWYLGRTDATLSCDV

RSNPEPTGYDWSTTSGTFPTSAVAQGSQLVIHAVDSLFNTTFVCTVTNAVGMGRAEQ

VIFVRETPNTAGAGATGGIIGGIIAAIIATAVAATGILICRQQRKEQTLQGAEEDED

LEGPPSYKPPTPKAKLEAQEMPSQLFTLGASEHSPLKTPYFDAGASCTEQEMPRYHE

LPTLEERSGPLHPGATSLGSPIPVPPGPPAVEDVSLDLEDEEGEEEEEYLDKINPIY

DALSYSSPSDSYQGKGFVMSRAMYV (SEQ ID NO: 42)

Mouse Nectin-
>NM_008990.3 Mus musculus nectin cell adhesion molecule

2 (CD112)
2 (Nectin2), transcript variant 1, mRNA

isoform beta
GAGCCCTAGGATCGGCTTGGCGAAGAGGGGCGGGGCCTGTGACGTCATGAGTCCGGC

CCGCTGGAGCTAAGCGAGGGGCCGGGGGGCGCGGATCCTGAGAGCCAGGCGAGGGAA

AGCTGGGCCGAACGAACTGATCCGGGGAGCCGTGAGCGGCGGAAGCCGGCCTGGAGC

CGGACACTTCAGACCCCTGACTGCCCTCCCAGCCGATCGGTACACGAAGAGTGGTCC

CTAGGCACCCCCTGCCCGGGCCCAGTCCCTCCCCGGGCCCCCCATGGCCCGGGCCGC

AGTCCTCCCGCCGTCCAGATTGTCACCGACGCTGCCGTTGTTGCCGCTGCTACTGCT

CCTGCTTCAGGAAACAGGAGCCCAAGATGTGCGGGTACGAGTGCTTCCCGAGGTCCG

GGGCCGCTTGGGAGGCACCGTGGAGTTACCGTGCCACCTGCTCCCACCCACGACGGA

GCGCGTCTCTCAGGTGACCTGGCAGCGCCTGGATGGCACAGTTGTGGCTGCTTTCCA

CCCATCCTTCGGAGTGGATTTCCCCAACTCTCAGTTCAGCAAGGACCGTCTGTCCTT

TGTCAGAGCGAGACCAGAAACAAACGCAGACCTGCGGGATGCCACACTGGCCTTCCG

GGGACTGAGGGTAGAGGACGAGGGCAATTACACCTGCGAGTTTGCCACGTTTCCCAA

CGGTACCCGCAGGGGGGTGACCTGGCTCAGAGTCATAGCCCAGCCTGAGAACCACGC

TGAAGCCCAGGAGGTCACAATTGGCCCCCAGTCGGTGGCTGTAGCCCGCTGTGTCTC

CACTGGGGGCCGCCCCCCTGCCCGAATCACCTGGATCTCATCTCTGGGTGGAGAGGC

CAAAGATACTCAGGAGCCAGGGATACAGGCTGGCACCGTCACTATCATCAGCCGATA

CTCCTTGGTGCCCGTGGGCCGAGCGGATGGCGTCAAGGTCACGTGTAGAGTGGAACA

CGAGAGCTTCGAAGAGCCGATCCTGCTGCCAGTGACCCTCTCTGTGCGCTACCCTCC

AGAAGTATCCATCTCCGGCTATGATGACAACTGGTACCTTGGCCGCAGTGAGGCCAT

ACTGACCTGTGATGTACGAAGCAACCCAGAGCCCACAGACTATGACTGGAGCACGAC

CTCGGGCGTCTTCCCAGCCTCTGCAGTGGCCCAGGGCTCTCAGCTGCTTGTCCACTC

TGTGGATCGAATGGTCAACACTACCTTCATCTGTACAGCCACCAACGCTGTGGGGAC

AGGCCGTGCTGAGCAGGTCATCCTGGTGCGAGAGTCACCCAGCACAGCAGGAGCAGG

GGCCACTGGTGGCATCATTGGAGGTATTATCGCTGCCATCATCGCCACCGCAGTGGC

TGGCACAGGCATCCTCATCTGCCGACAACAGCGGAAGGAGCAGAGGCTTCAAGCTGC

GGATGAGGAAGAAGAACTGGAAGGACCTCCCTCCTATAAACCACCCACCCCGAAGGC

CAAGCTGGAGGAACCAGAGATGCCCTCTCAACTCTTCACCTTGGGGGCCTCAGAGCA

CAGCCCAGTGAAGACGCCATACTTTGATGCTGGTGTCTCTTGTGCTGATCAGGAGAT

GCCTCGGTATCACGAGCTGCCCACTCTGGAAGAGCGGTCAGGGCCCCTGCTGTTGGG

GGCTACAGGCCTGGGACCTTCTCTTCTGGTGCCTCCAGGACCCAATGTTGTGGAGGG

GGTTTCCCTGAGTCTCGAAGATGAGGAGGAAGATGATGAGGAGGAAGACTTCCTGGA

TAAAATCAACCCTATTTATGATGCCCTGTCCTACCCCAGCCCCTCTGACTCCTACCA

GAGCAAAGACTTTTTTGTGTCACGGGCCATGTATGTGTGAGGGAGGCACAGGGGCTC

TGACGTCTCACCTTTCACCCTTGACCCATGAGCTTTCCACCAGTAATCTAGGACACT

CTGACTTCCAGGCAGACCAGGGACAACTATCACCCATTGCAATCCACCTGTGACTTC

TTAGTGACTCCACCATGACGTCCAATCTATGATGTCTGAGGCAGGCAAACCTGCACA

ACTGGAAACCTGGAGATTTTTATCTCCCTTGGCAGGGAGCTCACCATATCCTTCTGC

ACCACCTGTGACCCCCCCCCCCCCCCCAAGGACTCCTAAGACTACGACCCTTTGACC

ATGCCACTCAGTATCTCAAGAACCCTTAAAGTCCCAAAGGAATCGGACCTTGCACTT

GTCCTCAGGCAATAGAGTCCAACAGATATGCAAGAACGGGATCAGGGGCTCCCTGTT

GCTCAGACCTGAGCCCTCCAGGCAGCAGAAGCTCACCTGATCCCTCCCCACCCTGCT

CCCCAAAGGTGAAAAGGAGAGGATTCCCCAATGTAAGGTAGGACCTCCCCATCTCCA

CCTACTCCTGCAGGCAGGAATCTCAGGTTTCTCACACCCTCTCCTCAGCACCCAGGT

TCCTGTCTCCAGAGCATGAATTCCAGGTCCAATGCTAGAGGGGAGAACCTAATGCAA

GTGTGCCTTGCCACCCCAAGTTTGGGAGACTCTGCTCTTATCCTGAGGACTACTGAA

TTCTTTTAACCCCTACCCAGTGAGATGAGAACTACATATCCCTCTTTAGGGGATGGT

GTGTGTATGTGTGTGTGATGGAGAATCTGGGCATCTGGGTTGGGAATTTTATTTTGT

AAGCATTTCCTACATAATATGAGTTTCTACTTTGATAAAGTCTTGTGTTTTCTGTG

(SEQ ID NO: 43)

>NP_033016.3 nectin-2 isoform 1 precursor [Mus musculus]

MARAAVLPPSRLSPTLPLLPLLLLLLQETGAQDVRVRVLPEVRGRLGGTVELPCHLL

PPTTERVSQVTWQRLDGTVVAAFHPSFGVDFPNSQFSKDRLSFVRARPETNADLRDA

TLAFRGLRVEDEGNYTCEFATFPNGTRRGVTWLRVIAQPENHAEAQEVTIGPQSVAV

ARCVSTGGRPPARITWISSLGGEAKDTQEPGIQAGTVTIISRYSLVPVGRADGVKVT

CRVEHESFEEPILLPVTLSVRYPPEVSISGYDDNWYLGRSEAILTCDVRSNPEPTDY

DWSTTSGVFPASAVAQGSQLLVHSVDRMVNTTFICTATNAVGTGRAEQVILVRESPS

TAGAGATGGIIGGIIAAIIATAVAGTGILICRQQRKEQRLQAADEEEELEGPPSYKP

PTPKAKLEEPEMPSQLFTLGASEHSPVKTPYFDAGVSCADQEMPRYHELPTLEERSG

PLLLGATGLGPSLLVPPGPNVVEGVSLSLEDEEEDDEEEDFLDKINPIYDALSYPSP

SDSYQSKDFFVSRAMYV (SEQ ID NO: 44)

Human IL-10
>NM_000572.3 Homo sapiens interleukin 10 (IL10),

transcript variant 1, mRNA

ACACATCAGGGGCTTGCTCTTGCAAAACCAAACCACAAGACAGACTTGCAAAAGAAG

GCATGCACAGCTCAGCACTGCTCTGTTGCCTGGTCCTCCTGACTGGGGTGAGGGCCA

GCCCAGGCCAGGGCACCCAGTCTGAGAACAGCTGCACCCACTTCCCAGGCAACCTGC

CTAACATGCTTCGAGATCTCCGAGATGCCTTCAGCAGAGTGAAGACTTTCTTTCAAA

TGAAGGATCAGCTGGACAACTTGTTGTTAAAGGAGTCCTTGCTGGAGGACTTTAAGG

GTTACCTGGGTTGCCAAGCCTTGTCTGAGATGATCCAGTTTTACCTGGAGGAGGTGA

TGCCCCAAGCTGAGAACCAAGACCCAGACATCAAGGCGCATGTGAACTCCCTGGGGG

AGAACCTGAAGACCCTCAGGCTGAGGCTACGGCGCTGTCATCGATTTCTTCCCTGTG

AAAACAAGAGCAAGGCCGTGGAGCAGGTGAAGAATGCCTTTAATAAGCTCCAAGAGA

AAGGCATCTACAAAGCCATGAGTGAGTTTGACATCTTCATCAACTACATAGAAGCCT

ACATGACAATGAAGATACGAAACTGAGACATCAGGGTGGCGACTCTATAGACTCTAG

GACATAAATTAGAGGTCTCCAAAATCGGATCTGGGGCTCTGGGATAGCTGACCCAGC

CCCTTGAGAAACCTTATTGTACCTCTCTTATAGAATATTTATTACCTCTGATACCTC

AACCCCCATTTCTATTTATTTACTGAGCTTCTCTGTGAACGATTTAGAAAGAAGCCC

AATATTATAATTTTTTTCAATATTTATTATTTTCACCTGTTTTTAAGCTGTTTCCAT

AGGGTGACACACTATGGTATTTGAGTGTTTTAAGATAAATTATAAGTTACATAAGGG

AGGAAAAAAAATGTTCTTTGGGGAGCCAACAGAAGCTTCCATTCCAAGCCTGACCAC

GCTTTCTAGCTGTTGAGCTGTTTTCCCTGACCTCCCTCTAATTTATCTTGTCTCTGG

GCTTGGGGCTTCCTAACTGCTACAAATACTCTTAGGAAGAGAAACCAGGGAGCCCCT

TTGATGATTAATTCACCTTCCAGTGTCTCGGAGGGATTCCCCTAACCTCATTCCCCA

ACCACTTCATTCTTGAAAGCTGTGGCCAGCTTGTTATTTATAACAACCTAAATTTGG

TTCTAGGCCGGGCGCGGTGGCTCACGCCTGTAATCCCAGCACTTTGGGAGGCTGAGG

CGGGTGGATCACTTGAGGTCAGGAGTTCCTAACCAGCCTGGTCAACATGGTGAAACC

CCGTCTCTACTAAAAATACAAAAATTAGCCGGGCATGGTGGCGCGCACCTGTAATCC

CAGCTACTTGGGAGGCTGAGGCAAGAGAATTGCTTGAACCCAGGAGATGGAAGTTGC

AGTGAGCTGATATCATGCCCCTGTACTCCAGCCTGGGTGACAGAGCAAGACTCTGTC

TCAAAAAATAAAAATAAAAATAAATTTGGTTCTAATAGAACTCAGTTTTAACTAGAA

TTTATTCAATTCCTCTGGGAATGTTACATTGTTTGTCTGTCTTCATAGCAGATTTTA

ATTTTGAATAAATAAATGTATCTTATTCACATCA (SEQ ID NO: 45)

>NP_000563.1 interleukin-10 isoform 1 precursor [Homo

sapiens]

MHSSALLCCLVLLTGVRASPGQGTQSENSCTHFPGNLPNMLRDLRDAFSRVKTFFQM

KDQLDNLLLKESLLEDFKGYLGCQALSEMIQFYLEEVMPQAENQDPDIKAHVNSLGE

NLKTLRLRLRRCHRFLPCENKSKAVEQVKNAFNKLQEKGIYKAMSEFDIFINYIEAY

MTMKIRN (SEQ ID NO: 46)

Mouse IL-10
>NM_010548.2 Mus musculus interleukin 10 (Il10), mRNA

ACATTTAGAGACTTGCTCTTGCACTACCAAAGCCACAAGGCAGCCTTGCAGAAAAGA

GAGCTCCATCATGCCTGGCTCAGCACTGCTATGCTGCCTGCTCTTACTGACTGGCAT

GAGGATCAGCAGGGGCCAGTACAGCCGGGAAGACAATAACTGCACCCACTTCCCAGT

CGGCCAGAGCCACATGCTCCTAGAGCTGCGGACTGCCTTCAGCCAGGTGAAGACTTT

CTTTCAAACAAAGGACCAGCTGGACAACATACTGCTAACCGACTCCTTAATGCAGGA

CTTTAAGGGTTACTTGGGTTGCCAAGCCTTATCGGAAATGATCCAGTTTTACCTGGT

AGAAGTGATGCCCCAGGCAGAGAAGCATGGCCCAGAAATCAAGGAGCATTTGAATTC

CCTGGGTGAGAAGCTGAAGACCCTCAGGATGCGGCTGAGGCGCTGTCATCGATTTCT

CCCCTGTGAAAATAAGAGCAAGGCAGTGGAGCAGGTGAAGAGTGATTTTAATAAGCT

CCAAGACCAAGGTGTCTACAAGGCCATGAATGAATTTGACATCTTCATCAACTGCAT

AGAAGCATACATGATGATCAAAATGAAAAGCTAAAACACCTGCAGTGTGTATTGAGT

CTGCTGGACTCCAGGACCTAGACAGAGCTCTCTAAATCTGATCCAGGGATCTTAGCT

AACGGAAACAACTCCTTGGAAAACCTCGTTTGTACCTCTCTCCGAAATATTTATTAC

CTCTGATACCTCAGTTCCCATTCTATTTATTCACTGAGCTTCTCTGTGAACTATTTA

GAAAGAAGCCCAATATTATAATTTTACAGTATTTATTATTTTTAACCTGTGTTTAAG

CTGTTTCCATTGGGGACACTTTATAGTATTTAAAGGGAGATTATATTATATGATGGG

AGGGGTTCTTCCTTGGGAAGCAATTGAAGCTTCTATTCTAAGGCTGGCCACACTTGA

GAGCTGCAGGGCCCTTTGCTATGGTGTCCTTTCAATTGCTCTCATCCCTGAGTTCAG

AGCTCCTAAGAGAGTTGTGAAGAAACTCATGGGTCTTGGGAAGAGAAACCAGGGAGA

TCCTTTGATGATCATTCCTGCAGCAGCTCAGAGGGTTCCCCTACTGTCATCCCCCAG

CCGCTTCATCCCTGAAAACTGTGGCCAGTTTGTTATTTATAACCACCTAAAATTAGT

TCTAATAGAACTCATTTTTAACTAGAAGTAATGCAATTCCTCTGGGAATGGTGTATT

GTTTGTCTGCCTTTGTAGCAGACTCTAATTTTGAATAAATGGATCTTATTCG (SEQ

ID NO: 47)

>NP_034678.1 interleukin-10 precursor [Mus musculus]

MPGSALLCCLLLLTGMRISRGQYSREDNNCTHFPVGQSHMLLELRTAFSQVKTFFQT

KDQLDNILLTDSLMQDFKGYLGCQALSEMIQFYLVEVMPQAEKHGPEIKEHLNSLGE

KLKTLRMRLRRCHRFLPCENKSKAVEQVKSDFNKLQDQGVYKAMNEFDIFINCIEAY

MMIKMKS (SEQ ID NO: 48)

Human TSG-6
>NM_007115.3 Homo sapiens TNF alpha induced protein 6

(TNFAIP6), mRNA

AGTCACATTTCAGCCACTGCTCTGAGAATTTGTGAGCAGCCCCTAACAGGCTGTTAC

TTCACTACAACTGACGATATGATCATCTTAATTTACTTATTTCTCTTGCTATGGGAA

GACACTCAAGGATGGGGATTCAAGGATGGAATTTTTCATAACTCCATATGGCTTGAA

CGAGCAGCCGGTGTGTACCACAGAGAAGCACGGTCTGGCAAATACAAGCTCACCTAC

GCAGAAGCTAAGGCGGTGTGTGAATTTGAAGGCGGCCATCTCGCAACTTACAAGCAG

CTAGAGGCAGCCAGAAAAATTGGATTTCATGTCTGTGCTGCTGGATGGATGGCTAAG

GGCAGAGTTGGATACCCCATTGTGAAGCCAGGGCCCAACTGTGGATTTGGAAAAACT

GGCATTATTGATTATGGAATCCGTCTCAATAGGAGTGAAAGATGGGATGCCTATTGC

TACAACCCACACGCAAAGGAGTGTGGTGGCGTCTTTACAGATCCAAAGCAAATTTTT

AAATCTCCAGGCTTCCCAAATGAGTACGAAGATAACCAAATCTGCTACTGGCACATT

AGACTCAAGTATGGTCAGCGTATTCACCTGAGTTTTTTAGATTTTGACCTTGAAGAT

GACCCAGGTTGCTTGGCTGATTATGTTGAAATATATGACAGTTACGATGATGTCCAT

GGCTTTGTGGGAAGATACTGTGGAGATGAGCTTCCAGATGACATCATCAGTACAGGA

AATGTCATGACCTTGAAGTTTCTAAGTGATGCTTCAGTGACAGCTGGAGGTTTCCAA

ATCAAATATGTTGCAATGGATCCTGTATCCAAATCCAGTCAAGGAAAAAATACAAGT

ACTACTTCTACTGGAAATAAAAACTTTTTAGCTGGAAGATTTAGCCACTTATAAAAA

AAAAAAAAAGGATGATCAAAACACACAGTGTTTATGTTGGAATCTTTTGGAACTCCT

TTGATCTCACTGTTATTATTAACATTTATTTATTATTTTTCTAAATGTGAAAGCAAT

ACATAATTTAGGGAAAATTGGAAAATATAGGAAACTTTAAACGAGAAAATGAAACCT

CTCATAATCCCACTGCATAGAAATAACAAGCGTTAACATTTTCATATTTTTTTCTTT

CAGTCATTTTTCTATTTGTGGTATATGTATATATGTACCTATATGTATTTGCATTTG

AAATTTTGGAATCCTGCTCTATGTACAGTTTTGTATTATACTTTTTAAATCTTGAAC

TTTATAAACATTTTCTGAAATCATTGATTATTCTACAAAAACATGATTTTAAACAGC

TGTAAAATATTCTATGATATGAATGTTTTATGCATTATTTAAGCCTGTCTCTATTGT

TGGAATTTCAGGTCATTTTCATAAATATTGTTGCAATAAATATCCTTGAACACACAA

AAAAAAAAAAAAAA (SEQ ID NO: 49)

>NP_009046.2 tumor necrosis factor-inducible gene 6

protein precursor [Homo sapiens]

MIILIYLFLLLWEDTQGWGFKDGIFHNSIWLERAAGVYHREARSGKYKLTYAEAKAV

CEFEGGHLATYKQLEAARKIGFHVCAAGWMAKGRVGYPIVKPGPNCGFGKTGIIDYG

IRLNRSERWDAYCYNPHAKECGGVFTDPKQIFKSPGFPNEYEDNQICYWHIRLKYGQ

RIHLSFLDFDLEDDPGCLADYVEIYDSYDDVHGFVGRYCGDELPDDIISTGNVMTLK

FLSDASVTAGGFQIKYVAMDPVSKSSQGKNTSTTSTGNKNFLAGRFSHL (SEQ ID

NO: 50)

Mouse TSG-6
>NM_009398.2 Mus musculus tumor necrosis factor alpha

induced protein 6 (Tnfaip6), mRNA

CCGCTGCTCTGAGAATTTCGTGTGGGCAGCCCCGACATTGTAACCGGCTCTGCAACC

GAAGAGATGGTCGTCCTCCTTTGCTTATGCGTCTTGCTGTGGGAAGAGGCTCACGGA

TGGGGATTCAAGAACGGGATCTTTCATAACTCCATATGGCTTGAACAAGCAGCGGGC

GTATACCACAGAGAAGCTCGGGCTGGCAGATACAAGCTCACCTACGCCGAAGCCAAG

GCCGTATGTGAATTTGAAGGTGGTCGTCTCGCAACCTACAAGCAGCTAGAGGCAGCC

AGAAAAATTGGATTCCATGTCTGTGCTGCTGGATGGATGGCCAAGGGTAGAGTCGGA

TACCCCATTGTGAAACCTGGGCCCAACTGTGGATTTGGGAAAACGGGTATCATCGAT

TATGGAATCCGGCTCAACAGGAGTGAGCGATGGGATGCCTATTGCTACAACCCACAT

GCAAAGGAGTGTGGTGGTGTCTTCACAGATCCGAAGCGAATTTTTAAATCCCCGGGC

TTCCCAAATGAGTACGATGACAACCAGGTCTGCTACTGGCACATTCGGCTCAAGTAC

GGTCAGCGAATTCACCTGAGCTTTTTGGACTTTGACCTTGAACATGATCCAGGCTGC

TTGGCTGACTATGTAGAAATCTATGACAGTTATGATGACGTCCACGGCTTTGTAGGA

AGATACTGTGGTGATGAACTTCCAGAAGACATCATTAGCACAGGAAATGTCATGACC

TTGAAGTTTCTGAGTGATGCATCCGTCACGGCTGGAGGCTTCCAGATTAAATACGTC

ACAGTGGATCCTGCATCTAAATCCAGTCAAGCCAAAAATACAAGTACTACTGGAAAT

AAGAAGTTCTTACCTGGAAGGTTTAGCCATCTATAAAAAATTTTTTTTAAAAATGTT

CAAAACATCCAGTACAATATTTATATTTGTTTTTGTTGTTGTTGTTGGTTTTTTTTT

TTTTATTTTGTTTTGTTTTGTTTTTTTGAGACGGGGTTTCTCTGTATAGCCTTGGCT

GTCCTGGAACTCACTTTGAAGACCAGGCTGGCCTCGAACTCAGAAATCCACCTGCCT

CCGCCTACCAAGTGCTGGGATTAAAGGCGTCCACCACCACCGCCCGGCTTCAATATT

TATATTTGTAGCTCTTGGACCTCGTTTGTTCTCTTTTGTATTTTTATTATTAACATG

TATTTATTATTTTTCCAAATGTGAAAGCCATATGTAATTATGTGGAAAATTGACAAA

TAAATACAGAGAACTTCAAATGAGTTTTTTTTTTAAATCTCATAATTGTACTACACA

GAAATAACTAATGTTAAAGTTTTTAAATGTTTGTCTTTCATTCATTTTTCTACTTGT

AGTATATGTACATATGTAACTCTATGATTTGCGTTTGAATTTTGGCATTCTGCCTTT

TGTAACCTGATATTTTTAACCTTGACATTGTATAGCTCAAGCACTTCCCAAGATCTC

TGAGTTTTCTACAAAATGGGACTTTGTAAATATGATTGTTCCCTGCTTTATTTAAGC

TGAATTTATATTAGGATTTAAGGTTGTTTTCATAAATATTGCTGTAATAAATACTTT

TGGAT (SEQ ID NO: 51)

>NP_033424.1 tumor necrosis factor-inducible gene 6

protein precursor [Mus musculus]

MVVLLCLCVLLWEEAHGWGFKNGIFHNSIWLEQAAGVYHREARAGRYKLTYAEAKAV

CEFEGGRLATYKQLEAARKIGFHVCAAGWMAKGRVGYPIVKPGPNCGFGKTGIIDYG

IRLNRSERWDAYCYNPHAKECGGVFTDPKRIFKSPGFPNEYDDNQVCYWHIRLKYGQ

RIHLSFLDFDLEHDPGCLADYVEIYDSYDDVHGFVGRYCGDELPEDIISTGNVMTLK

FLSDASVTAGGFQIKYVTVDPASKSSQAKNTSTTGNKKFLPGRFSHL (SEQ ID

NO: 52)

Human B7-H3
>NM_001024736.2 Homo sapiens CD276 molecule (CD276),

(CD276)
transcript variant 1, mRNA

ATTCGGGCCGGGCCTCGCTGCGGCGGCGACTGAGCCAGGCTGGGCCGCGTCCCTGAG

TCCCAGAGTCGGCGCGGCGCGGCAGGGGCAGCCTTCCACCACGGGGAGCCCAGCTGT

CAGCCGCCTCACAGGAAGATGCTGCGTCGGCGGGGCAGCCCTGGCATGGGTGTGCAT

GTGGGTGCAGCCCTGGGAGCACTGTGGTTCTGCCTCACAGGAGCCCTGGAGGTCCAG

GTCCCTGAAGACCCAGTGGTGGCACTGGTGGGCACCGATGCCACCCTGTGCTGCTCC

TTCTCCCCTGAGCCTGGCTTCAGCCTGGCACAGCTCAACCTCATCTGGCAGCTGACA

GATACCAAACAGCTGGTGCACAGCTTTGCTGAGGGCCAGGACCAGGGCAGCGCCTAT

GCCAACCGCACGGCCCTCTTCCCGGACCTGCTGGCACAGGGCAACGCATCCCTGAGG

CTGCAGCGCGTGCGTGTGGCGGACGAGGGCAGCTTCACCTGCTTCGTGAGCATCCGG

GATTTCGGCAGCGCTGCCGTCAGCCTGCAGGTGGCCGCTCCCTACTCGAAGCCCAGC

ATGACCCTGGAGCCCAACAAGGACCTGCGGCCAGGGGACACGGTGACCATCACGTGC

TCCAGCTACCAGGGCTACCCTGAGGCTGAGGTGTTCTGGCAGGATGGGCAGGGTGTG

CCCCTGACTGGCAACGTGACCACGTCGCAGATGGCCAACGAGCAGGGCTTGTTTGAT

GTGCACAGCATCCTGCGGGTGGTGCTGGGTGCAAATGGCACCTACAGCTGCCTGGTG

CGCAACCCCGTGCTGCAGCAGGATGCGCACAGCTCTGTCACCATCACACCCCAGAGA

AGCCCCACAGGAGCCGTGGAGGTCCAGGTCCCTGAGGACCCGGTGGTGGCCCTAGTG

GGCACCGATGCCACCCTGCGCTGCTCCTTCTCCCCCGAGCCTGGCTTCAGCCTGGCA

CAGCTCAACCTCATCTGGCAGCTGACAGACACCAAACAGCTGGTGCACAGTTTCACC

GAAGGCCGGGACCAGGGCAGCGCCTATGCCAACCGCACGGCCCTCTTCCCGGACCTG

CTGGCACAAGGCAATGCATCCCTGAGGCTGCAGCGCGTGCGTGTGGCGGACGAGGGC

AGCTTCACCTGCTTCGTGAGCATCCGGGATTTCGGCAGCGCTGCCGTCAGCCTGCAG

GTGGCCGCTCCCTACTCGAAGCCCAGCATGACCCTGGAGCCCAACAAGGACCTGCGG

CCAGGGGACACGGTGACCATCACGTGCTCCAGCTACCGGGGCTACCCTGAGGCTGAG

GTGTTCTGGCAGGATGGGCAGGGTGTGCCCCTGACTGGCAACGTGACCACGTCGCAG

ATGGCCAACGAGCAGGGCTTGTTTGATGTGCACAGCGTCCTGCGGGTGGTGCTGGGT

GCGAATGGCACCTACAGCTGCCTGGTGCGCAACCCCGTGCTGCAGCAGGATGCGCAC

GGCTCTGTCACCATCACAGGGCAGCCTATGACATTCCCCCCAGAGGCCCTGTGGGTG

ACCGTGGGGCTGTCTGTCTGTCTCATTGCACTGCTGGTGGCCCTGGCTTTCGTGTGC

TGGAGAAAGATCAAACAGAGCTGTGAGGAGGAGAATGCAGGAGCTGAGGACCAGGAT

GGGGAGGGAGAAGGCTCCAAGACAGCCCTGCAGCCTCTGAAACACTCTGACAGCAAA

GAAGATGATGGACAAGAAATAGCCTGACCATGAGGACCAGGGAGCTGCTACCCCTCC

CTACAGCTCCTACCCTCTGGCTGCAATGGGGCTGCACTGTGAGCCCTGCCCCCAACA

GATGCATCCTGCTCTGACAGGTGGGCTCCTTCTCCAAAGGATGCGATACACAGACCA

CTGTGCAGCCTTATTTCTCCAATGGACATGATTCCCAAGTCATCCTGCTGCCTTTTT

TCTTATAGACACAATGAACAGACCACCCACAACCTTAGTTCTCTAAGTCATCCTGCC

TGCTGCCTTATTTCACAGTACATACATTTCTTAGGGACACAGTACACTGACCACATC

ACCACCCTCTTCTTCCAGTGCTGCGTGGACCATCTGGCTGCCTTTTTTCTCCAAAAG

ATGCAATATTCAGACTGACTGACCCCCTGCCTTATTTCACCAAAGACACGATGCATA

GTCACCCCGGCCTTGTTTCTCCAATGGCCGTGATACACTAGTGATCATGTTCAGCCC

TGCTTCCACCTGCATAGAATCTTTTCTTCTCAGACAGGGACAGTGCGGCCTCAACAT

CTCCTGGAGTCTAGAAGCTGTTTCCTTTCCCCTCCTTCCTCCTCTTGCTCTAGCCTT

AATACTGGCCTTTTCCCTCCCTGCCCCAAGTGAAGACAGGGCACTCTGCGCCCACCA

CATGCACAGCTGTGCATGGAGACCTGCAGGTGCACGTGCTGGAACACGTGTGGTTCC

CCCCTGGCCCAGCCTCCTCTGCAGTGCCCCTCTCCCCTGCCCATCCTCCCCACGGAA

GCATGTGCTGGTCACACTGGTTCTCCAGGGGTCTGTGATGGGGCCCCTGGGGGTCAG

CTTCTGTCCCTCTGCCTTCTCACCTCTTTGTTCCTTTCTTTTCATGTATCCATTCAG

TTGATGTTTATTGAGCAACTACAGATGTCAGCACTGTGTTAGGTGCTGGGGGCCCTG

CGTGGGAAGATAAAGTTCCTCCCTCAAGGACTCCCCATCCAGCTGGGAGACAGACAA

CTAACTACACTGCACCCTGCGGTTTGCAGGGGGCTCCTGCCTGGCTCCCTGCTCCAC

ACCTCCTCTGTGGCTCAAGGCTTCCTGGATACCTCACCCCCATCCCACCCATAATTC

TTACCCAGAGCATGGGGTTGGGGCGGAAACCTGGAGAGAGGGACATAGCCCCTCGCC

ACGGCTAGAGAATCTGGTGGTGTCCAAAATGTCTGTCCAGGTGTGGGCAGGTGGGCA

GGCACCAAGGCCCTCTGGACCTTTCATAGCAGCAGAAAAGGCAGAGCCTGGGGCAGG

GCAGGGCCAGGAATGCTTTGGGGACACCGAGGGGACTGCCCCCCACCCCCACCATGG

TGCTATTCTGGGGCTGGGGCAGTCTTTTCCTGGCTTGCCTCTGGCCAGCTCCTGGCC

TCTGGTAGAGTGAGACTTCAGACGTTCTGATGCCTTCCGGATGTCATCTCTCCCTGC

CCCAGGAATGGAAGATGTGAGGACTTCTAATTTAAATGTGGGACTCGGAGGGATTTT

GTAAACTGGGGGTATATTTTGGGGAAAATAAATGTCTTTGTAAAAA (SEQ ID

NO: 53)

>NP_001019907.1 CD276 antigen isoform a precursor [Homo

sapiens]

MLRRRGSPGMGVHVGAALGALWFCLTGALEVQVPEDPVVALVGTDATLCCSFSPEPG

FSLAQLNLIWQLTDTKQLVHSFAEGQDQGSAYANRTALFPDLLAQGNASLRLQRVRV

ADEGSFTCFVSIRDFGSAAVSLQVAAPYSKPSMTLEPNKDLRPGDTVTITCSSYQGY

PEAEVFWQDGQGVPLTGNVTTSQMANEQGLFDVHSILRVVLGANGTYSCLVRNPVLQ

QDAHSSVTITPQRSPTGAVEVQVPEDPVVALVGTDATLRCSFSPEPGFSLAQLNLIW

QLTDTKQLVHSFTEGRDQGSAYANRTALFPDLLAQGNASLRLQRVRVADEGSFTCFV

SIRDFGSAAVSLQVAAPYSKPSMTLEPNKDLRPGDTVTITCSSYRGYPEAEVFWQDG

QGVPLTGNVTTSQMANEQGLFDVHSVLRVVLGANGTYSCLVRNPVLQQDAHGSVTIT

GQPMTFPPEALWVTVGLSVCLIALLVALAFVCWRKIKQSCEEENAGAEDQDGEGEGS

KTALQPLKHSDSKEDDGQEIA (SEQ ID NO: 54)

Mouse B7-H3
>NM_133983.4 Mus musculus CD276 antigen (Cd276), mRNA

(CD276)
CGGCGCGGCGCGCCAAAGTGACCTGGTACAGCCTGGACCCCAAGCTCATCGGCTTTG

TCTGGCTGGCCGCCTGGCCTCTTCCCACTTGGATTTGGATGATCCTGAGGCCTTTGG

AGGAACTTCGAGACAAAGGCCCCTCTTCCTCTTCCACGGGCAGGAGCAGCCATTCGC

CACGGAGAGCCCAGCTGTCAGCTGTCTCACAGGAAGATGCTTCGAGGATGGGGTGGC

CCCAGTGTGGGTGTGTGTGTGCGCACAGCACTGGGGGTGCTGTGCCTCTGCCTCACA

GGAGCTGTGGAAGTCCAGGTCTCTGAAGACCCCGTGGTGGCCCTGGTGGACACGGAT

GCCACCCTACGCTGCTCCTTTTCCCCAGAGCCTGGCTTCAGTCTGGCACAGCTCAAC

CTCATCTGGCAGCTGACAGACACCAAACAGCTGGTGCACAGCTTCACGGAGGGCCGG

GACCAAGGCAGTGCCTACTCCAACCGCACAGCGCTCTTCCCTGACCTGTTGGTGCAA

GGCAATGCGTCCTTGAGGCTGCAGCGCGTCCGAGTAACCGACGAGGGCAGCTACACC

TGCTTTGTGAGCATCCAGGACTTTGACAGCGCTGCTGTTAGCCTGCAGGTGGCCGCC

CCCTACTCGAAGCCCAGCATGACCCTGGAGCCCAACAAGGACCTACGTCCAGGGAAC

ATGGTGACCATCACGTGCTCTAGCTACCAGGGCTATCCGGAGGCCGAGGTGTTCTGG

AAGGATGGACAGGGAGTGCCCTTGACTGGCAATGTGACCACATCCCAGATGGCCAAC

GAGCGGGGCTTGTTCGATGTTCACAGCGTGCTGAGGGTGGTGCTGGGTGCTAACGGC

ACCTACAGCTGCCTGGTACGCAACCCGGTGTTGCAGCAAGATGCTCACGGCTCAGTC

ACCATCACAGGGCAGCCCCTGACATTCCCCCCTGAGGCTCTGTGGGTAACCGTGGGG

CTCTCTGTCTGTCTTGTGGTACTACTGGTGGCCCTGGCTTTCGTGTGCTGGAGAAAG

ATCAAGCAGAGCTGCGAGGAGGAGAATGCAGGTGCCGAGGACCAGGATGGAGATGGA

GAAGGATCCAAGACAGCTCTACGGCCTCTGAAACCCTCTGAAAACAAAGAAGATGAC

GGACAAGAAATTGCTTGATTGGGAGCTGCTGCCCTTCCCAGGTGGGGGGCCCACCCT

CTGGCAGTGTTGAGCTTCAATGCGAGCCCTTCCCCCAACGAATGGGTTTGTCCCACA

GATCTACCCGTTCGTCAAAGGACGTGGTCCATAGACCACCCACAGCCTTACTTTTCC

AATGGACTTAATTCCCATCATCCTGCAGCCTCATTTCTCCAGTGACACGATACACGA

ACCATCCTGCGGCCTTATTTCCCACGGACACGACACAAAGATGTCCCTCCTCGGTGT

TCCTCCAGAGTCGTCTGGTGGCCTTGTGATACGGCGTGAACCTTCTTCCTTCTGCCT

TACGTCTAATGGACACACACGCACCACCCCCACACCCTTGCTCCTCCAAAGCCATGC

AGACTGTGTAACTGCTATTATTCTCCAAGGGGCATCCTGTGCAGATGAAACCCTGCT

TTATTTCCCTGAAGACAGCTGCACAGTGACCTCTTAGTTCTTGCTCCCATGGCCCTG

ATGTATCCTAGTTACCAGCCCTCAACCTCAGTTCTGAGGGTGGGATCCCATCGCTCA

GCAAGGCTTCATCCTGACCTCCCTGCCCTGATCTGATCTGGCCCTGGCTTTTGTTGT

CTCGCTCCCTGACTAAGTGAGATGGGGCACTCTCCCGCCCCCGCCCCCCCCAGGTCA

CAGATACCTACCTGCAGCTGTGCGTGCTGGATCACGCACATACTTGCCTTGCATGGT

CTCCTGGCTGCCCTGGGCTGTGCCTGTTCTTCCATAGGAAGCAAGTTCTTGTCTCCC

TGGTTCTCAGGGCCCCTCAGGGGCTCAGCCTTCAGCCCTGTGCTTCCCCATGTTGGG

AATCTTTGTTACCTTTTTCTTCTTTGTAAATTAACATCTGATAACAACCACAGGGTC

CAATGGGACTTTCACAGACCTGCCAGCTAGATAAATAATGACAACAGAAGTTTATTA

ATATTTTAAGACTTAGGCCTTTTGCTGGGCAGCCTCCCAACTATTCTATCCTGACTA

ATCCTGGCACTATGTCCCACCACATGGCCAGGTCTACCTCTCTGCTCCACTCTCCAT

CCACCTCCATGTCTGCCAGCAAATCTCCCGTGATTCAGTTCTTCTCCCAGAGTCCCT

ATCTCTGCCCAGAAGTACCATCTTCGACTTCCTGCCCAACTATTGGCCGTCAGCTCT

TCATTAAAGCCGATCAGATGTAATTCTAGATTGCCTTAGGCAGGTGAGGAAGAAACA

AGTATTTGTAAAATATGAGACCAGCAATGGGCCATAGAAATAACAGCACCAGATCCT

GCCAGCATTTAGCCCTCTGTTGGTACAAAATTAACAATTGAATATACAGAGACCTAC

TTCCAGAGTGTACCCCAACAACAGGCGTGAGCATGGTGCTGGGTACTAGGGTCCTGC

TGGAAAATCAGAGACCTTACCTACAGCTGGGACATGACCTTGCTTCCGACTTACCCA

CCACTTCTGGATACCTCACCCTCAGCCCACACTATCCCTGGCCTAGGGCCCAGGGTA

GAGCCAGAAACATGGAGAAAGCATGGCCCCTTGCCGTACCTGGAGAACTGGGTATTT

TCCAGAGTCTTTATAGATGTGGACTGGAAGGCAGGTGGCCACAGCCGTGCAGACCTG

GGTCAGGTCAGAAACCTATGCCATGCTGGGACCTACTCAACAGCAGAAGCATGAAGA

GGGCCTGAGGACAAGAAAGGCCTTCTTACCATGGTGCTATTCTGGAGCTGGGATATA

TACCTGGCTTGTCTCTGACTGCCCTGGCTTCTGGCAGAACTTCTGATGTCCTCCTGA

AGGCCTCTCTCCCACCCCAGTACCTGAGAACCTGAGGATAATTTAAACATGGGACTC

TGGCCAGCACCTGGGAGAGACAGGTAGATCTCTGATTTTTGACTCAGCCTGGTCTAT

CGAGTGAGTTCCAGGACATCTGGGGCTACACAGAGAAACCATCTTAAAGACTAAAAA

TAATAAACATGAGACTGTAAACTGGGTGTATTTTGGGAGAAATAAATGTCTTTTTCT

TTCAA (SEQ ID NO: 55)

>NP_598744.1 CD276 antigen precursor [Mus musculus]

MLRGWGGPSVGVCVRTALGVLCLCLTGAVEVQVSEDPVVALVDTDATLRCSFSPEPG

FSLAQLNLIWQLTDTKQLVHSFTEGRDQGSAYSNRTALFPDLLVQGNASLRLQRVRV

TDEGSYTCFVSIQDFDSAAVSLQVAAPYSKPSMTLEPNKDLRPGNMVTITCSSYQGY

PEAEVFWKDGQGVPLTGNVTTSQMANERGLFDVHSVLRVVLGANGTYSCLVRNPVLQ

QDAHGSVTITGQPLTFPPEALWVTVGLSVCLVVLLVALAFVCWRKIKQSCEEENAGA

EDQDGDGEGSKTALRPLKPSENKEDDGQEIA (SEQ ID NO: 56)

Human B7-H4
>NM_024626.4 Homo sapiens V-set domain containing T cell

(VTCN1)
activation inhibitor 1 (VTCN1), transcript variant 1,

mRNA

GTGAGTCACCAAGGAAGGCAGCGGCAGCTCCACTCAGCCAGTACCCAGATACGCTGG

GAACCTTCCCCAGCCATGGCTTCCCTGGGGCAGATCCTCTTCTGGAGCATAATTAGC

ATCATCATTATTCTGGCTGGAGCAATTGCACTCATCATTGGCTTTGGTATTTCAGGG

AGACACTCCATCACAGTCACTACTGTCGCCTCAGCTGGGAACATTGGGGAGGATGGA

ATCCTGAGCTGCACTTTTGAACCTGACATCAAACTTTCTGATATCGTGATACAATGG

CTGAAGGAAGGTGTTTTAGGCTTGGTCCATGAGTTCAAAGAAGGCAAAGATGAGCTG

TCGGAGCAGGATGAAATGTTCAGAGGCCGGACAGCAGTGTTTGCTGATCAAGTGATA

GTTGGCAATGCCTCTTTGCGGCTGAAAAACGTGCAACTCACAGATGCTGGCACCTAC

AAATGTTATATCATCACTTCTAAAGGCAAGGGGAATGCTAACCTTGAGTATAAAACT

GGAGCCTTCAGCATGCCGGAAGTGAATGTGGACTATAATGCCAGCTCAGAGACCTTG

CGGTGTGAGGCTCCCCGATGGTTCCCCCAGCCCACAGTGGTCTGGGCATCCCAAGTT

GACCAGGGAGCCAACTTCTCGGAAGTCTCCAATACCAGCTTTGAGCTGAACTCTGAG

AATGTGACCATGAAGGTTGTGTCTGTGCTCTACAATGTTACGATCAACAACACATAC

TCCTGTATGATTGAAAATGACATTGCCAAAGCAACAGGGGATATCAAAGTGACAGAA

TCGGAGATCAAAAGGCGGAGTCACCTACAGCTGCTAAACTCAAAGGCTTCTCTGTGT

GTCTCTTCTTTCTTTGCCATCAGCTGGGCACTTCTGCCTCTCAGCCCTTACCTGATG

CTAAAATAATGTGCCTCGGCCACAAAAAAGCATGCAAAGTCATTGTTACAACAGGGA

TCTACAGAACTATTTCACCACCAGATATGACCTAGTTTTATATTTCTGGGAGGAAAT

GAATTCATATCTAGAAGTCTGGAGTGAGCAAACAAGAGCAAGAAACAAAAAGAAGCC

AAAAGCAGAAGGCTCCAATATGAACAAGATAAATCTATCTTCAAAGACATATTAGAA

GTTGGGAAAATAATTCATGTGAACTAGACAAGTGTGTTAAGAGTGATAAGTAAAATG

CACGTGGAGACAAGTGCATCCCCAGATCTCAGGGACCTCCCCCTGCCTGTCACCTGG

GGAGTGAGAGGACAGGATAGTGCATGTTCTTTGTCTCTGAATTTTTAGTTATATGTG

CTGTAATGTTGCTCTGAGGAAGCCCCTGGAAAGTCTATCCCAACATATCCACATCTT

ATATTCCACAAATTAAGCTGTAGTATGTACCCTAAGACGCTGCTAATTGACTGCCAC

TTCGCAACTCAGGGGCGGCTGCATTTTAGTAATGGGTCAAATGATTCACTTTTTATG

ATGCTTCCAAAGGTGCCTTGGCTTCTCTTCCCAACTGACAAATGCCAAAGTTGAGAA

AAATGATCATAATTTTAGCATAAACAGAGCAGTCGGCGACACCGATTTTATAAATAA

ACTGAGCACCTTCTTTTTAAACAAACAAATGCGGGTTTATTTCTCAGATGATGTTCA

TCCGTGAATGGTCCAGGGAAGGACCTTTCACCTTGTCTATATGGCATTATGTCATCA

CAAGCTCTGAGGCTTCTCCTTTCCATCCTGCGTGGACAGCTAAGACCTCAGTTTTCA

ATAGCATCTAGAGCAGTGGGACTCAGCTGGGGTGATTTCGCCCCCCATCTCCGGGGG

AATGTCTGAAGACAATTTTGGTTACCTCAATGAGGGAGTGGAGGAGGATACAGTGCT

ACTACCAACTAGTGGATAGAGGCCAGGGATGCTGCTCAACCTCCTACCATGTACAGG

ACGTCTCCCCATTACAACTACCCAATCCGAAGTGTCAACTGTGTCAGGGCTAAGAAA

CCCTGGTTTTGAGTAGAAAAGGGCCTGGAAAGAGGGGAGCCAACAAATCTGTCTGCT

TCCTCACATTAGTCATTGGCAAATAAGCATTCTGTCTCTTTGGCTGCTGCCTCAGCA

CAGAGAGCCAGAACTCTATCGGGCACCAGGATAACATCTCTCAGTGAACAGAGTTGA

CAAGGCCTATGGGAAATGCCTGATGGGATTATCTTCAGCTTGTTGAGCTTCTAAGTT

TCTTTCCCTTCATTCTACCCTGCAAGCCAAGTTCTGTAAGAGAAATGCCTGAGTTCT

AGCTCAGGTTTTCTTACTCTGAATTTAGATCTCCAGACCCTGCCTGGCCACAATTCA

AATTAAGGCAACAAACATATACCTTCCATGAAGCACACACAGACTTTTGAAAGCAAG

GACAATGACTGCTTGAATTGAGGCCTTGAGGAATGAAGCTTTGAAGGAAAAGAATAC

TTTGTTTCCAGCCCCCTTCCCACACTCTTCATGTGTTAACCACTGCCTTCCTGGACC

TTGGAGCCACGGTGACTGTATTACATGTTGTTATAGAAAACTGATTTTAGAGTTCTG

ATCGTTCAAGAGAATGATTAAATATACATTTCCTACACCA (SEQ ID NO: 57)

>NP_078902.2 V-set domain-containing T-cell activation

inhibitor 1 isoform 1 precursor [Homo sapiens]

MASLGQILFWSIISIIIILAGAIALIIGFGISGRHSITVTTVASAGNIGEDGILSCT

FEPDIKLSDIVIQWLKEGVLGLVHEFKEGKDELSEQDEMFRGRTAVFADQVIVGNAS

LRLKNVQLTDAGTYKCYIITSKGKGNANLEYKTGAFSMPEVNVDYNASSETLRCEAP

RWFPQPTVVWASQVDQGANFSEVSNTSFELNSENVTMKVVSVLYNVTINNTYSCMIE

NDIAKATGDIKVTESEIKRRSHLQLLNSKASLCVSSFFAISWALLPLSPYLMLK

(SEQ ID NO: 58)

Mouse B7-H4
>NM_178594.3 Mus musculus V-set domain containing T cell

(VTCN1)
activation inhibitor 1 (Vtcn1), mRNA

GTGAGTCACAACACCCAGGAGGGCAGCAGCAGGCAGGCAGCTCCACTCACCAAAATC

TGGCCCCACACACAGCAGGACTGTGGGAAGGAACTCCCTCTCCATGGCTTCCTTGGG

GCAGATCATCTTTTGGAGTATTATTAACATCATCATCATCCTGGCTGGGGCCATCGC

ACTCATCATTGGCTTTGGCATTTCAGGCAAGCACTTCATCACGGTCACGACCTTCAC

CTCAGCTGGAAACATTGGAGAGGACGGGACCCTGAGCTGCACTTTTGAACCTGACAT

CAAACTCAACGGCATCGTCATCCAGTGGCTGAAAGAAGGCATCAAAGGTTTGGTCCA

CGAGTTCAAAGAAGGCAAAGACGACCTCTCACAGCAGCATGAGATGTTCAGAGGCCG

CACAGCAGTGTTTGCTGATCAGGTGGTAGTTGGCAATGCTTCCCTGAGACTGAAAAA

CGTGCAGCTCACGGATGCTGGCACCTACACATGTTACATCCGCACCTCAAAAGGCAA

AGGGAATGCAAACCTTGAGTATAAGACCGGAGCCTTCAGTATGCCAGAGATAAATGT

GGACTATAATGCCAGTTCAGAGAGTTTACGCTGCGAGGCTCCTCGGTGGTTCCCCCA

GCCCACAGTGGCCTGGGCATCTCAAGTCGACCAAGGAGCCAATTTCTCAGAAGTCTC

CAACACCAGCTTTGAGTTGAACTCTGAGAATGTGACCATGAAGGTCGTATCTGTGCT

CTACAATGTCACAATCAACAACACATACTCCTGTATGATTGAAAACGACATTGCCAA

AGCCACCGGGGACATCAAAGTGACAGATTCAGAGGTCAAAAGGCGAAGTCAGCTGCA

GTTGCTGAACTCTGGGCCTTCCCCGTGTGTTTTTTCTTCTGCCTTTGTGGCTGGCTG

GGCACTCCTATCTCTCTCCTGTTGCCTGATGCTAAGATGAGGGGCCCTGGCTACACA

AAAGCATGCAACGTTGCTGGTCCAACAGAATCCCGGAGAACTACAGAAATATTTTCC

TCAAGACATGACCTAGTTTTATATTTCTAGAAGAAGATGAAATCATGTCTAGAAGTC

TGGAGAGAGCAGACAGGAACAAGATGTGGAAGGAAAACAAAAGTAACCCACAGACAC

CCCCGATCGGAACAAGATGGACCTAGAAAATAATTCAACCAAACTAGAGTATACTAA

GTGTGCTGTTACAATGTGTGTAGGGTAGGTGTCCTCCCACATCTCAGGGGCCTCCCC

TGGTCCACCAGCTCCTGAGTTAGGATGGGCTGTTATGATGTCACTCTGAAGGTTCCT

GGATGGTTCCTACTGCCATATACTCATTTTATATTCAGCACATTAAACCATAGTGAA

TGCTATGAAAAGCTGCTAATCAGCTGCCACTCCGAGATTCGGAGGTGGCAACGTCTG

AGTGACAGGTCCAGTGATTCGCTTCTCCTTAGGATGCTTTTACAAGCTCTTTGGCGT

CTCCTCCCACCTGGCAAATGCCAAATGCATAGGGGAGGGTGATCATCATTCTAGGGC

AAACAAAATAGTTGAGGGATGCTGATTTCCCAAATCATCCGAATCACTTCTCCCTTG

AGCAAACAAGCGCCCTGTTATTTCTCAAATGCTGCTTTGTGAATCAGTCCAGGGCAA

GGCGCTCTCCTCATCCCGCTATGTGGCCTTAAGTCATCGTAAGGTTTGAAGTTTCTA

CTTTCGATCCTGCATGGAGAGCTATAATCTCAGCTCCCCCGCCCCCCCCACACACAC

CTCTGCACACACACCCCCCCCCAACACTGGGAGTAAACCAGGATGATGTCCGTCTTC

TCATTCCCCATGTGACCGTTGGCAGTGTAGAGAGACTGATTGTCACAGCTAAAGGAA

GAGGGACAACAGGGTCACTGGTGTCTACAGAGATTATATTCTACGTGTCTCACTGAA

TTTACACAACTCCAAGTGCCAACCACATCAAGGTCAGGAAATCCTGAACTGGAATAA

GAAAGACCCAGAAGATGAATGTGAACAGATCCATTTGCTTCCCGACAGTGGGCACAG

ACTTCAGTCTCTGGCTACTGTTCCAAGACCCAGGGCTCTGCAATTGTGTGACATCCT

TCAGTGAACCCACATGGGAAATTCTCCATGGAATTATCTTCAGCCCACTGTACTTCT

GAATCCCTCTTCCTTCCTTCTGTGCCACACAGCAAGTCTGGCTTAAATGCTGCCTGA

TCTCCATTTCAAGTTTTCTGCCTCTGGATTTTTAGATCTCAAGACCATGGACGAAAC

ATCAGTTACAGCAACAAAAGTGAATTTTCCGTGCAGAGACTTCTAGGGGTTCTGTTT

GTTTTCAGGGTGCTAGAGATCACACTCAGATGCTCATATATGTTAGGTAAATGTTCT

CCCACTGAGTTACAGCCCAGCTCACACAGAGACTTCTAAAAGAAAATACGGCCATGC

TCTTTGAAATGGAGCATTGAGGGATGAAGTTTGGATGGCGAAGAAAACTTCTCACCA

GCTCTCTCCCCACATTCGTGCCAAGCACTGCCTCCCTAGACTTCGGGTCACCATATC

TGTACTACGTTTTGATACAGAAGGCTCGAGACCATTCAAGAGAATTATTTAGTACAC

(SEQ ID NO: 59)

>NP_848709.2 V-set domain containing T-cell activation

inhibitor 1 precursor [Mus musculus]

MASLGQIIFWSIINIIIILAGAIALIIGFGISGKHFITVTTFTSAGNIGEDGTLSCT

FEPDIKLNGIVIQWLKEGIKGLVHEFKEGKDDLSQQHEMFRGRTAVFADQVVVGNAS

LRLKNVQLTDAGTYTCYIRTSKGKGNANLEYKTGAFSMPEINVDYNASSESLRCEAP

RWFPQPTVAWASQVDQGANFSEVSNTSFELNSENVTMKVVSVLYNVTINNTYSCMIE

NDIAKATGDIKVTDSEVKRRSQLQLLNSGPSPCVESSAFVAGWALLSLSCCLMLR

(SEQ ID NO: 60)

Human B7-H5
>NM_022153.2 Homo sapiens V-set immunoregulatory receptor

(VISTA)
(VSIR), mRNA

AGTCGCGGGAGGCTTCCCCGCGCCGGCCGCGTCCCGCCCGCTCCCCGGCACCAGAAG

TTCCTCTGCGCGTCCGACGGCGACATGGGCGTCCCCACGGCCCTGGAGGCCGGCAGC

TGGCGCTGGGGATCCCTGCTCTTCGCTCTCTTCCTGGCTGCGTCCCTAGGTCCGGTG

GCAGCCTTCAAGGTCGCCACGCCGTATTCCCTGTATGTCTGTCCCGAGGGGCAGAAC

GTCACCCTCACCTGCAGGCTCTTGGGCCCTGTGGACAAAGGGCACGATGTGACCTTC

TACAAGACGTGGTACCGCAGCTCGAGGGGCGAGGTGCAGACCTGCTCAGAGCGCCGG

CCCATCCGCAACCTCACGTTCCAGGACCTTCACCTGCACCATGGAGGCCACCAGGCT

GCCAACACCAGCCACGACCTGGCTCAGCGCCACGGGCTGGAGTCGGCCTCCGACCAC

CATGGCAACTTCTCCATCACCATGCGCAACCTGACCCTGCTGGATAGCGGCCTCTAC

TGCTGCCTGGTGGTGGAGATCAGGCACCACCACTCGGAGCACAGGGTCCATGGTGCC

ATGGAGCTGCAGGTGCAGACAGGCAAAGATGCACCATCCAACTGTGTGGTGTACCCA

TCCTCCTCCCAGGATAGTGAAAACATCACGGCTGCAGCCCTGGCTACGGGTGCCTGC

ATCGTAGGAATCCTCTGCCTCCCCCTCATCCTGCTCCTGGTCTACAAGCAAAGGCAG

GCAGCCTCCAACCGCCGTGCCCAGGAGCTGGTGCGGATGGACAGCAACATTCAAGGG

ATTGAAAACCCCGGCTTTGAAGCCTCACCACCTGCCCAGGGGATACCCGAGGCCAAA

GTCAGGCACCCCCTGTCCTATGTGGCCCAGCGGCAGCCTTCTGAGTCTGGGCGGCAT

CTGCTTTCGGAGCCCAGCACCCCCCTGTCTCCTCCAGGCCCCGGAGACGTCTTCTTC

CCATCCCTGGACCCTGTCCCTGACTCTCCAAACTTTGAGGTCATCTAGCCCAGCTGG

GGGACAGTGGGCTGTTGTGGCTGGGTCTGGGGCAGGTGCATTTGAGCCAGGGCTGGC

TCTGTGAGTGGCCTCCTTGGCCTCGGCCCTGGTTCCCTCCCTCCTGCTCTGGGCTCA

GATACTGTGACATCCCAGAAGCCCAGCCCCTCAACCCCTCTGGATGCTACATGGGGA

TGCTGGACGGCTCAGCCCCTGTTCCAAGGATTTTGGGGTGCTGAGATTCTCCCCTAG

AGACCTGAAATTCACCAGCTACAGATGCCAAATGACTTACATCTTAAGAAGTCTCAG

AACGTCCAGCCCTTCAGCAGCTCTCGTTCTGAGACATGAGCCTTGGGATGTGGCAGC

ATCAGTGGGACAAGATGGACACTGGGCCACCCTCCCAGGCACCAGACACAGGGCACG

GTGGAGAGACTTCTCCCCCGTGGCCGCCTTGGCTCCCCCGTTTTGCCCGAGGCTGCT

CTTCTGTCAGACTTCCTCTTTGTACCACAGTGGCTCTGGGGCCAGGCCTGCCTGCCC

ACTGGCCATCGCCACCTTCCCCAGCTGCCTCCTACCAGCAGTTTCTCTGAAGATCTG

TCAACAGGTTAAGTCAATCTGGGGCTTCCACTGCCTGCATTCCAGTCCCCAGAGCTT

GGTGGTCCCGAAACGGGAAGTACATATTGGGGCATGGTGGCCTCCGTGAGCAAATGG

TGTCTTGGGCAATCTGAGGCCAGGACAGATGTTGCCCCACCCACTGGAGATGGTGCT

GAGGGAGGTGGGTGGGGCCTTCTGGGAAGGTGAGTGGAGAGGGGCACCTGCCCCCCG

CCCTCCCCATCCCCTACTCCCACTGCTCAGCGCGGGCCATTGCAAGGGTGCCACACA

ATGTCTTGTCCACCCTGGGACACTTCTGAGTATGAAGCGGGATGCTATTAAAAACTA

CATGGGGAAACAGGTGCAAACCCTGGAGATGGATTGTAAGAGCCAGTTTAAATCTGC

ACTCTGCTGCTCCTCCCCCACCCCCACCTTCCACTCCATACAATCTGGGCCTGGTGG

AGTCTTCGCTTCAGAGCCATTCGGCCAGGTGCGGGTGATGTTCCCATCTCCTGCTTG

TGGGCATGCCCTGGCTTTGTTTTTATACACATAGGCAAGGTGAGTCCTCTGTGGAAT

TGTGATTGAAGGATTTTAAAGCAGGGGAGGAGAGTAGGGGGCATCTCTGTACACTCT

GGGGGTAAAACAGGGAAGGCAGTGCCTGAGCATGGGGACAGGTGAGGTGGGGCTGGG

CAGACCCCCTGTAGCGTTTAGCAGGATGGGGGCCCCAGGTACTGTGGAGAGCATAGT

CCAGCCTGGGCATTTGTCTCCTAGCAGCCTACACTGGCTCTGCTGAGCTGGGCCTGG

GTGCTGAAAGCCAGGATTTGGGGCTAGGCGGGAAGATGTTCGCCCAATTGCTTGGGG

GGTTGGGGGGATGGAAAAGGGGAGCACCTCTAGGCTGCCTGGCAGCAGTGAGCCCTG

GGCCTGTGGCTACAGCCAGGGAACCCCACCTGGACACATGGCCCTGCTTCTAAGCCC

CCCAGTTAGGCCCAAAGGAATGGTCCACTGAGGGCCTCCTGCTCTGCCTGGGCTGGG

CCAGGGGCTTTGAGGAGAGGGTAAACATAGGCCCGGAGATGGGGCTGACACCTCGAG

TGGCCAGAATATGCCCAAACCCCGGCTTCTCCCTTGTCCCTAGGCAGAGGGGGGTCC

CTTCTTTTGTTCCCTCTGGTCACCACAATGCTTGATGCCAGCTGCCATAGGAAGAGG

GTGCTGGCTGGCCATGGTGGCACACACCTGTCCTCCCAGCACTTTGCAGGGCTGAGG

TGGAAGGACCGCTTAAGCCCAGGTGTTCAAGGCTGCTGTGAGCTGTGTTCGAGCCAC

TACACTCCAGCCTGGGGACGGAGCAAAACTTTGCCTCAAAACAAATTTTAAAAAGAA

AGAAAGAAGGAAAGAGGGTATGTTTTTCACAATTCATGGGGGCCTGCATGGCAGGAG

TGGGGACAGGACACCTGCTGTTCCTGGAGTCGAAGGACAAGCCCACAGCCCAGATTC

CGGTTCTCCCAACTCAGGAAGAGCATGCCCTGCCCTCTGGGGAGGCTGGCCTGGCCC

CAGCCCTCAGCTGCTGACCTTGAGGCAGAGACAACTTCTAAGAATTTGGCTGCCAGA

CCCCAGGCCTGGCTGCTGCTGTGTGGAGAGGGAGGCGGCCCGCAGCAGAACAGCCAC

CGCACTTCCTCCTCAGCTTCCTCTGGTGCGGCCCTGCCCTCTCTTCTCTGGACCCTT

TTACAACTGAACGCATCTGGGCTTCGTGGTTTCCTGTTTTCAGCGAAATTTACTCTG

AGCTCCCAGTTCCATCTTCATCCATGGCCACAGGCCCTGCCTACAACGCACTAGGGA

CGTCCCTCCCTGCTGCTGCTGGGGAGGGGCAGGCTGCTGGAGCCGCCCTCTGAGTTG

CCCGGGATGGTAGTGCCTCTGATGCCAGCCCTGGTGGCTGTGGGCTGGGGTGCATGG

GAGAGCTGGGTGCGAGAACATGGCGCCTCCAGGGGGCGGGAGGAGCACTAGGGGCTG

GGGCAGGAGGCTCCTGGAGCGCTGGATTCGTGGCACAGTCTGAGGCCCTGAGAGGGA

AATCCATGCTTTTAAGAACTAATTCATTGTTAGGAGATCAATCAGGAATTAGGGGCC

ATCTTACCTATCTCCTGACATTCACAGTTTAATAGAGACTTCCTGCCTTTATTCCCT

CCCAGGGAGAGGCTGAAGGAATGGAATTGAAAGCACCATTTGGAGGGTTTTGCTGAC

ACAGCGGGGACTGCTCAGCACTCCCTAAAAACACACCATGGAGGCCACTGGTGACTG

CTGGTGGGCAGGCTGGCCCTGCCTGGGGGAGTCCGTGGCGATGGGCGCTGGGGTGGA

GGTGCAGGAGCCCCAGGACCTGCTTTTCAAAAGACTTCTGCCTGACCAGAGCTCCCA

CTACATGCAGTGGCCCAGGGCAGAGGGGCTGATACATGGCCTTTTTCAGGGGGTGCT

CCTCGCGGGGTGGACTTGGGAGTGTGCAGTGGGACAGGGGGCTGCAGGGGTCCTGCC

ACCACCGAGCACCAACTTGGCCCCTGGGGTCCTGCCTCATGAATGAGGCCTTCCCCA

GGGCTGGCCTGACTGTGCTGGGGGCTGGGTTAACGTTTTCTCAGGGAACCACAATGC

ACGAAAGAGGAACTGGGGTTGCTAACCAGGATGCTGGGAACAAAGGCCTCTTGAAGC

CCAGCCACAGCCCAGCTGAGCATGAGGCCCAGCCCATAGACGGCACAGGCCACCTGG

CCCATTCCCTGGGCATTCCCTGCTTTGCATTGCTGCTTCTCTTCACCCCATGGAGGC

TATGTCACCCTAACTATCCTGGAATGTGTTGAGAGGGATTCTGAATGATCAATATAG

CTTGGTGAGACAGTGCCGAGATAGATAGCCATGTCTGCCTTGGGCACGGGAGAGGGA

AGTGGCAGCATGCATGCTGTTTCTTGGCCTTTTCTGTTAGAATACTTGGTGCTTTCC

AACACACTTTCACATGTGTTGTAACTTGTTTGATCCACCCCCTTCCCTGAAAATCCT

GGGAGGTTTTATTGCTGCCATTTAACACAGAGGGCAATAGAGGTTCTGAAAGGTCTG

TGTCTTGTCAAAACAAGTAAACGGTGGAACTACGACTAAA (SEQ ID NO: 61)

>NP_071436.1 V-type immunoglobulin domain-containing

suppressor of T-cell activation precursor [Homo sapiens]

MGVPTALEAGSWRWGSLLFALFLAASLGPVAAFKVATPYSLYVCPEGQNVTLTCRLL

GPVDKGHDVTFYKTWYRSSRGEVQTCSERRPIRNLTFQDLHLHHGGHQAANTSHDLA

QRHGLESASDHHGNFSITMRNLTLLDSGLYCCLVVEIRHHHSEHRVHGAMELQVQTG

KDAPSNCVVYPSSSQDSENITAAALATGACIVGILCLPLILLLVYKQRQAASNRRAQ

ELVRMDSNIQGIENPGFEASPPAQGIPEAKVRHPLSYVAQRQPSESGRHLLSEPSTP

LSPPGPGDVFFPSLDPVPDSPNFEVI (SEQ ID NO: 62)

Mouse B7-H5
>NM_028732.4 Mus musculus V-set immunoregulatory receptor

(VISTA)
(Vsir), transcript variant 1, mRNA

GGGGGCGCTGCTGGGCGGGGAGCTTGCTCGGCCGCCTGCCTCGCCTTGGGCTCAGCA

TTCACTCTAGCGAGCGAGCGGCGTGTACAGCCGGCTCCCTGGGCTCCTGGAGTCCCG

CTTGCTCCAAGCGCACTCCAGCAGTCTCTTTCTGCTCTTGCCCGGCTCGACGGCGAC

ATGGGTGTCCCCGCGGTCCCAGAGGCCAGCAGCCCGCGCTGGGGAACCCTGCTCCTT

GCTATTTTCCTGGCTGCATCCAGAGGTCTGGTAGCAGCCTTCAAGGTCACCACTCCA

TATTCTCTCTATGTGTGTCCCGAGGGACAGAATGCCACCCTCACCTGCAGGATTCTG

GGCCCCGTGTCCAAAGGGCACGATGTGACCATCTACAAGACGTGGTACCTCAGCTCA

CGAGGCGAGGTCCAGATGTGCAAAGAACACCGGCCCATACGCAACTTCACATTGCAG

CACCTTCAGCACCACGGAAGCCACCTGAAAGCCAACGCCAGCCATGACCAGCCCCAG

AAGCATGGGCTAGAGCTAGCTTCTGACCACCACGGTAACTTCTCTATCACCCTGCGC

AATGTGACCCCAAGGGACAGCGGCCTCTACTGCTGTCTAGTGATAGAATTAAAAAAC

CACCACCCAGAACAACGGTTCTACGGGTCCATGGAGCTACAGGTACAGGCAGGCAAA

GGCTCGGGGTCCACATGCATGGCGTCTAATGAGCAGGACAGTGACAGCATCACGGCT

GCGGCCCTGGCCACCGGCGCCTGCATCGTGGGAATCCTCTGCCTCCCCCTTATCCTG

CTGCTGGTCTATAAGCAGAGACAGGTGGCCTCTCACCGCCGTGCCCAGGAGTTGGTG

AGGATGGACAGCAGCAACACCCAAGGAATCGAAAACCCAGGCTTCGAGACCACTCCA

CCCTTCCAGGGGATGCCTGAGGCCAAGACCAGGCCGCCACTGTCCTATGTGGCCCAG

CGGCAACCTTCGGAGTCAGGACGGTACCTGCTCTCTGACCCCAGCACACCTCTGTCG

CCTCCAGGCCCTGGGGACGTCTTTTTCCCATCCCTAGATCCAGTCCCTGACTCCCCT

AACTCTGAAGCCATCTAAACCAGCTGGGGAACCATGAACCATGGTACCTGGGTCAGG

GATATGTGCACTTGATCTATGGCTGGCCCTTGGACAGTCTTTTAGGCACTGACTCCA

GCTTCCTTGCTCCTGCTCTGAGCCTAGACTCTGCTTTTACAAGATGCACAGACCCTC

CCCTATCTCTTTCAGACGCTACTTGGGGGGCAGGGAGAAGATGTTGGATTGCTCATT

GCTGTTCTCAAGATCTTGGGATGCTGAGTTCTCCCTAGAGACTTGACTTCGACAGCC

ACAGATGTCAGATGACCTGCATCCTATGAACGTCCGGCTTGGCAAGAGCCTTTCTTC

ATGGAAACCAGTAGCCCGGAGGGGATGAGGTAGGCACCTTGCCACCCTCCCGGGAGA

GAGACACAAGATGTGAGAGACTCCTGCTCACTGTGGGGGTGTGGCTGGCCTGCTTGT

TTGCCTGAGGATGCTCCTCTGTTGGACTGACTCTATCCCCCTGGATTCTGGAGCTTG

GCTGGCCTATGTCCCACCAGAGGAGCATCTCAGCAGCCTTCCACCAGCAACCTGAGG

GCCTGCCAGCTTCGTGGCTCTGGGCTCTCATTACCTGTATGGCCGTCCACAGAGCTC

AGTGGCCAGAGGCTTTGAAACAGGAAGTACATGTCAGGTTCAGGAACCACTGTGAGC

TCATTAGTGTCTTGAGCAATGTGAGGCCTGGACCAGTGGACACGGAGGGAGGGTGGC

GAGAGGATGATGGGGATGATGAGGGGAACACGCTCCCTTCCTGTCCTTGTCATCCAC

CACTACCACTATTCAGTGTGGAGCAGTGGCAAAGGTGACCGACCTCCACAATGTCCT

AGTGATGCTGGACCATTTCTAAGTGTGAAAGAGATGCTATTAAAAACAGTATGTGGC

AATGGCTGCCAACAGCTGAGTGGACTGGAGGCACTGGCTTTAAGGCCCTGGAGGTGC

AGGGCCCGGTATGGGGATAGGGATGGGAGTTTCAGTGAGGGCCTAGGGATCACTCCG

CTTCTGACCACTCTTCTTCTGAGCCTCACCTCAGGGTGACCTTCAGGCACACAGAAG

AGCTTGCCCCTGGTCCGATACTACTCTTGGCTCTCATCTCCAGGGTTTGGCATGACC

TGGGCACACAGGGGGAGTCTTCAGAAAGGATTTTAAAGCATGAAAAGAAAGGGTAGT

TCTTGTGAGGTAGGGATGGGCAGCTGATGTTTGAGAGTGAGGAGGGATACGGCTGGG

CAGATCACTCTCCAGTCTCTAGAGGGAAAGTAGCTCTAAGTCTGGGAGAGCAGCAGC

CCAGTGGTACCATATGTCTTCTTGCAGCTTCCACTGGCTGGGCTGAACTGGGCATGG

GTAGGAAAGCTCCTGTTCTGGGCCTGCAGCCAGGGAGAACCCCATTCATTCCCTGAG

GACAGATGGGTGGGGAGAGAAGAGAGAGTTTCAGGCCGGGAAGCAGCAATAAGCTAT

CTGCTGGGGACCCAGACAAGTTGTCTGATGAGGTCCAAGATGTGGGATGCCAGTTAT

ACCTGGGGCTTGGGGATCCTTAGAGGCTTTGTATCATCATCATAGGAGTGTCGGGGT

GGCCAGGGCATCAAAGCCATGACCCCTGTTTTATCCTCAGGGTCCACTCTTCTGCAC

CATCCATTGCTCTAGATCTATGCAGTTACTATAGACAGAATGTGTTGTTCTGTTTGG

CTTTGGGGATAATGGCCTGGCGAACTGCCAGCTGTTCAGTGGCAGGGCTGTGAGGCC

AGTCAAAGACTAGAACCCACAGACCAGCTGAACGATGAGTATAGCCTGTCCCCTGGG

GGAGCCTGACCTGTCTCCAGCCCTAAGCTTCAGACCTCACCACTCAGATGACTTCTA

AGAATTTGCCTGTGGGGACCCCTGCATGGCTGCAGCTCCGTGGAAAGGAGAGGAGGC

CCCCAGCAGAAGAACCACTCGCTTCCTGCCCAGCTTCCTCCTGTAGGGCTCTAAGTC

TCTTCTTCTTGGGACCCTGCAAGCAAAGGCATGTCAGCTTGGTGGTTTCCTGTTTTG

GGTGAAGTTTTGTGTGGTCCGGGTTCTGTCTACATCCATGAACTTGGGTGCTACCAC

CTTGCTGCTGCTGTAGAGACAGCTGCAGGATCTTAGGGTGGAAAATGGAGGTGCCCT

GAGGTGCTAGCCCTTGGGGCAAAAGATGGGGTGGCAATGAGACACAGTGGGGAACTG

AGTTCCCCAAGAGGAGGGAGGAGCCCTGTAGCCTCAAGGGCCATATTGGGTTCCTGG

TACCAGCAAAAGCCTAGAGAGCGAAGTCTGTATTTTGAGGAGGTAATTGATCCTTAC

GGAATCCATCAGAAATTTGGAGCGGGTGCTTTATCTATCTCTGGAGGGTCTCTACCT

ATCTCCGATGAAGCTCTCCCTGGGCCTGGGATGGGAGAAACCAGGAGGAAAGGTGTC

TGATAAAGCAGGGGCTTCTTGACAAGCCAAAGGGCCACTGGTAGCTGTTGTGGACCG

AGCTGACCCTGCTGAAGTATTGTAGTGTGCCTTGGACCAACTTCTCAAAAGAGCAAC

CCCGGGGCTACCCTACTTCTGCCAGGAAGAGGCGGAGAAGGGGCTGAGAGGCCTGGA

AGGGGCTAGCTCCTTCTTTGAGAACTGCTCCCCGGAGGACTTGGAGGAGGCGGCTAG

GCTACGGGCTGCTGAGGGCCCTTTGTCTTTCCTAACCTGGGCACTGTTAGGATGCTC

CCTCCTGGAAAAGGCTTTCCTGGGTGTGAGCTAGAGCAGTGTCCATGCCAGCGCTGA

ACCTGCCATGGTGGGAGCTGAACTAAAAATTTCTCAGGGAACTAAAATAGGCAAAAG

AGGAACTGGGGGAGGAGGGTGCCAGGCAGGATGGGGGGAAGGGAGGGCAGTGCAAAA

GTCTCTTGAAACACAGACAGCCCAGCTGAGTGCCAGTCCCAGATCACAGAGAATACG

GCTCATCTGGCTCATGTTCTGCATGCTTGCTGCTTTACCCTGGCACTTTCCTTCTCC

ACCATGAGTGCGAGTCCTGGGAGTCCTGGGAGGGTGAGGATTAATGCCAGCCTGGGG

AGCAGATAGCTGACAGAGTCCTTGGGTAACTGGCTTGAACCAGGACCTCAGGATTCC

ACTCTGGGGATCTAGCTTTGTCTGGGCCAGTGAAGATCTCTATAATGGCATTATTGC

CAGGGGATAAACATTTCACTGGGTTCTGATCTGTTGGGTGTGGCTTCCTGGAAAATA

TGGTGAGAGGAATTCTGCTAAGGATACAGTTGATAAGAAAGTTCTGAGATTGATTAG

TAATGCCTGCCTTGGACTCAGGAAGGGAAGTGGCAGTATGAATGCCATGTCTTAATC

ATTTTGGTTAAAATATGCTTCCCAAAAGATTTCCACGTGTGTTCTTGTTTATTTGAC

ATCTGTCTCCATATCAGTCTTGAAAGCCTTTCTGTGTGTATATATATGATGTTTGCG

TGTATATATGTTTTTGTGTGTGCATATGGAAGTCAGAAATCACTGGGTGTCTTCCTC

CATTCCTTTGCAATGTATGTTTTTTTTTTTTTTACGATTTATTTACTATATGAATGT

TTTGCCTGAATACATGCATAGGTGTCACGTACATGCCTGCTGGAACGCTTGGAACTG

GAGTTACAGGTGGCTATGAGCTACAGTGTGAGCACTGGGAATCAAACCTGGGTCTTC

TGCAAGAGCAACAAATTAAAAGTCAGCTCTTAACTACTTGAGCTATTTTTCCAACTC

C (SEQ ID NO: 63)

>NP_083008.1 V-type immunoglobulin domain-containing

suppressor of T-cell activation isoform 1 precursor [Mus

musculus]

MGVPAVPEASSPRWGTLLLAIFLAASRGLVAAFKVTTPYSLYVCPEGQNATLTCRIL

GPVSKGHDVTIYKTWYLSSRGEVQMCKEHRPIRNFTLQHLQHHGSHLKANASHDQPQ

KHGLELASDHHGNFSITLRNVTPRDSGLYCCLVIELKNHHPEQRFYGSMELQVQAGK

GSGSTCMASNEQDSDSITAAALATGACIVGILCLPLILLLVYKQRQVASHRRAQELV

RMDSSNTQGIENPGFETTPPFQGMPEAKTRPPLSYVAQRQPSESGRYLLSDPSTPLS

PPGPGDVFFPSLDPVPDSPNSEAI (SEQ ID NO: 64)

Human B7-H7
>NM_007072.4 Homo sapiens HERV-H LTR-associating 2

(HHLA2)
(HHLA2), transcript variant 1, mRNA

AGTTCTCTTCAAGTCATGTAATCGACTTTTTTGAATTAGTTTTCAGTTTCATTTTGT

TTTCCCTAATTCAAGTTGGGAACACTTCATTTTCCCCAATTCAAGTTGGGAACACTT

CCTTGGTATTTCCTTGCTACATGGACTTTAGCAAATGCTACTTTACTCTCCTTCCAG

CTACTCAGGAGGCTGAGGCAGGAGAATCGCTTGAACCCGGGAGGCGGAGGTTACAGT

GAGCCTTTTCCTAGTTTTACTGTTGGAAGCCTAACTCACAGGAGAGATTATGCAATA

CAGTCCTGAAGTCAAGGGAGGAGAGCATGTAGGAGAATACTAACCCTGCACAGATTG

TGATGGTGATGTGGAATATACTAAAGCCTAGAACGCACCTCCTCTGCATGACTAATA

TGTTCTGCACAAGACATGAAGGCACAGACAGCACTGTCTTTCTTCCTCATTCTCATA

ACATCTCTGAGTGGATCTCAAGGCATATTCCCTTTGGCTTTCTTCATTTATGTTCCT

ATGAATGAACAAATCGTCATTGGAAGACTTGATGAAGATATAATTCTCCCTTCTTCA

TTTGAGAGGGGATCCGAAGTCGTAATACACTGGAAGTATCAAGATAGCTATAAGGTT

CACAGTTACTACAAAGGCAGTGACCATTTGGAAAGCCAAGATCCCAGATATGCAAAC

AGGACATCCCTTTTCTATAATGAGATTCAAAATGGGAATGCGTCGCTATTTTTCAGA

AGAGTAAGCCTTCTGGACGAAGGAATTTACACCTGCTATGTAGGAACAGCAATTCAA

GTGATTACAAACAAAGTGGTGCTAAAGGTGGGAGTTTTTCTCACACCCGTGATGAAG

TATGAAAAGAGGAACACAAACAGCTTCTTAATATGCAGCGTGTTAAGTGTTTATCCT

CGTCCAATTATCACGTGGAAAATGGACAACACACCTATCTCTGAAAACAACATGGAA

GAAACAGGGTCTTTGGATTCTTTTTCTATTAACAGCCCACTGAATATTACAGGATCA

AATTCATCTTATGAATGTACAATTGAAAATTCACTGCTGAAGCAAACATGGACAGGG

CGCTGGACGATGAAAGATGGCCTTCATAAAATGCAAAGTGAACACGTTTCACTCTCA

TGTCAACCTGTAAATGATTATTTTTCACCAAACCAAGACTTCAAAGTTACTTGGTCC

AGAATGAAAAGTGGGACTTTCTCTGTCCTGGCTTACTATCTGAGCTCCTCACAAAAT

ACAATTATCAATGAATCCCGATTCTCATGGAACAAAGAGCTGATAAACCAGAGTGAC

TTCTCTATGAATTTGATGGATCTTAATCTTTCAGACAGTGGGGAATATTTATGCAAT

ATTTCTTCGGATGAATATACTTTACTTACCATCCACACAGTGCATGTAGAACCGAGC

CAAGAAACAGCTTCCCATAACAAAGGCTTATGGATTTTGGTGCCCTCTGCGATTTTG

GCAGCTTTTCTGCTGATTTGGAGCGTAAAATGTTGCAGAGCCCAGCTAGAAGCCAGG

AGGAGCAGACACCCTGCTGATGGAGCCCAACAAGAAAGATGTTGTGTCCCTCCTGGT

GAGCGCTGTCCCAGTGCACCCGATAATGGCGAAGAAAATGTGCCTCTTTCAGGAAAA

GTATAGGAAATGAGAGAAGACTGTGACAACTCATGACCTGCATCCTTAATATCCAGT

GACTTCATCTCCCCTTTCTTCACCACAATTCCAGGCAATGGCCTGTCGGAGCAGACA

ATTCTACCACTGCAAAGAGTTGTAACCATTTTCTGGTATCACATTTATTTTTCAAGA

CATACTTTTCAAGACATCATTCACTGACCCACTACCTGCATTGAGTATAAATGCCTG

GATGTTAAGGATTCCAATTTAACTTTGAAAAGAACTGTCTCATTCATTTACATTTCT

GTTACAGTCAGCCCAGGAGGTTACAGTGAGCTCTCCACTAAGAATCTGGAAGAAATG

CATCACTAGGGGTTGATTCCCAATCTGATCAACTGATAATGGGTGAGAGAGCAGGTA

AGAGCCAAAGTCACCTTAGTGGAAAGGTTAAAAACCAGAGCCTGGAAACCAAGATGA

TTGATTTGACAAGGTATTTTAGTCTAGTTTTATATGAACGGTTGTATCAGGGTAACC

AACTCGATTTGGGATGAATCTTAGGGCACCAAAGACTAAGACAGTATCTTTAAGATT

GCTAGGGAAAAGGGCCCTATGTGTCAGGCCTCTGAGCCCAAGCCAAGCATCGCATCC

CCTGTGATTTGCACGTATACATCCAGATGGCCTAAAGTAACTGAAGATCCACAAAAG

AAGTAAAAATAGCCTTAACTGATGACATTCCACCATTGTGATTTGTTCCTGCCCCAC

CCTAACTGATCAATGTACTTTGTAATCTCCCCCACCCTTAAGAAGGTACTTTGTAAT

CTTCCCCACCCTTAAGAAGGTTCTTTGTAATTCTCCCCACCCTTGAGAATGTACTTT

GTGAGATCCACCCTGCCCACAAAACATTGCTCTTAACTTCACCGCCTAACCCAAAAC

CTATAAGAACTAATGATAATCCATCACCCTTCGCTGACTCTCTTTTCGGACTCAGCC

CACCTGCACCCAGGTGAAATAAACAGCTTTATTGCTCACACAAA (SEQ ID NO:

65)

>NP_009003.1 HERV-H LTR-associating protein 2 isoform a

precursor [Homo sapiens]

MKAQTALSFFLILITSLSGSQGIFPLAFFIYVPMNEQIVIGRLDEDIILPSSFERGS

EVVIHWKYQDSYKVHSYYKGSDHLESQDPRYANRTSLFYNEIQNGNASLFFRRVSLL

DEGIYTCYVGTAIQVITNKVVLKVGVFLTPVMKYEKRNTNSFLICSVLSVYPRPIIT

WKMDNTPISENNMEETGSLDSFSINSPLNITGSNSSYECTIENSLLKQTWTGRWTMK

DGLHKMQSEHVSLSCQPVNDYFSPNQDFKVTWSRMKSGTFSVLAYYLSSSQNTIINE

SRFSWNKELINQSDFSMNLMDLNLSDSGEYLCNISSDEYTLLTIHTVHVEPSQETAS

HNKGLWILVPSAILAAFLLIWSVKCCRAQLEARRSRHPADGAQQERCCVPPGERCPS

APDNGEENVPLSGKV (SEQ ID NO: 66

Mouse BTNL1
>NM_001111094.1 Mus musculus butyrophilin-like 1 (Btnl1),

mRNA

ACCCTTAAATAAGAGCTGAAGATGGCTGCAGCTTTCTCCTAGACTCCTCCAGGAGAA

ACTCTAAAGCCAGAGCCTGGGGGCAGCATTGTGTGTCCACCTTGCCACTGAGAACAT

CTACGGAAATTGGACACTCTGGCCCCAGCATCCACACGCTTGACTGTTGGCCACAGT

AACACAGGTGTGGATGGTCCCCAGAGCCAGGGTCCAGGAGTGCACTGAGGATCCCTG

GGGCTTCAAGGAACCCACAGCTCTGTCCAGACGGGAATTTTTTTCCTGAGAACTTTC

ACCTGTTGCCCTCCTATGGTGAACCTGGACTTGACCTTCCACTCTGATGATGAAGGG

CTCCCCCTCCGTCCCTCCAGCTGGTTGTCTCCTCCCTCTGCTCCTCCTGCTGTTTAC

CGGAGTCTCTGGAGAAGTGTCTTGGTTTTCTGTGAAGGGACCAGCTGAGCCCATCAC

TGTCCTGCTGGGGACTGAAGCCACCCTGCCCTGCCAGCTGTCTCCTGAACAGAGTGC

AGCTCGCATGCACATCCGATGGTACCGTGCCCAGCCCACCCCTGCTGTGCTGGTGTT

CCACAACGGACAGGAGCAGGGAGAGGTGCAGATGCCGGAATACAGGGGCAGGACCCA

GATGGTGAGACAAGCCATTGACATGGGAAGTGTGGCTCTGCAGATACAGCAGGTCCA

GGCCTCTGATGATGGCCTGTACCACTGTCAGTTTACAGATGGCTTCACCTCCCAAGA

GGTCTCCATGGAGCTTCGAGTCATAGGTTTAGGCTCTGCCCCTCTTGTTCACATGAC

AGGACCTGAGAATGATGGGATCCGAGTGTTGTGCTCCTCAAGTGGCTGGTTCCCAAA

ACCCAAAGTGCAATGGAGAGACACCTCCGGGAACATGCTACTGTCCTCCTCTGAGTT

GCAGACCCAAGACAGAGAAGGGCTCTTCCAGGTGGAAGTGTCTCTTTTGGTCACAGA

TAGAGCTATTGGCAATGTGATCTGCTCCATCCAAAATCCCATGTATGACCAGGAGAA

ATCGAAGGCCATCCTCCTCCCAGAGCCCTTCTTCCCCAAGACGTGTCCATGGAAAGT

AGCCCTGGTTTGTTCTGTCCTCATACTATTGGTCCTGCTCGGTGGGATCAGCCTTGG

AATCTGGAAAGAACATCAAGTCAAAAGGAGAGAAATTAAAAAATGGTCAAAGGAACA

TGAAGAAATGCTTCTGTTGAAGAAGGGGACAAAATCTGTACTGAAGATCAGAGATGA

CCTCCAGGCCGACCTAGATCGGAGGAAGGCGCTGTACAAAGAAGACTGGAAGAAGGC

CTTGCTGTACCCTGACTGGAGGAAGGAGCTGTTCCAGGAGGCTCCTGTGAGGATAAA

TTATGAAATGCCTGACCAGGACAAGACAGACTCAAGGACAGAAGAGAACAGAGGTGA

GGAGACTGTCAGCAGCTCACAAGTAGACCACAACCTCATCACACTCTCCCAGGAAGG

CTTCATGTTGGGAAGATACTACTGGGAGGTGGATGTCAAGGACACAGAGGAGTGGAC

ACTAGGAGTTTATGAGCTGTGCACTCAGGATGCATCACTTACAGACCCCTTGAGGAA

ATTCAGAGTCCTGGAAAAGAATGGAGATGGATACAGGGCTCTTGACTTCTGTTCCCA

AAACATTAATTCGGAAGAACCTCTGCAACTGAAGACACGTCCGCTGAAGATCGCCAT

CTTCTTGGATCAGGAAGACAATGACCTCTCTTTCTACAACATGACCGATGAGACACA

CATCTTTTCCTTTGCCCAGGTCCCTTTCTTGGGATCACCCTATCCTTACTTCACACG

TAATTCCATGGGGCTCTCTGCAACAGCACAGCCCTAAGTGATGTGCACAGGGAATTC

AATGGGTGGGTGCTGCAGCGTGCTACCCGTAAGGCCCTCTTAGGCAGGCACAGGGGG

CCTCTGACCAAGAGGCCTCTTAACCTGAGACTCCATGAGCCTCGGGGATCAGATCCT

GGACAAGATTCTCGGACCATCTGTGTCGTGCATGGTGTTATAGTTATTAATAGCCTT

CCTTCTTTTGACAAAAATGTGTTTAATCATTCCTAAGATAAATGAATCCATGGCTTT

CTGA (SEQ ID NO: 67)

>NP_001104564.1 butyrophilin-like protein 1 precursor

[Mus musculus]

MMKGSPSVPPAGCLLPLLLLLFTGVSGEVSWFSVKGPAEPITVLLGTEATLPCQLSP

EQSAARMHIRWYRAQPTPAVLVFHNGQEQGEVQMPEYRGRTQMVRQAIDMGSVALQI

QQVQASDDGLYHCQFTDGFTSQEVSMELRVIGLGSAPLVHMTGPENDGIRVLCSSSG

WFPKPKVQWRDTSGNMLLSSSELQTQDREGLFQVEVSLLVTDRAIGNVICSIQNPMY

DQEKSKAILLPEPFFPKTCPWKVALVCSVLILLVLLGGISLGIWKEHQVKRREIKKW

SKEHEEMLLLKKGTKSVLKIRDDLQADLDRRKALYKEDWKKALLYPDWRKELFQEAP

VRINYEMPDQDKTDSRTEENRGEETVSSSQVDHNLITLSQEGFMLGRYYWEVDVKDT

EEWTLGVYELCTQDASLTDPLRKFRVLEKNGDGYRALDFCSQNINSEEPLQLKTRPL

KIAIFLDQEDNDLSFYNMTDETHIFSFAQVPFLGSPYPYFTRNSMGLSATAQP

(SEQ ID NO: 68)

Human VSIG8
>NM_001013661.1 Homo sapiens V-set and immunoglobulin

domain containing 8 (VSIG8), mRNA

ACTCATTGCACCTTCCTGCCACCCCAGGCAGTGTCTGGGCCCTCAGCTCCCCCTCCC

TCCACCTACCCCCTCACACCCACCACTACGACCCCACGGGATACCCAGCCCAGACGG

AGGAAACACCGAGCCTAGAGACATGAGAGTTGGAGGAGCATTCCACCTTCTACTCGT

GTGCCTGAGCCCAGCACTGCTGTCTGCTGTGCGGATCAACGGGGATGGACAGGAGGT

CCTGTACCTGGCAGAAGGTGATAATGTGAGGCTGGGCTGCCCCTACGTCCTGGACCC

TGAGGACTATGGTCCCAATGGGCTGGACATCGAGTGGATGCAGGTCAACTCAGACCC

CGCCCACCACCGAGAGAACGTGTTCCTTAGTTACCAGGACAAGAGGATCAACCATGG

CAGCCTTCCCCATCTGCAGCAGAGGGTCCGCTTTGCAGCCTCAGACCCAAGCCAGTA

CGATGCCTCCATCAACCTCATGAACCTGCAGGTATCTGATACAGCCACTTATGAGTG

CCGGGTGAAGAAGACCACCATGGCCACCCGGAAGGTCATTGTCACTGTCCAAGCACG

ACCTGCAGTGCCCATGTGCTGGACAGAGGGCCACATGACATATGGCAACGATGTGGT

GCTGAAGTGCTATGCCAGTGGGGGCTCCCAGCCCCTCTCCTACAAGTGGGCCAAGAT

CAGTGGGCACCATTACCCCTATCGAGCTGGGTCTTACACCTCCCAGCACAGCTACCA

CTCAGAGCTGTCCTACCAGGAGTCCTTCCACAGCTCCATAAACCAAGGCCTGAACAA

TGGGGACCTGGTGTTGAAGGATATCTCCAGAGCAGATGATGGGCTGTATCAGTGCAC

AGTGGCCAACAACGTGGGCTACAGTGTTTGTGTGGTGGAGGTGAAGGTCTCAGACTC

CCGGCGTATAGGCGTGATCATCGGCATCGTCCTGGGCTCTCTGCTCGCGCTGGGCTG

CCTGGCCGTAGGCATCTGGGGGCTCGTCTGCTGCTGCTGCGGGGGCTCCGGGGCTGG

CGGCGCCCGCGGTGCCTTCGGCTACGGCAACGGCGGCGGGGTCGGCGGAGGGGCCTG

CGGCGACTTGGCTAGTGAGATCAGAGAGGACGCCGTGGCGCCCGGGTGCAAGGCCAG

CGGGCGCGGCAGCCGCGTCACCCACCTCCTGGGGTACCCGACGCAGAACGTCAGCCG

CTCCCTGCGCCGCAAGTACGCGCCTCCCCCCTGCGGCGGCCCCGAGGACGTGGCCCT

GGCGCCCTGCACCGCCGCCGCCGCCTGCGAAGCGGGCCCCTCCCCGGTCTACGTCAA

GGTCAAGAGCGCGGAGCCGGCTGACTGCGCCGAGGGGCCGGTGCAGTGCAAGAACGG

CCTCTTGGTGTGAGCGCGCGCGCCGGGCCGGGCTGCGCCCCAGCCAGGAGGAGGGCG

CGGGGCTCTCTGTCTGCAGCTGGGGACACGTCGGGGCTGGGGACGACCTCGCTCGCC

CCAGGCTGCCAGGCGGCTGGGGGTGAAGGCATTTCCCTAAGGAAATGCGTAGGGAGG

CAGAGCCTCCTCCCCAAAAGTGGGAAGGGGCGGGCGAGGGCGGAGGAAGGCGATCCT

GAGCCTTCTCCGCACCCCCGGGACCGAAGGCTTGGGGGAGAGGGAGGGAGGAGGAGG

CTGAGTGTCCTAGAGCGGCTGAGGCCGGAGGCCTGGTGTCCCCAGCCTAAGCAGAGG

GCCCCGGGGGCCGGGTGGGTGGGGGTCTGTCTGGACGAATTGTTCTGTGTGTGAGGT

CTGAGCTCTGAGGCAGCAGTGTTAGCACAATAAAGAAACATTGAGACGTGA (SEQ

ID NO: 69)

>NP_001013683.1 V-set and immunoglobulin domain-

containing protein 8 precursor [Homo sapiens]

MRVGGAFHLLLVCLSPALLSAVRINGDGQEVLYLAEGDNVRLGCPYVLDPEDYGPNG

LDIEWMQVNSDPAHHRENVFLSYQDKRINHGSLPHLQQRVRFAASDPSQYDASINLM

NLQVSDTATYECRVKKTTMATRKVIVTVQARPAVPMCWTEGHMTYGNDVVLKCYASG

GSQPLSYKWAKISGHHYPYRAGSYTSQHSYHSELSYQESFHSSINQGLNNGDLVLKD

ISRADDGLYQCTVANNVGYSVCVVEVKVSDSRRIGVIIGIVLGSLLALGCLAVGIWG

LVCCCCGGSGAGGARGAFGYGNGGGVGGGACGDLASEIREDAVAPGCKASGRGSRVT

HLLGYPTQNVSRSLRRKYAPPPCGGPEDVALAPCTAAAACEAGPSPVYVKVKSAEPA

DCAEGPVQCKNGLLV (SEQ ID NO: 70)

Mouse VSIG8
>NM_177723.4 Mus musculus V-set and immunoglobulin domain

containing 8 (Vsig8), transcript variant 1, mRNA

ACTCATTGCATCTTCCTGCCACCCCGGGCAGTGTCTGGGCCCTCCGCTCCCCCTCCC

TCCACCTGCCCCTTCCACCCACCACCACCAGCCCACTGGAGCCCAGCTCAGGCGGAG

GAAAGACCAAGCCTAGAGACATGGGAGTTCGAGGAGCACTCCATCTTCTACTTGTGT

GCCTGAGCCCAGCACTGTTGTCTGCTGTAAGGATCAACGGGGATGGCCAGGAGGTCA

TGTACCTGGCAGAAGGTGACAATGTGAGGCTAGGCTGTCCCTACCTCCTGGATCCTG

AGGATTTGGGTACCAACAGTCTGGACATTGAGTGGATGCAAGTCAACTCAGAGCCCT

CACACAGGGAGAATGTTTTTCTTACTTATCAAGACAAGAGGATAGGTCATGGCAACC

TCCCCCATCTGCAGCAGAGGGTCCGCTTTGCAGCCTCAGACCCCAGCCAGTACGATG

CCTCCATCAACCTCATGAACCTGCAGGTATCTGACACAGCAACCTATGAGTGCCGGG

TGAAGAAGACCACCATGGCCACCAGGAAGGTCATTGTCACTGTCCAAGCACGTCCTG

CGGTGCCCATGTGTTGGACGGAAGGCCACATGTCAAAGGGCAACGATGTGGTGCTGA

AGTGCTTTGCCAACGGAGGCTCTCAGCCCCTCTCCTACAAGTGGGCCAAGATCAGTG

GGCACAGTCACCCCTACCGAGCTGGGGCTTACCACTCACAGCACAGCTTCCACTCTG

AGCTTTCTTACCAAGAGTCATTCCACAGCACCATCAACCAAGGCCTGGGCAACGGAG

ACCTGCTGTTGAAGGGCATCAACGCAGACGACGATGGGCTGTATCAGTGCACAGTGG

CCAACCATGTGGGCTACAGCGTCTGTGTGGTAGAGGTGAAAGTCTCAGACTCCCAGC

GAGTAGGCATGATCGTTGGAGCAGTGCTGGGCTCTTTGCTCATGCTGGCCTGCCTGG

CACTAGGCATCTGGGGGCTCATCTGCTGCTGCTGCGGAGGCGGCGGGGCCGGTGGTG

CCCGAGGTGCCTTCGGCTACGGGGTCGGCGGCGGGGTCGGCGGAGGGGCCTGCGGCG

ACTTGGCTAGTGAGATCAGAGTGGACGCCGAGGCGCCCGGGTGTAAGGCCAGCGGGC

GCGGCAGCCGCGTCACCCACCTCCTGGGGTACCCGACGCAGAACGTCAGCCGCTCCC

TGCGCCGCAAGTACGCGCCTCCGCCCTGCGGCGGCCCCGAGGACGTGGCCCTAGTGC

CCCGCACCGCCTCCGCCTCCTGCGAAGCGGGTCCCTCCCCCGTCTACATCAAGGTCA

AGAGCGCGGAGCCGGCCGACTGCGCCGACTGTGCCCAGGTCGAGCAGCGCTCGTGCA

AGGACGGCCTCTTAGTGTGAGCGCACAGCACCGGGCTGCGCCCCGGCTGGGAGGTGG

TTCGGGGGCTCTCTGCCCGCAGCTGGGGACAGGTTCGGGCCAGCAGACCTGGCTCTC

TCATTGGCCACCTAGCGGTGGTAAGGAAATTTCCCTCTGAGAAGCCAAGCCGGGCAG

ACCCTCCTCCCCTGTAGTGGGAGGAGAGGCGGGGGAGACAGAAAACAGTTCAGAGCT

CTCCCTCACCCCTGGTTTCCAGGGAGAGGAAGGGAGAGGAGAGCTGTCGGTATCCCA

GAACCGCAGAGGTACAACCCAGATGTCCCCAGCCAAGGCGAGGGCCCCCCAGCCCTG

GGTAGGTGGATGTCAGGGCTGAATTGCTCTGTGTGTGAGATCTGAGCTCCAAGGCAA

CAGTGTTAGCACAATAAAGAAACTTAAAGACTGAAAAAAAAAAAAAA (SEQ ID

NO: 71)

>NP_808391.2 V-set and immunoglobulin domain-containing

protein 8 precursor [Mus musculus]

MGVRGALHLLLVCLSPALLSAVRINGDGQEVMYLAEGDNVRLGCPYLLDPEDLGTNS

LDIEWMQVNSEPSHRENVFLTYQDKRIGHGNLPHLQQRVRFAASDPSQYDASINLMN

LQVSDTATYECRVKKTTMATRKVIVTVQARPAVPMCWTEGHMSKGNDVVLKCFANGG

SQPLSYKWAKISGHSHPYRAGAYHSQHSFHSELSYQESFHSTINQGLGNGDLLLKGI

NADDDGLYQCTVANHVGYSVCVVEVKVSDSQRVGMIVGAVLGSLLMLACLALGIWGL

ICCCCGGGGAGGARGAFGYGVGGGVGGGACGDLASEIRVDAEAPGCKASGRGSRVTH

LLGYPTQNVSRSLRRKYAPPPCGGPEDVALVPRTASASCEAGPSPVYIKVKSAEPAD

CADCAQVEQRSCKDGLLV (SEQ ID NO: 72)

Human VSIG3
>NM_001015887.3 Homo sapiens immunoglobulin superfamily

(IGSF11)
member 11 (IGSF11), transcript variant 2, mRNA

AGTCCTGGGGCAGGGCTGGGTGGCACGGCTGGCGAGCCCGGAACGCCTCTGGTCACA

GCTCAGCGTCCGCGGAGCCGGGCGGCGCTGCAGCTGCACTTGGCTCGTCTGTGGGTC

TGACAGTCCCAGCTCTGCGCGGGGAACAGCGGCCCGGCGCTGGGTGTGGGAGGACCA

GGCTGCCCCAAGAGCGCGGAGACTCACGCCCGCTCCTCTCCTGTTGCGACCGGGAGC

CGGGTAGGAGGCAGGCGCGCTCCCTGCGGCCCCGGGATGACTTCTCAGCGTTCCCCT

CTGGCGCCTTTGCTGCTCCTCTCTCTGCACGGTGTTGCAGCATCCCTGGAAGTGTCA

GAGAGCCCTGGGAGTATCCAGGTGGCCCGGGGTCAGCCAGCAGTCCTGCCCTGCACT

TTCACTACCAGCGCTGCCCTCATTAACCTCAATGTCATTTGGATGGTCACTCCTCTC

TCCAATGCCAACCAACCTGAACAGGTCATCCTGTATCAGGGTGGACAGATGTTTGAT

GGTGCCCCCCGGTTCCACGGTAGGGTAGGATTTACAGGCACCATGCCAGCTACCAAT

GTCTCTATCTTCATTAATAACACTCAGTTATCAGACACTGGCACCTACCAGTGCCTG

GTCAACAACCTTCCAGACATAGGGGGCAGGAACATTGGGGTCACCGGTCTCACAGTG

TTAGTTCCCCCTTCTGCCCCACACTGCCAAATCCAAGGATCCCAGGATATTGGCAGC

GATGTCATCCTGCTCTGTAGCTCAGAGGAAGGCATTCCTCGACCAACTTACCTTTGG

GAGAAGTTAGACAATACCCTCAAACTACCTCCAACAGCTACTCAGGACCAGGTCCAG

GGAACAGTCACCATCCGGAACATCAGTGCCCTGTCTTCAGGTTTGTACCAGTGCGTG

GCTTCTAATGCTATTGGAACCAGCACCTGTCTTCTGGATCTCCAGGTTATTTCACCC

CAGCCCAGGAACATTGGACTAATAGCTGGAGCCATTGGCACTGGTGCAGTTATTATC

ATTTTTTGCATTGCACTAATTTTAGGGGCATTCTTTTACTGGAGAAGCAAAAATAAA

GAGGAGGAAGAAGAAGAAATTCCTAATGAAATAAGAGAGGATGATCTTCCACCCAAG

TGTTCTTCTGCCAAAGCATTTCACACTGAGATTTCCTCCTCGGACAACAACACACTA

ACCTCTTCCAATGCCTACAACAGTCGATACTGGAGCAACAATCCAAAAGTTCATAGA

AACACAGAGTCAGTCAGCCACTTCAGTGACTTGGGCCAATCTTTCTCTTTCCACTCA

GGCAATGCCAACATACCATCCATTTATGCTAATGGGACCCATCTGGTCCCGGGTCAA

CATAAGACTCTGGTAGTGACAGCCAACAGAGGGTCATCACCACAGGTGATGTCCAGG

AGCAATGGCTCAGTCAGTAGGAAGCCTCGGCCTCCACACACTCATTCCTACACCATC

AGCCACGCAACACTGGAACGAATTGGTGCAGTACCTGTCATGGTACCAGCCCAGAGT

CGGGCCGGGTCCTTGGTATAGGACATGAGGAAATGTTGTGTTCAGAAATGAATAAAT

GGAATGCCCTCATACAAGGGGGAGGGTGGGGTGGGGAGTGCTGGGAAAGAAACACTT

CCTTATAATTATATTAGTAAAATGCACAAAGAAGAAGGCAGTGCTGTTACTTGGCCA

CTAAGATGTGTAAAATGGACTGAAATGCTCCATCATGAAGACTTGCTTCCCCACCAA

AGATGTCCTGGGATTCTGCTGGATCTCAAAGATGTGCCAAGCCAAGGAAAAAGATAC

AAGAGCAGAATAGTACTTAAAATCCAAACTGCCGCCCAGATGGGCTTGTTCTTCATG

CCTAACTTAATAATTTTTAAGAGATTAAAGTGCCAGATGGAGTTTAAATATTGAAAT

TATTTTAAAAGGTAGGTGTCTTTAAGAAAATAACAAGCAACCCTGTGATATGTTCCG

TCTCTCCCAATTCCCTCGTTATATAGAGGGCTTAATGGTATAAATGGTTAATATTGG

TCCCAACAGGGCTGACTCTTCTATCATATAATCAAAACTTTTTACATGAGCAAAATT

CAGTAAGAAATGGGGGAAGACAAAGGAAACGTCTTTGAGAAGCCCCTTCATATTTAT

TTATTTATCTCTTCCTGAACCATGAATTTCATATGTGGAATATTGCTATATTGACAG

ATTCTTGCCTGTCTGTGTTATTCTAGGATCTGTTACAGGTCCATGGCAATTACTGTT

TATTTTTTCCTGGAAAAATATTTTTTTATAAAAGGCTTTTTTTTTTTTTTAAATACA

TGAGAGGCATTGGGCTAAGAAAGAAAAGACTGTTGTATAATACCTTGTTCAATGGTT

GTATTTAGTGAGCTCATAGAGGTCCATCATATCATGACCGAGCTAGGTTGTGTGGGC

AGGAAGGTAGGGCTAAGGGGTTGTAGCCTTGCTGGGCAGCCTCTCAGAGCAAGGTTG

TTCAGATCTCCCTTGCTATTACAGTAGGTTACTATTAATGAGGGCAGCACCTGATGC

CTTTTGTACTGAGGTATGTAACTTTCTCCTTATTTGACAAGTAGAAGTTAACTTACT

TGTCAGGGAGGGCAGACGTTTTTTTGTTCTGTTTCGTTTTTCAAAATAATGCTTTTT

GCAAAAGAGGTAAGACTGAGACTAAAGGTGTTATCTTCTGGTGTGCTCCTGGAAGTG

TCTACCCTACATTTGTGTCAGCTCAGGGTTGCAGTGTTGCCCAGATGCATTTTACAT

CACTGTAAAGAGATTACTTTTGTGGTTACTACCTGGCTTGGCTGGCCTTGCGGTTCA

CCAGATTAATTTACAAACTCCCCCACTTTATTTTGTGCTATGTAGATCTGGCCATAC

TTGCATTAGTGACTGTCTTGCCTTAACCACACTTAAGCAACCCACAAATTTCTTCTC

AGATTTGTTTCCTAGATTACTTATGATACTCATCCCATGTCTCAATAAGAGTGTCTT

TTCTTTCTGGATGTGTTCTCTTACTCCCTCTTACCACCATACTTTTTGCTCTCTTCT

CCTGCAAGCGTAGTCTTCACAGGGAGTGGCTTCCTGACATTTTTTTCAGTTATGTGA

ATGAATGGAAACCAACAGCTGCTGCAAACACTGTTTTTCCAAGAAGGCTACACTCAG

AACCTAACCATTGCCAACCATTTCAGTATTGATAAAAAGCTGAATTTACTTTAGCAT

TACTTATTTTTTTTTCCATTTGATGGTTCTTACTTTGTAAAAATTTAAATAAATGAA

TGTCTATACTTTTTATAAAGAAAAGTGAAAATACCATGACACTGAAAAGATGATGCT

ATCAGATGCTGTTTAGAAAGCATTTATCTTGCATTTCTTTATTCTTTCTAATTATCT

AAAATTCAATAAAATTTTATTCATATAAAATAAGTTGTCATTAATTATCAATACTAA

CGAGTATGTCATTTTAAAACTTAGTATTCTCTTTAATGTTACAAGA (SEQ ID

NO: 73)

>NP_001015887.1 immunoglobulin superfamily member 11

isoform b precursor [Homo sapiens]

MTSQRSPLAPLLLLSLHGVAASLEVSESPGSIQVARGQPAVLPCTFTTSAALINLNV

IWMVTPLSNANQPEQVILYQGGQMFDGAPRFHGRVGFTGTMPATNVSIFINNTQLSD

TGTYQCLVNNLPDIGGRNIGVTGLTVLVPPSAPHCQIQGSQDIGSDVILLCSSEEGI

PRPTYLWEKLDNTLKLPPTATQDQVQGTVTIRNISALSSGLYQCVASNAIGTSTCLL

DLQVISPQPRNIGLIAGAIGTGAVIIIFCIALILGAFFYWRSKNKEEEEEEIPNEIR

EDDLPPKCSSAKAFHTEISSSDNNTLTSSNAYNSRYWSNNPKVHRNTESVSHFSDLG

QSFSFHSGNANIPSIYANGTHLVPGQHKTLVVTANRGSSPQVMSRSNGSVSRKPRPP

HTHSYTISHATLERIGAVPVMVPAQSRAGSLV (SEQ ID NO: 74)

Mouse VSIG3
>NM_170599.2 Mus musculus immunoglobulin superfamily,

(IGSF11)
member 11 (Igsf11), mRNA

CGGCTGGTGGTGGCCGCGGCGGCCGGCGAGCCCGGGACGCCCGAGCCTGCCCCGAGC

CTCGGCGGAGCGGAGTGGCCTCGGCGCTCCCGTGTCCCGCTTGGTCCCACGCTGCAC

CCCGCCGCCCAGGAGCCCGGCGGACGGCGGCTCCCCCGGCGGCTCCGGCATGACTCG

GCGGCGCTCCGCTCCGGCGTCCTGGCTGCTCGTGTCGCTGCTCGGTGTCGCAACATC

CCTGGAAGTGTCCGAGAGCCCAGGCAGTGTCCAGGTGGCCCGGGGCCAGACAGCAGT

CCTGCCCTGCGCCTTCTCCACCAGTGCTGCCCTCCTGAACCTCAATGTCATTTGGAT

GGTCATTCCCCTCTCCAATGCAAACCAGCCCGAACAGGTCATTCTTTATCAGGGTGG

ACAAATGTTTGACGGCGCCCTCCGGTTCCACGGGAGGGTAGGATTTACCGGCACCAT

GCCTGCTACCAATGTCTCGATCTTCATCAATAACACACAGCTGTCAGATACGGGCAC

GTACCAGTGCTTGGTGAATAACCTTCCAGACAGAGGGGGCAGAAACATCGGGGTCAC

TGGCCTCACAGTGTTAGTCCCCCCTTCTGCTCCACAATGCCAAATCCAAGGATCCCA

GGACCTCGGCAGTGACGTCATCCTTCTGTGTAGTTCAGAGGAAGGCATCCCTCGGCC

CACGTACCTTTGGGAGAAGTTAGATAATACGCTCAAGCTACCTCCAACAGCCACTCA

GGACCAGGTCCAGGGAACAGTCACCATCCGGAATATCAGTGCCCTCTCTTCCGGTCT

GTACCAGTGTGTGGCTTCTAATGCCATCGGGACCAGCACCTGTCTGCTGGACCTCCA

GGTTATCTCACCCCAGCCCCGGAGCGTTGGAGTAATAGCCGGAGCGGTTGGCACCGG

TGCTGTTCTTATCGTCATCTGCCTTGCACTAATTTCAGGGGCGTTCTTTTACTGGAG

AAGCAAAAACAAAGAGGAGGAGGAGGAAGAAATTCCTAATGAAATCAGAGAGGATGA

TCTTCCCCCTAAATGCTCTTCTGCCAAAGCCTTCCACACGGAGATATCCTCCTCAGA

AAATAACACGCTGACCTCTTCCAATACCTACAACAGTCGATACTGGAACAACAATCC

AAAACCCCATAGAAACACAGAGTCTTTCAACCACTTCAGTGACTTACGCCAGTCTTT

CTCTGGCAATGCAGTTATCCCATCAATCTATGCAAATGGGAACCATCTGGTTTTGGG

TCCACATAAGACTCTGGTAGTTACAGCCAACAGAGGGTCATCACCTCAGGTCTTGCC

CAGGAACAATGGTTCAGTCAGCAGGAAGCCTTGGCCTCAACACACTCATTCCTACAC

AGTAAGCCAAATGACCCTGGAGCGCATCGGTGCAGTGCCTGTCATGGTGCCTGCCCA

GAGTCGAGCAGGGTCCCTGGTATAGGATGACTGAGGAAACCATGTTCAGAAGAGAAT

AAATGGACCGCCTTCAGGCAAGGGGGGAGCACTGCCTTCAGGCAAGGGGGGAGCACT

GCCTTCAGGCAAGAGGGAGAGTGGGATGGGTGAGTGCTGAAAAATAAACTTTTGTTA

CGATTCCATTAGCAAAAAGCACAAAGAGGAGGCGTGTGTGAAGTGGCCTGGGGTTGT

TCCATAATGAAGACTCAAGAAGACTGTTTCCCCACCACAGATGTCCTGAGATTCAGT

TAAAACGAAACATGCTGCATCTCCAGAGATGTGCCAAGCCAAGGAGAATGCTAGAAG

CAGAGTAAAGCTTACCCCCCAAACTGTGGTCCAGCTGGACCCCTTCTTTAATTCTTG

CCTAACTTAATTATTTTCAGGACCCTTCAAGTGCCAGGTGGAATTTACATAATGAAA

TTATTTTTTAAAAATAGGTGTCCTTAGGGAGAGAAAACAGGAGCAAGCTCATGGTCT

GGCCTAGTCTCCCTCTCCCACTCCTTCTGATGACACTAGCAATGCATTCCATCTGAC

CTGACTTTATCATAGAGGCAAAATTGTTCAGAACACTGGCTGGAGATGGGGAGAAAT

AAGGAAACTTCTTGTGAACACCCTACACACACACACACACACACACACACACACACA

CACACACACACACACACACACACACACACATTTATTTACCTCCTCCTGAACCATGAA

TCGTATTGGTGATTTTGCTATATTGACAGATTCTCATCTGTTACACTCTAGGATCTC

TCACAGGTCTGTGGCAATTACTGTTCATGATTTCCTGAAAAAATATTTTTTTAAAAG

AAAACTATTTTTTTTAAATACTAGAGAGACAGTGGACTAGGAAAGCGAGAACTTGCC

GCCTTGTCTAGTGACTGTATTCAATGACTGAACAGAGGCCCCCCCCACCATACAAGA

GTTTTAGGTGATTGAGTGGGTGGAACCAGCTGGAGCCAGGTGGGAGGGGCCTTTACA

TTGCCAGCAGGGCCCCAAAGAATTGAGATTGTGTATGGCAACCGTTAATGAGGACAG

CGCCTGATGCCTTTTGTACCGAGGAAGATAATTGCCTCTTGTTTGACAAGTAGAGTT

TAGTAGGTTATTACAAAAAGGGCAAGAGTTGTTTTGGTTTTGTTTCTTTCAAAATAA

TTTTTTTTCAAAAGAATAACAAGGGTTAGGCAAATGGGGGACCTTCCTGTGTGCTCT

TGGGGGTCTGCTCAGCATCTGGAAATTTGGGTGTGCGATTTTCCCTGAACACATTGC

ATACCAGTGTAAAAAGACTCTGCCTCCCCCCTTTTTGGCTTTTTTACTGGGCTTGGC

TGGCCTTGCAGTTTACCAGATTCATTTACAGACTCTCTGCTCTGTATGGCGCCGCCT

GCCATGTCTGTCTTGGTGACTATCCTGCCTTAATCACTTTGCTTTAGGGCAACTCAT

GGTGATCTCTTCCAAGATCTGTTTTTAAATTGTTTGGACTACTTGAGCCACAACTCT

CAGAGGACATTCCTTTTTTTTTTTTTTTTTTTTTCTCCTTTCTTCCATTGCTTTGTC

CCTCTTCCCCTGTGCTTCCTGCCTTCTTTCCCTGTCCCATGGGCACAGTCCTCACAG

GGAGTGGCCTCCTCTCTCCAGTGATGTAAGTGAATGGAAGCCATCACTGGCTGCACA

TACCTTTTTCAAAAGGGACACTCGGGAAGTCACTGCTGTGACCGTTTCGATGTTGAT

AAGAAGGTGAATTTACTGTAGTGTTACCACCTTCTCCCCACTTGATGGTTCTTGACT

TTGTAAAAATTTAAATAAATGAATGTCTATACTTTTTAAGGAAAAGAGAAAATACCA

TGTCACAGAAAAGGTGAAACTATTAGATGCTGTTTAGAAAGCATTTATCTTGCATTT

CTTTATTCTTTCTAATTACCTAAAATTCAATAAAAGTTTATTCATATAAAAAAAAAA

AAAAAAAAAA (SEQ ID NO: 75)

>NP_733548.2 immunoglobulin superfamily member 11

precursor [Mus musculus]

MTRRRSAPASWLLVSLLGVATSLEVSESPGSVQVARGQTAVLPCAFSTSAALLNLNV

IWMVIPLSNANQPEQVILYQGGQMFDGALRFHGRVGFTGTMPATNVSIFINNTQLSD

TGTYQCLVNNLPDRGGRNIGVTGLTVLVPPSAPQCQIQGSQDLGSDVILLCSSEEGI

PRPTYLWEKLDNTLKLPPTATQDQVQGTVTIRNISALSSGLYQCVASNAIGTSTCLL

DLQVISPQPRSVGVIAGAVGTGAVLIVICLALISGAFFYWRSKNKEEEEEEIPNEIR

EDDLPPKCSSAKAFHTEISSSENNTLTSSNTYNSRYWNNNPKPHRNTESFNHFSDLR

QSFSGNAVIPSIYANGNHLVLGPHKTLVVTANRGSSPQVLPRNNGSVSRKPWPQHTH

SYTVSQMTLERIGAVPVMVPAQSRAGSLV (SEQ ID NO: 76)

Human VSIG4
>NM_007268.3 Homo sapiens V-set and immunoglobulin domain

containing 4 (VSIG4), transcript variant 1, mRNA

ACAGACGCTGGCGGCCACCAGAAGTTTGAGCCTCTTTGGTAGCAGGAGGCTGGAAGA

AAGGACAGAAGTAGCTCTGGCTGTGATGGGGATCTTACTGGGCCTGCTACTCCTGGG

GCACCTAACAGTGGACACTTATGGCCGTCCCATCCTGGAAGTGCCAGAGAGTGTAAC

AGGACCTTGGAAAGGGGATGTGAATCTTCCCTGCACCTATGACCCCCTGCAAGGCTA

CACCCAAGTCTTGGTGAAGTGGCTGGTACAACGTGGCTCAGACCCTGTCACCATCTT

TCTACGTGACTCTTCTGGAGACCATATCCAGCAGGCAAAGTACCAGGGCCGCCTGCA

TGTGAGCCACAAGGTTCCAGGAGATGTATCCCTCCAATTGAGCACCCTGGAGATGGA

TGACCGGAGCCACTACACGTGTGAAGTCACCTGGCAGACTCCTGATGGCAACCAAGT

CGTGAGAGATAAGATTACTGAGCTCCGTGTCCAGAAACTCTCTGTCTCCAAGCCCAC

AGTGACAACTGGCAGCGGTTATGGCTTCACGGTGCCCCAGGGAATGAGGATTAGCCT

TCAATGCCAGGCTCGGGGTTCTCCTCCCATCAGTTATATTTGGTATAAGCAACAGAC

TAATAACCAGGAACCCATCAAAGTAGCAACCCTAAGTACCTTACTCTTCAAGCCTGC

GGTGATAGCCGACTCAGGCTCCTATTTCTGCACTGCCAAGGGCCAGGTTGGCTCTGA

GCAGCACAGCGACATTGTGAAGTTTGTGGTCAAAGACTCCTCAAAGCTACTCAAGAC

CAAGACTGAGGCACCTACAACCATGACATACCCCTTGAAAGCAACATCTACAGTGAA

GCAGTCCTGGGACTGGACCACTGACATGGATGGCTACCTTGGAGAGACCAGTGCTGG

GCCAGGAAAGAGCCTGCCTGTCTTTGCCATCATCCTCATCATCTCCTTGTGCTGTAT

GGTGGTTTTTACCATGGCCTATATCATGCTCTGTCGGAAGACATCCCAACAAGAGCA

TGTCTACGAAGCAGCCAGGGCACATGCCAGAGAGGCCAACGACTCTGGAGAAACCAT

GAGGGTGGCCATCTTCGCAAGTGGCTGCTCCAGTGATGAGCCAACTTCCCAGAATCT

GGGCAACAACTACTCTGATGAGCCCTGCATAGGACAGGAGTACCAGATCATCGCCCA

GATCAATGGCAACTACGCCCGCCTGCTGGACACAGTTCCTCTGGATTATGAGTTTCT

GGCCACTGAGGGCAAAAGTGTCTGTTAAAAATGCCCCATTAGGCCAGGATCTGCTGA

CATAATTGCCTAGTCAGTCCTTGCCTTCTGCATGGCCTTCTTCCCTGCTACCTCTCT

TCCTGGATAGCCCAAAGTGTCCGCCTACCAACACTGGAGCCGCTGGGAGTCACTGGC

TTTGCCCTGGAATTTGCCAGATGCATCTCAAGTAAGCCAGCTGCTGGATTTGGCTCT

GGGCCCTTCTAGTATCTCTGCCGGGGGCTTCTGGTACTCCTCTCTAAATACCAGAGG

GAAGATGCCCATAGCACTAGGACTTGGTCATCATGCCTACAGACACTATTCAACTTT

GGCATCTTGCCACCAGAAGACCCGAGGGAGGCTCAGCTCTGCCAGCTCAGAGGACCA

GCTATATCCAGGATCATTTCTCTTTCTTCAGGGCCAGACAGCTTTTAATTGAAATTG

TTATTTCACAGGCCAGGGTTCAGTTCTGCTCCTCCACTATAAGTCTAATGTTCTGAC

TCTCTCCTGGTGCTCAATAAATATCTAATCATAACAGCAA (SEQ ID NO: 77)

>NP_009199.1 V-set and immunoglobulin domain-containing

protein 4 isoform 1 precursor [Homo sapiens]

MGILLGLLLLGHLTVDTYGRPILEVPESVTGPWKGDVNLPCTYDPLQGYTQVLVKWL

VQRGSDPVTIFLRDSSGDHIQQAKYQGRLHVSHKVPGDVSLQLSTLEMDDRSHYTCE

VTWQTPDGNQVVRDKITELRVQKLSVSKPTVTTGSGYGFTVPQGMRISLQCQARGSP

PISYIWYKQQTNNQEPIKVATLSTLLFKPAVIADSGSYFCTAKGQVGSEQHSDIVKF

VVKDSSKLLKTKTEAPTTMTYPLKATSTVKQSWDWTTDMDGYLGETSAGPGKSLPVF

AIILIISLCCMVVFTMAYIMLCRKTSQQEHVYEAARAHAREANDSGETMRVAIFASG

CSSDEPTSQNLGNNYSDEPCIGQEYQIIAQINGNYARLLDTVPLDYEFLATEGKSVC

(SEQ ID NO: 78)

Mouse VSIG4
>NM_177789.5 Mus musculus V-set and immunoglobulin domain

containing 4 (Vsig4), mRNA

AGCTACCAGCACTTCCAGGTTCTTCAGCAGCAAGAGGATGGAAGGATGAATAGAAGT

AGCTTCAAATAGGATGGAGATCTCATCAGGCTTGCTGTTCCTGGGCCACCTAATAGT

GCTCACCTATGGCCACCCCACCCTAAAAACACCTGAGAGTGTGACAGGGACCTGGAA

AGGAGATGTGAAGATTCAGTGCATCTATGATCCCCTGAGAGGCTACAGGCAAGTTTT

GGTGAAATGGCTGGTAAGACACGGCTCTGACTCCGTCACCATCTTCCTACGTGACTC

CACTGGAGACCATATCCAGCAGGCAAAGTACAGAGGCCGCCTGAAAGTGAGCCACAA

AGTTCCAGGAGATGTGTCCCTCCAAATAAATACCCTGCAGATGGATGACAGGAATCA

CTATACATGTGAGGTCACCTGGCAGACTCCTGATGGAAACCAAGTAATAAGAGATAA

GATCATTGAGCTCCGTGTTCGGAAATATAATCCACCTAGAATCAATACTGAAGCACC

TACAACCCTGCACTCCTCTTTGGAAGCAACAACTATAATGAGTTCAACCTCTGACTT

GACCACTAATGGGACTGGAAAACTTGAGGAGACCATTGCTGGTTCAGGGAGGAACCT

GCCAATCTTTGCCATAATCTTCATCATCTCCCTTTGCTGCATAGTAGCTGTCACCAT

ACCTTATATCTTGTTCCGCTGCAGGACATTCCAACAAGAGTATGTCTATGGAGTGAG

CAGGGTGTTTGCCAGGAAGACAAGCAACTCTGAAGAAACCACAAGGGTGACTACCAT

CGCAACTGATGAACCAGATTCCCAGGCTCTGATTAGTGACTACTCTGATGATCCTTG

CCTCAGCCAGGAGTACCAAATAACCATCAGATCAACAATGTCTATTCCTGCCTGCTG

AACACAGTTTCCAGAAACTAAGAAGTTCTTGCTACTGAAGAAAATAACATCTGCTAA

AATGCCCCTACTAAGTCAAGGTCTACTGGCGTAATTACCTGTTACTTATTTACTACT

TGCCTTCAACATAGCTTTCTCCCTGGCTTCCTTTCTTCTTAGACAACCTAAAGTATC

TATCTAGTCTGCCAATTCTGGGGCCATTGAGAAATCCTGGGTTTGGCTAAGAATATA

CTACATGCACCTCAAGAAATCTAGCTTCTGGGCTTCACCCAGAACAATTTTCTTCCT

AGGGCCTTCACAACTCTTCTCCAAACAGCAGAGAAATTCCATAGCAGTAGAGGTTCT

TTATCATGCCTCCAGACAGCGTGAGTCTCAGTCCTACAAACTCAGACAAGCACATGG

GTCTAGGATTACTCCTCTTTCTCTAGGGCCAGATGACTTTTAATTGATATTACTATT

GCTACATTATGAATCTAATGCACATGTATTCTTTTGTTGTTAATAAATGTTTAATCA

TGACATCAA (SEQ ID NO: 79)

>NP_808457.1 V-set and immunoglobulin domain-containing

protein 4 precursor [Mus musculus]

MEISSGLLFLGHLIVLTYGHPTLKTPESVTGTWKGDVKIQCIYDPLRGYRQVLVKWL

VRHGSDSVTIFLRDSTGDHIQQAKYRGRLKVSHKVPGDVSLQINTLQMDDRNHYTCE

VTWQTPDGNQVIRDKIIELRVRKYNPPRINTEAPTTLHSSLEATTIMSSTSDLTTNG

TGKLEETIAGSGRNLPIFAIIFIISLCCIVAVTIPYILFRCRTFQQEYVYGVSRVFA

RKTSNSEETTRVTTIATDEPDSQALISDYSDDPCLSQEYQITIRSTMSIPAC (SEQ

ID NO: 80)

Human Tim-3
>NM_032782.5 Homo sapiens hepatitis A virus cellular

(HAVCR2)
receptor 2 (HAVCR2), mRNA

ATTTGGAGAGTTAAAACTGTGCCTAACAGAGGTGTCCTCTGACTTTTCTTCTGCAAG

CTCCATGTTTTCACATCTTCCCTTTGACTGTGTCCTGCTGCTGCTGCTGCTACTACT

TACAAGGTCCTCAGAAGTGGAATACAGAGCGGAGGTCGGTCAGAATGCCTATCTGCC

CTGCTTCTACACCCCAGCCGCCCCAGGGAACCTCGTGCCCGTCTGCTGGGGCAAAGG

AGCCTGTCCTGTGTTTGAATGTGGCAACGTGGTGCTCAGGACTGATGAAAGGGATGT

GAATTATTGGACATCCAGATACTGGCTAAATGGGGATTTCCGCAAAGGAGATGTGTC

CCTGACCATAGAGAATGTGACTCTAGCAGACAGTGGGATCTACTGCTGCCGGATCCA

AATCCCAGGCATAATGAATGATGAAAAATTTAACCTGAAGTTGGTCATCAAACCAGC

CAAGGTCACCCCTGCACCGACTCGGCAGAGAGACTTCACTGCAGCCTTTCCAAGGAT

GCTTACCACCAGGGGACATGGCCCAGCAGAGACACAGACACTGGGGAGCCTCCCTGA

TATAAATCTAACACAAATATCCACATTGGCCAATGAGTTACGGGACTCTAGATTGGC

CAATGACTTACGGGACTCTGGAGCAACCATCAGAATAGGCATCTACATCGGAGCAGG

GATCTGTGCTGGGCTGGCTCTGGCTCTTATCTTCGGCGCTTTAATTTTCAAATGGTA

TTCTCATAGCAAAGAGAAGATACAGAATTTAAGCCTCATCTCTTTGGCCAACCTCCC

TCCCTCAGGATTGGCAAATGCAGTAGCAGAGGGAATTCGCTCAGAAGAAAACATCTA

TACCATTGAAGAGAACGTATATGAAGTGGAGGAGCCCAATGAGTATTATTGCTATGT

CAGCAGCAGGCAGCAACCCTCACAACCTTTGGGTTGTCGCTTTGCAATGCCATAGAT

CCAACCACCTTATTTTTGAGCTTGGTGTTTTGTCTTTTTCAGAAACTATGAGCTGTG

TCACCTGACTGGTTTTGGAGGTTCTGTCCACTGCTATGGAGCAGAGTTTTCCCATTT

TCAGAAGATAATGACTCACATGGGAATTGAACTGGGACCTGCACTGAACTTAAACAG

GCATGTCATTGCCTCTGTATTTAAGCCAACAGAGTTACCCAACCCAGAGACTGTTAA

TCATGGATGTTAGAGCTCAAACGGGCTTTTATATACACTAGGAATTCTTGACGTGGG

GTCTCTGGAGCTCCAGGAAATTCGGGCACATCATATGTCCATGAAACTTCAGATAAA

CTAGGGAAAACTGGGTGCTGAGGTGAAAGCATAACTTTTTTGGCACAGAAAGTCTAA

AGGGGCCACTGATTTTCAAAGAGATCTGTGATCCCTTTTTGTTTTTTGTTTTTGAGA

TGGAGTCTTGCTCTGTTGCCCAGGCTGGAGTGCAATGGCACAATCTCGGCTCACTGC

AAGCTCCGCCTCCTGGGTTCAAGCGATTCTCCTGCCTCAGCCTCCTGAGTGGCTGGG

ATTACAGGCATGCACCACCATGCCCAGCTAATTTGTTGTATTTTTAGTAGAGACAGG

GTTTCACCATGTTGGCCAGTGTGGTCTCAAACTCCTGACCTCATGATTTGCCTGCCT

CGGCCTCCCAAAGCACTGGGATTACAGGCGTGAGCCACCACATCCAGCCAGTGATCC

TTAAAAGATTAAGAGATGACTGGACCAGGTCTACCTTGATCTTGAAGATTCCCTTGG

AATGTTGAGATTTAGGCTTATTTGAGCACTGCCTGCCCAACTGTCAGTGCCAGTGCA

TAGCCCTTCTTTTGTCTCCCTTATGAAGACTGCCCTGCAGGGCTGAGATGTGGCAGG

AGCTCCCAGGGAAAAACGAAGTGCATTTGATTGGTGTGTATTGGCCAAGTTTTGCTT

GTTGTGTGCTTGAAAGAAAATATCTCTGACCAACTTCTGTATTCGTGGACCAAACTG

AAGCTATATTTTTCACAGAAGAAGAAGCAGTGACGGGGACACAAATTCTGTTGCCTG

GTGGAAAGAAGGCAAAGGCCTTCAGCAATCTATATTACCAGCGCTGGATCCTTTGAC

AGAGAGTGGTCCCTAAACTTAAATTTCAAGACGGTATAGGCTTGATCTGTCTTGCTT

ATTGTTGCCCCCTGCGCCTAGCACAATTCTGACACACAATTGGAACTTACTAAAAAT

TTTTTTTTACTGTT (SEQ ID NO: 81)

>NP_116171.3 hepatitis A virus cellular receptor 2

precursor [Homo sapiens]

MFSHLPFDCVLLLLLLLLTRSSEVEYRAEVGQNAYLPCFYTPAAPGNLVPVCWGKGA

CPVFECGNVVLRTDERDVNYWTSRYWLNGDFRKGDVSLTIENVTLADSGIYCCRIQI

PGIMNDEKFNLKLVIKPAKVTPAPTRQRDFTAAFPRMLTTRGHGPAETQTLGSLPDI

NLTQISTLANELRDSRLANDLRDSGATIRIGIYIGAGICAGLALALIFGALIFKWYS

HSKEKIQNLSLISLANLPPSGLANAVAEGIRSEENIYTIEENVYEVEEPNEYYCYVS

SRQQPSQPLGCRFAMP (SEQ ID NO: 82)

Mouse Tim-3
>NM_134250.2 Mus musculus hepatitis A virus cellular

(HAVCR2)
receptor 2 (Havcr2), mRNA

ACCATTTTAACCGAGGAGCTAAAGCTATCCCTACACAGAGCTGTCCTTGGATTTCCC

CTGCCAAGTACTCATGTTTTCAGGTCTTACCCTCAACTGTGTCCTGCTGCTGCTGCA

ACTACTACTTGCAAGGTCATTGGAAAATGCTTATGTGTTTGAGGTTGGTAAGAATGC

CTATCTGCCCTGCAGTTACACTCTATCTACACCTGGGGCACTTGTGCCTATGTGCTG

GGGCAAGGGATTCTGTCCTTGGTCACAGTGTACCAACGAGTTGCTCAGAACTGATGA

AAGAAATGTGACATATCAGAAATCCAGCAGATACCAGCTAAAGGGCGATCTCAACAA

AGGAGACGTGTCTCTGATCATAAAGAATGTGACTCTGGATGACCATGGGACCTACTG

CTGCAGGATACAGTTCCCTGGTCTTATGAATGATAAAAAATTAGAACTGAAATTAGA

CATCAAAGCAGCCAAGGTCACTCCAGCTCAGACTGCCCATGGGGACTCTACTACAGC

TTCTCCAAGAACCCTAACCACGGAGAGAAATGGTTCAGAGACACAGACACTGGTGAC

CCTCCATAATAACAATGGAACAAAAATTTCCACATGGGCTGATGAAATTAAGGACTC

TGGAGAAACGATCAGAACTGCTATCCACATTGGAGTGGGAGTCTCTGCTGGGTTGAC

CCTGGCACTTATCATTGGTGTCTTAATCCTTAAATGGTATTCCTGTAAGAAAAAGAA

GTTATCGAGTTTGAGCCTTATTACACTGGCCAACTTGCCTCCAGGAGGGTTGGCAAA

TGCAGGAGCAGTCAGGATTCGCTCTGAGGAAAATATCTACACCATCGAGGAGAACGT

ATATGAAGTGGAGAATTCAAATGAGTACTACTGCTACGTCAACAGCCAGCAGCCATC

CTGACCGCCTCTGGACTGCCACTTTTAAAGGCTCGCCTTCATTTCTGACTTTGGTAT

TTCCCTTTTTGAAAACTATGTGATATGTCACTTGGCAACCTCATTGGAGGTTCTGAC

CACAGCCACTGAGAAAAGAGTTCCAGTTTTCTGGGGATAATTAACTCACAAGGGGAT

TCGACTGTAACTCATGCTACATTGAAATGCTCCATTTTATCCCTGAGTTTCAGGGAT

CGGATCTCCCACTCCAGAGACTTCAATCATGCGTGTTGAAGCTCACTCGTGCTTTCA

TACATTAGGAATGGTTAGTGTGATGTCTTTGAGACATAGAGGTTTGTGGTATATCTG

CAAAGCTCCTGAACAGGTAGGGGGAATAAAGGGCTAAGATAGGAAGGTGAGGTTCTT

TGTTGATGTTGAAAATCTAAAGAAGTTGGTAGCTTTTCTAGAGATTTCTGACCTTGA

AAGATTAAGAAAAAGCCAGGTGGCATATGCTTAACACTATATAACTTGGGAACCTTA

GGCAGGAGGGTGATAAGTTCAAGGTCAGCCAGGGCTATGCTGGTAAGACTGTCTCAA

AATCCAAAGACGAAAATAAACATAGAGACAGCAGGAGGCTGGAGATGAGGCTCGGAC

AGTGAGGTGCATTTTGTACAAGCACGAGGAATCTATATTTGATCGTAGACCCCACAT

GAAAAAGCTAGGCCTGGTAGAGCATGCTTGTAGACTCAAGAGATGGAGAGGTAAAGG

CACAACAGATCCCCGGGGCTTGCGTGCAGTCAGCTTAGCCTAGGTGCTGAGTTCCAA

GTCCACAAGAGTCCCTGTCTCAAAGTAAGATGGACTGAGTATCTGGCGAATGTCCAT

GGGGGTTGTCCTCTGCTCTCAGAAGAGACATGCACATGAACCTGCACACACACACAC

ACACACACACACACACACACACACACACACACACACACACACATGAAATGAAGGTTC

TCTCTGTGCCTGCTACCTCTCTATAACATGTATCTCTACAGGACTCTCCTCTGCCTC

TGTTAAGACATGAGTGGGAGCATGGCAGAGCAGTCCAGTAATTAATTCCAGCACTCA

GAAGGCTGGAGCAGAAGCGTGGAGAGTTCAGGAGCACTGTGCCCAACACTGCCAGAC

TCTTCTTACAGAAGAAAAAGGTTACCCGCAAGCAGCCTGCTGTCTGTAAAAGGAAAC

CCTGCGAAAGGCAAACTTTGACTGTTGTGTGCTCAAGGGGAACTGACTCAGACAACT

TCTCCATTCCTGGAGGAAACTGGAGCTGTTTCTGACAGAAGAACAACCGGTGACTGG

GACATACGAAGGCAGAGCTCTTGCAGCAATCTATATAGTCAGCAAAATATTCTTTGG

GAGGACAGTCGTCACCAAATTGATTTCCAAGCCGGTGGACCTCAGTTTCATCTGGCT

TACAGCTGCCTGCCCAGTGCCCTTGATCTGTGCTGGCTCCCATCTATAACAGAATCA

AATTAAATAGACCCCGAGTGAAAATATTAAGTGAGCAGAAAGGTAGCTTTGTTCAAA

GATTTTTTTGCATTGGGGAGCAACTGTGTACATCAGAGGACATCTGTTAGTGAGGAC

ACCAAAACCTGTGGTACCGTTTTTTCATGTATGAATTTTGTTGTTTAGGTTGCTTCT

AGCTAGCTGTGGAGGTCCTGGCTTTCTTAGGTGGGTATGGAAGGGAGACCATCTAAC

AAAATCCATTAGAGATAACAGCTCTCATGCAGAAGGGAAAACTAATCTCAAATGTTT

TAAAGTAATAAAACTGTACTGGCAAAGTACTTTGAGCATATTTAAA (SEQ ID

NO: 83)

>NP_599011.2 hepatitis A virus cellular receptor 2

homolog precursor [Mus musculus]

MFSGLTLNCVLLLLQLLLARSLENAYVFEVGKNAYLPCSYTLSTPGALVPMCWGKGF

CPWSQCTNELLRTDERNVTYQKSSRYQLKGDLNKGDVSLIIKNVTLDDHGTYCCRIQ

FPGLMNDKKLELKLDIKAAKVTPAQTAHGDSTTASPRTLTTERNGSETQTLVTLHNN

NGTKISTWADEIKDSGETIRTAIHIGVGVSAGLTLALIIGVLILKWYSCKKKKLSSL

SLITLANLPPGGLANAGAVRIRSEENIYTIEENVYEVENSNEYYCYVNSQQPS

(SEQ ID NO: 84)

Human Tim-4
>NM_138379.3 Homo sapiens T cell immunoglobulin and mucin

(TIMD4)
domain containing 4 (TIMD4), transcript variant 1, mRNA

AGACTCCTGGGTCCGGTCAACCGTCAAAATGTCCAAAGAACCTCTCATTCTCTGGCT

GATGATTGAGTTTTGGTGGCTTTACCTGACACCAGTCACTTCAGAGACTGTTGTGAC

GGAGGTTTTGGGTCACCGGGTGACTTTGCCCTGTCTGTACTCATCCTGGTCTCACAA

CAGCAACAGCATGTGCTGGGGGAAAGACCAGTGCCCCTACTCCGGTTGCAAGGAGGC

GCTCATCCGCACTGATGGAATGAGGGTGACCTCAAGAAAGTCAGCAAAATATAGACT

TCAGGGGACTATCCCGAGAGGTGATGTCTCCTTGACCATCTTAAACCCCAGTGAAAG

TGACAGCGGTGTGTACTGCTGCCGCATAGAAGTGCCTGGCTGGTTCAACGATGTAAA

GATAAACGTGCGCCTGAATCTACAGAGAGCCTCAACAACCACGCACAGAACAGCAAC

CACCACCACACGCAGAACAACAACAACAAGCCCCACCACCACCCGACAAATGACAAC

AACCCCAGCTGCACTTCCAACAACAGTCGTGACCACACCCGATCTCACAACCGGAAC

ACCACTCCAGATGACAACCATTGCCGTCTTCACAACAGCAAACACGTGCCTTTCACT

AACCCCAAGCACCCTTCCGGAGGAAGCCACAGGTCTTCTGACTCCCGAGCCTTCTAA

GGAAGGGCCCATCCTCACTGCAGAATCAGAAACTGTCCTCCCCAGTGATTCCTGGAG

TAGTGTTGAGTCTACTTCTGCTGACACTGTCCTGCTGACATCCAAAGAGTCCAAAGT

TTGGGATCTCCCATCAACATCCCACGTGTCAATGTGGAAAACGAGTGATTCTGTGTC

TTCTCCTCAGCCTGGAGCATCTGATACAGCAGTTCCTGAGCAGAACAAAACAACAAA

AACAGGACAGATGGATGGAATACCCATGTCAATGAAGAATGAAATGCCCATCTCCCA

ACTACTGATGATCATCGCCCCCTCCTTGGGATTTGTGCTCTTCGCATTGTTTGTGGC

GTTTCTCCTGAGAGGGAAACTCATGGAAACCTATTGTTCGCAGAAACACACAAGGCT

AGACTACATTGGAGATAGTAAAAATGTCCTCAATGACGTGCAGCATGGAAGGGAAGA

CGAAGACGGCCTTTTTACCCTCTAACAACGCAGTAGCATGTTAGATTGAGGATGGGG

GCATGACACTCCAGTGTCAAAATAAGTCTTAGTAGATTTCCTTGTTTCATAAAAAAG

ACTCACTTATTCCATGGATGTCATTGATCCAGGCTTGCTTTAGTTTCATGAATGAAG

GGTACTTTAGAGACCACAA (SEQ ID NO: 85)

>NP_612388.2 T-cell immunoglobulin and mucin domain-

containing protein 4 isoform 1 precursor [Homo sapiens]

MSKEPLILWLMIEFWWLYLTPVTSETVVTEVLGHRVTLPCLYSSWSHNSNSMCWGKD

QCPYSGCKEALIRTDGMRVTSRKSAKYRLQGTIPRGDVSLTILNPSESDSGVYCCRI

EVPGWFNDVKINVRLNLQRASTTTHRTATTTTRRTTTTSPTTTRQMTTTPAALPTTV

VTTPDLTTGTPLQMTTIAVFTTANTCLSLTPSTLPEEATGLLTPEPSKEGPILTAES

ETVLPSDSWSSVESTSADTVLLTSKESKVWDLPSTSHVSMWKTSDSVSSPQPGASDT

AVPEQNKTTKTGQMDGIPMSMKNEMPISQLLMIIAPSLGFVLFALFVAFLLRGKLME

TYCSQKHTRLDYIGDSKNVLNDVQHGREDEDGLFTL (SEQ ID NO: 86)

Mouse Tim-4
>NM_178759.4 Mus musculus T cell immunoglobulin and mucin

(TIMD4)
domain containing 4 (Timd4), mRNA

AGATCCTATCAAAATGTCCAAGGGGCTTCTCCTCCTCTGGCTGGTGACGGAGCTCTG

GTGGCTTTATCTGACACCAGCTGCCTCAGAGGATACAATAATAGGGTTTTTGGGCCA

GCCGGTGACTTTGCCTTGTCATTACCTCTCGTGGTCCCAGAGCCGCAACAGTATGTG

CTGGGGCAAAGGTTCATGTCCCAATTCCAAGTGCAATGCAGAGCTTCTCCGTACAGA

TGGAACAAGAATCATCTCCAGGAAGTCAACAAAATATACACTTTTGGGGAAGGTCCA

GTTTGGTGAAGTGTCCTTGACCATCTCAAACACCAATCGAGGTGACAGTGGGGTGTA

CTGCTGCCGTATAGAGGTGCCTGGCTGGTTCAATGATGTCAAGAAGAATGTGCGCTT

GGAGCTGAGGAGAGCCACAACAACCAAAAAACCAACAACAACCACCCGGCCAACCAC

CACCCCTTATGTGACCACCACCACCCCAGAGCTGCTTCCAACAACAGTCATGACCAC

ATCTGTTCTCCCAACCACCACACCACCCCAGACACTAGCCACCACTGCCTTCAGTAC

AGCAGTGACCACGTGCCCCTCAACAACACCTGGCTCCTTCTCACAAGAAACCACAAA

AGGGTCCGCCTTCACTACAGAATCAGAAACTCTGCCTGCATCCAATCACTCTCAAAG

AAGCATGATGACCATATCTACAGACATAGCCGTACTCAGGCCCACAGGCTCTAACCC

TGGGATTCTCCCATCCACTTCACAGCTGACGACACAGAAAACAACATTAACAACAAG

TGAGTCTTTGCAGAAGACAACTAAATCACATCAGATCAACAGCAGACAGACCATCTT

GATCATTGCCTGCTGTGTGGGATTTGTGCTAATGGTGTTATTGTTTCTGGCGTTTCT

CCTTCGAGGGAAAGTCACAGGAGCCAACTGTTTGCAGAGACACAAGAGGCCAGACAA

CACTGAAGATAGTGACAGCGTCCTCAATGACATGTCACACGGGAGGGATGATGAAGA

CGGGATCTTCACTCTCTGACTCACCATCTTTATTTAGGATTAAGGATAGGGAATGGC

ACTTGAATTGTCAAAATAAGTTTGGGGACATTGTAATTTCCGTTTAAAGTCTCACTC

TGTTTACTGATGCTGTGGGTCCTGTCTGGTTGTATCTTCCCACATGAAGGTGCTTTA

GAGACACATTTTCCCTGCCTCGTGCCTTAGTCCTCTTTGTTGTTTTGTGGCTAGGTG

ACTTTTCACACTGGGCTTGAACACTGTCAGTGATGGTGAAATCCTTGCCACAGCTTT

GGGAGTCTCTTGCAGTCTCCCAGCAGTAGAGGGAGTTAGAAATATCCAGAGGGGAAA

AAAAAATCTCTCTTTTCAGACAGTATCTGCTTTATTGGTGGTAGCTGAACTTCATTT

ATACAGAGCTCCTTTAACCTGTCTGTCTTCTTCTTGGTATCTAAGCTGCCTTTTGTT

TTTGTTTTTGTTTTTGTTTTTATGATATTAACTTCTTTTCACATTCAAGTTTCTTTA

AAGTTGACTATAGTGCCTTCTGAACTCTTGCAGAGAGTTTGGATTTTGGAAGCTGCC

AGGTACCCATCACAGCAGGGGTGCCAGTGACAAGGATGGTGTACAAATGAAACACTG

AAGCTATCCAAATAAATTCCTCTAAGTGTAATTCATTTTACTGCAGCACAGGAAGAA

CAAATTTGTCTTACAACTTTAATAATTAGTACCATTATGAACCCTAGGAGAGAAATA

AGAGCAAATACCTGTTGAATAAATGAATGTAAGAAAATGTGTGTCTGAGCAAGAATA

CTCTGTCTGGCTACTATGGGAAGCTAGCTAGATCTGAAAGACATTCTCAGACTATCC

TCATGTTCAAGGCATTAAAGGAATAAGCCTCCAGCCCCTAACCTTAGGAGAATTCTG

CAGTCAAGTGAGGAGTTTTTAAAACAGGAATCTCTAGGTTCCAGTCCTCTAGCTATT

CTTTTATGCTTAGTCCAGGTAATGAGTTGAACATCCAAGTATTTTTTAAGGACCCAA

AGAAATGCAACCAGAGCTATTACCAGAATTTTGGAGTGGTCCTCCTAGAGTTGCCGC

ATGTTGCTGGGAAAATTGGGGTCTTAGAGTTCTTAGTCTACTTAATAAAAGAATTTT

AAAAAATGG (SEQ ID NO: 87)

>NP_848874.3 T-cell immunoglobulin and mucin domain-

containing protein 4 precursor [Mus musculus]

MSKGLLLLWLVTELWWLYLTPAASEDTIIGFLGQPVTLPCHYLSWSQSRNSMCWGKG

SCPNSKCNAELLRTDGTRIISRKSTKYTLLGKVQFGEVSLTISNTNRGDSGVYCCRI

EVPGWFNDVKKNVRLELRRATTTKKPTTTTRPTTTPYVTTTTPELLPTTVMTTSVLP

TTTPPQTLATTAFSTAVTTCPSTTPGSFSQETTKGSAFTTESETLPASNHSQRSMMT

ISTDIAVLRPTGSNPGILPSTSQLTTQKTTLTTSESLQKTTKSHQINSRQTILIIAC

CVGFVLMVLLFLAFLLRGKVTGANCLQRHKRPDNTEDSDSVLNDMSHGRDDEDGIFT

L (SEQ ID NO: 88)

Human
>NM_001712.5 Homo sapiens CEA cell adhesion molecule 1

CEACAM1
(CEACAM1), transcript variant 1, mRNA

AGCACAGAGAGTGGAAAACAGCAGAGGTGACAGAGCAGCCGTGCTCGAAGCGTTCCT

GGAGCCCAAGCTCTCCTCCACAGGTGAAGACAGGGCCAGCAGGAGACACCATGGGGC

ACCTCTCAGCCCCACTTCACAGAGTGCGTGTACCCTGGCAGGGGCTTCTGCTCACAG

CCTCACTTCTAACCTTCTGGAACCCGCCCACCACTGCCCAGCTCACTACTGAATCCA

TGCCATTCAATGTTGCAGAGGGGAAGGAGGTTCTTCTCCTTGTCCACAATCTGCCCC

AGCAACTTTTTGGCTACAGCTGGTACAAAGGGGAAAGAGTGGATGGCAACCGTCAAA

TTGTAGGATATGCAATAGGAACTCAACAAGCTACCCCAGGGCCCGCAAACAGCGGTC

GAGAGACAATATACCCCAATGCATCCCTGCTGATCCAGAACGTCACCCAGAATGACA

CAGGATTCTACACCCTACAAGTCATAAAGTCAGATCTTGTGAATGAAGAAGCAACTG

GACAGTTCCATGTATACCCGGAGCTGCCCAAGCCCTCCATCTCCAGCAACAACTCCA

ACCCTGTGGAGGACAAGGATGCTGTGGCCTTCACCTGTGAACCTGAGACTCAGGACA

CAACCTACCTGTGGTGGATAAACAATCAGAGCCTCCCGGTCAGTCCCAGGCTGCAGC

TGTCCAATGGCAACAGGACCCTCACTCTACTCAGTGTCACAAGGAATGACACAGGAC

CCTATGAGTGTGAAATACAGAACCCAGTGAGTGCGAACCGCAGTGACCCAGTCACCT

TGAATGTCACCTATGGCCCGGACACCCCCACCATTTCCCCTTCAGACACCTATTACC

GTCCAGGGGCAAACCTCAGCCTCTCCTGCTATGCAGCCTCTAACCCACCTGCACAGT

ACTCCTGGCTTATCAATGGAACATTCCAGCAAAGCACACAAGAGCTCTTTATCCCTA

ACATCACTGTGAATAATAGTGGATCCTATACCTGCCACGCCAATAACTCAGTCACTG

GCTGCAACAGGACCACAGTCAAGACGATCATAGTCACTGAGCTAAGTCCAGTAGTAG

CAAAGCCCCAAATCAAAGCCAGCAAGACCACAGTCACAGGAGATAAGGACTCTGTGA

ACCTGACCTGCTCCACAAATGACACTGGAATCTCCATCCGTTGGTTCTTCAAAAACC

AGAGTCTCCCGTCCTCGGAGAGGATGAAGCTGTCCCAGGGCAACACCACCCTCAGCA

TAAACCCTGTCAAGAGGGAGGATGCTGGGACGTATTGGTGTGAGGTCTTCAACCCAA

TCAGTAAGAACCAAAGCGACCCCATCATGCTGAACGTAAACTATAATGCTCTACCAC

AAGAAAATGGCCTCTCACCTGGGGCCATTGCTGGCATTGTGATTGGAGTAGTGGCCC

TGGTTGCTCTGATAGCAGTAGCCCTGGCATGTTTTCTGCATTTCGGGAAGACCGGCA

GGGCAAGCGACCAGCGTGATCTCACAGAGCACAAACCCTCAGTCTCCAACCACACTC

AGGACCACTCCAATGACCCACCTAACAAGATGAATGAAGTTACTTATTCTACCCTGA

ACTTTGAAGCCCAGCAACCCACACAACCAACTTCAGCCTCCCCATCCCTAACAGCCA

CAGAAATAATTTATTCAGAAGTAAAAAAGCAGTAATGAAACCTGTCCTGCTCACTGC

AGTGCTGATGTATTTCAAGTCTCTCACCCTCATCACTAGGAGATTCCTTTCCCCTGT

AGGGGTAGAGGGGTGGGGACAGAAACAACTTTCTCCTACTCTTCCTTCCTAATAGGC

ATCTCCAGGCTGCCTGGTCACTGCCCCTCTCTCAGTGTCAATAGATGAAAGTACATT

GGGAGTCTGTAGGAAACCCAACCTTCTTGTCATTGAAATTTGGCAAAGCTGACTTTG

GGAAAGAGGGACCAGAACTTCCCCTCCCTTCCCCTTTTCCCAACCTGGACTTGTTTT

AAACTTGCCTGTTCAGAGCACTCATTCCTTCCCACCCCCAGTCCTGTCCTATCACTC

TAATTCGGATTTGCCATAGCCTTGAGGTTATGTCCTTTTCCATTAAGTACATGTGCC

AGGAAACAAGAGAGAGAGAAAGTAAAGGCAGTAATGCCTTCTCCTATTTCTCCAAAG

CCTTGTGTGAACTCACCAAACACAAGAAAATCAAATATATAACCAATAGTGAAATGC

CACACCTTTGTCCACTGTCAGGGTTGTCTACCTGTAGGATCAGGGTCTAAGCACCTT

GGTGCTTAGCTAGAATACCACCTAATCCTTCTGGCAAGCCTGTCTTCAGAGAACCCA

CTAGAAGCAACTAGGAAAATCACTTGCCAAAATCCAAGGCAATTCCTGATGGAAAAT

GCAAAAGCACATATATGTTTTAATATCTTTATGGGCTCTGTTCAAGGCAGTGCTGAG

AGGGAGGGGTTATAGCTTCAGGAGGGAACCAGCTTCTGATAAACACAATCTGCTAGG

AACTTGGGAAAGGAATCAGAGAGCTGCCCTTCAGCGATTATTTAAATTATTGTTAAA

GAATACACAATTTGGGGTATTGGGATTTTTCTCCTTTTCTCTGAGACATTCCACCAT

TTTAATTTTTGTAACTGCTTATTTATGTGAAAAGGGTTATTTTTACTTAGCTTAGCT

ATGTCAGCCAATCCGATTGCCTTAGGTGAAAGAAACCACCGAAATCCCTCAGGTCCC

TTGGTCAGGAGCCTCTCAAGATTTTTTTTGTCAGAGGCTCCAAATAGAAAATAAGAA

AAGGTTTTCTTCATTCATGGCTAGAGCTAGATTTAACTCAGTTTCTAGGCACCTCAG

ACCAATCATCAACTACCATTCTATTCCATGTTTGCACCTGTGCATTTTCTGTTTGCC

CCCATTCACTTTGTCAGGAAACCTTGGCCTCTGCTAAGGTGTATTTGGTCCTTGAGA

AGTGGGAGCACCCTACAGGGACACTATCACTCATGCTGGTGGCATTGTTTACAGCTA

GAAAGCTGCACTGGTGCTAATGCCCCTTGGGGAAATGGGGCTGTGAGGAGGAGGATT

ATAACTTAGGCCTAGCCTCTTTTAACAGCCTCTGAAATTTATCTTTTCTTCTATGGG

GTCTATAAATGTATCTTATAATAAAAAGGAAGGACAGGAGGAAGACAGGCAAATGTA

CTTCTCACCCAGTCTTCTACACAGATGGAATCTCTTTGGGGCTAAGAGAAAGGTTTT

ATTCTATATTGCTTACCTGATCTCATGTTAGGCCTAAGAGGCTTTCTCCAGGAGGAT

TAGCTTGGAGTTCTCTATACTCAGGTACCTCTTTCAGGGTTTTCTAACCCTGACACG

GACTGTGCATACTTTCCCTCATCCATGCTGTGCTGTGTTATTTAATTTTTCCTGGCT

AAGATCATGTCTGAATTATGTATGAAAATTATTCTATGTTTTTATAATAAAAATAAT

ATATCAGACATCGA (SEQ ID NO: 89)

>NP_001703.2 carcinoembryonic antigen-related cell

adhesion molecule 1 isoform 1 precursor [Homo sapiens]

MGHLSAPLHRVRVPWQGLLLTASLLTFWNPPTTAQLTTESMPFNVAEGKEVLLLVHN

LPQQLFGYSWYKGERVDGNRQIVGYAIGTQQATPGPANSGRETIYPNASLLIQNVTQ

NDTGFYTLQVIKSDLVNEEATGQFHVYPELPKPSISSNNSNPVEDKDAVAFTCEPET

QDTTYLWWINNQSLPVSPRLQLSNGNRTLTLLSVTRNDTGPYECEIQNPVSANRSDP

VTLNVTYGPDTPTISPSDTYYRPGANLSLSCYAASNPPAQYSWLINGTFQQSTQELF

IPNITVNNSGSYTCHANNSVTGCNRTTVKTIIVTELSPVVAKPQIKASKTTVTGDKD

SVNLTCSTNDTGISIRWFFKNQSLPSSERMKLSQGNTTLSINPVKREDAGTYWCEVF

NPISKNQSDPIMLNVNYNALPQENGLSPGAIAGIVIGVVALVALIAVALACFLHFGK

TGRASDQRDLTEHKPSVSNHTQDHSNDPPNKMNEVTYSTLNFEAQQPTQPTSASPSL

TATEIIYSEVKKQ (SEQ ID NO: 90)

Mouse
>NM_01039185.1 Mus musculus carcinoembryonic antigen-

CEACAM1
related cell adhesion molecule 1 (Ceacam1), transcript

variant 1, mRNA

AAAGCTCCTTTAAGAAAAGCAGGGCAGATATCAGGGCAGCCTGGCTTAGCAGTAGTG

TTGGAGAAGAAGCTAGCAGGCAGGCAGCAGAGACATGGAGCTGGCCTCAGCACATCT

CCACAAAGGGCAGGTTCCCTGGGGAGGACTACTGCTCACAGCCTCACTTTTAGCCTC

CTGGAGCCCTGCCACCACTGCTGAAGTCACCATTGAGGCTGTGCCGCCCCAGGTTGC

TGAAGACAACAATGTTCTTCTACTTGTTCACAATCTGCCCCTGGCGCTTGGAGCCTT

TGCCTGGTACAAGGGAAACACTACGGCTATAGACAAAGAAATTGCACGATTTGTACC

AAATAGTAATATGAATTTCACGGGGCAAGCATACAGCGGCAGAGAGATAATATACAG

CAATGGATCCCTGCTCTTCCAAATGATCACCATGAAGGATATGGGAGTCTACACACT

AGATATGACAGATGAAAACTATCGTCGTACTCAGGCGACTGTGCGATTTCATGTACA

CCCCATATTATTAAAGCCCAACATCACAAGCAACAACTCCAATCCCGTGGAGGGTGA

CGACTCCGTATCATTAACCTGTGACTCTTACACTGACCCTGATAATATAAACTACCT

GTGGAGCAGAAATGGTGAAAGCCTTTCAGAAGGTGACAGGCTGAAGCTGTCTGAGGG

CAACAGGACTCTCACTTTACTCAATGTCACGAGGAATGACACAGGACCCTATGTGTG

TGAAACCCGGAATCCAGTGAGTGTCAACCGAAGTGACCCATTCAGCCTGAACATTAT

CTATGGTCCGGACACCCCGATTATATCCCCCTCAGATATTTATTTGCATCCAGGGTC

AAACCTCAACCTCTCCTGCCATGCAGCCTCTAACCCACCTGCACAGTACTTTTGGCT

TATCAATGAGAAGCCCCATGCATCCTCCCAAGAGCTCTTTATCCCCAACATCACTAC

TAATAATAGCGGAACCTATACCTGCTTCGTCAATAACTCTGTCACTGGCCTCAGTAG

GACCACAGTCAAGAACATTACAGTCCTTGAGCCAGTGACTCAGCCCTTCCTCCAAGT

CACCAACACCACAGTCAAAGAACTAGACTCTGTGACCCTGACCTGCTTGTCGAATGA

CATTGGAGCCAACATCCAGTGGCTCTTCAATAGCCAGAGTCTTCAGCTCACAGAGAG

AATGACACTCTCCCAGAACAACAGCATCCTCAGAATAGACCCTATTAAGAGGGAAGA

TGCCGGCGAGTATCAGTGTGAAATCTCGAATCCAGTCAGCGTCAGGAGGAGCAACTC

AATCAAGCTGGACATAATATTTGACCCAACACAAGGAGGCCTCTCAGATGGCGCCAT

TGCTGGCATCGTGATTGGAGTTGTGGCTGGGGTGGCTCTAATAGCAGGGCTGGCATA

TTTCCTCTATTCCAGGAAGTCTGGCGGGGGAAGTGACCAGCGAGATCTCACAGAGCA

CAAACCCTCAGCCTCCAACCACAATCTGGCTCCTTCTGACAACTCTCCTAACAAGGT

GGATGACGTCGCATACACTGTCCTGAACTTCAATTCCCAGCAACCCAACCGGCCAAC

TTCAGCCCCTTCTTCTCCAAGAGCCACAGAAACAGTTTATTCAGAAGTAAAAAAGAA

GTGAGCATAATCTGTCCGTCTGTCCTGCTGGCTGCACCAGTGATGCATTCCCGGATT

CTGTTCCTCACTGGAGGGTCTCAGCACACACACACACGTACACATGCGCGCGCGCAC

ACACACACACACACACACACACACACACTTACACACACACTCATGCATTCACTCTAT

TGACTCCTTCAGTGTCTATAGAAGAAAAGGTGGATCCTGGAGCCTACAGAAAACTCA

ACCCTTCTAGGCTTTCAAATTTGGCTGAGAGTGAGGTATCAAAATTTCTCACCCTTT

CACTTTCCTGACCCAGATTGTTGAAAATTGACCTATTCAGAGCACCTTCATTCCCCT

CCCAACTCCAAGTCCTGCCCTATCAGAGTCTGACTTGAATTTCCATAAACCTTGGAG

GTCACCTAAGTGCTTACGCCAAACAAAACAAAACAAAACAAAACAAAACAAAACAAA

ACAAAACAAAACAAACCAGAAGCAGGAAATGGCCAGTCCCATATCTTTAAAGGCTGA

TTGGAAGCCACCATACATGAGAAGATCAAACCTCCATGGGCAATCTACACACCCGAC

AACTGTCATGCTTACCCATCTGGGACATTCGAGTCTCTGAACCTTGTGCCCTCACGC

CTGAGCCCTTCTCTGAGCCTTTCTCCAGAAAATCCACTCACAGCAACTAGAGAGGCT

CTTTGTCAGCAACTCCAAGCAAACTGCTAGGCAGGATTCAGAAGAAAAGACAGCATC

TCTAACATCCACCAGGAAGGTGCCCAGAAAAGCAGAGCTGGTGACTTTGGACTGACA

GACATCTGGAGTGTGAAAAAGCAGCACAGAGCTAACCTTCGGAGAGTGTTGAAATTA

TTTGAAAAGAAGCCATATTTGGAGGTATTGGAGTTTTCCTCTTTCTGAGACAATCCA

CTATTTGAAAATTGTAGCTACTGAATTGCCTCTCAGTATGCGAGCTGATCACTTTGC

CTTAGGGCCACTAGATTTCTGTCTCCCTTAGCCCCTCAAGCCCTTTTGATCATGAGT

TCCAAACCAAAAATAAATAAATGAACAGTGAGGCAGTCCCTTGCAGTACCACTGTCA

TGGGTCAGGCTAAGCCTCCTGCTTTTCTGAATTAGTCAAGAAAAGCCTTGGTTTCCC

TTTTTCCATCTCTTTATCTTGTCTTTCAGATACTGGCCAGAGCCTGGACACTCTTCC

TCTGAGATCTCCAGCTTCTCTGCCTTCTTGTGTTTCTTTTAAACTCTAACAAAAACT

GTTCTCACCTTCAAAAAATAAAATAATAACAAGCTTTCCACATCCCCACCAAAGAGG

GACCCAGCTAGGTTTCTGGAAACCCAGCACCAGCCTCCAGCTGCCCTTCTGCAGTGT

TTCTGCCTCTGTTTCCCTTTCGTTTTGACTTTTTTCCTTCTTTTGAGACAGAGTTCC

AGCATGGAGCCTGTGCAGGTTTCAATCCCACAGTAACACCTTCTGCAGCACCCCACC

TGCTCAGACTGCAGCCCTGGCCACCAGGCCTGGCTACCTGGACATTCTGTCTGCCCT

GCACTCTCAGGAAACCTTGGCCTCTGCTACTGTCTGTTTGGCTCATTCAAAGTGTGT

CCTTAAAGGAATGCAGTCACCCATGCCAGAGGCAGTGTTTACAGCCTGGAATGCTCT

GCACTTCCAGTGGACCAGTGCTCCACCGGAAGTGGGCTGTTAGCAGGGTCCTCTCAC

CTGGCCCTGGCCTTTCTGTAGCCTTGAATCCTGCCTTCCCCACCAGGGCACCAGGGA

TGAGTGCAGCAGCAGGAGGAGAGGCAAACAGTCACCTCAGGAACCTTCTGAGCTAAG

GCACACCCTCTGTGCCTGTCAAGCAAAGGTTGTATTGGATATCAAGTGTTTGGTCTC

ACGCCAAGCCAACAGGCTTTGGAGAGAATTAATTAGTTCTCCTACTCAGGGATTTCT

TTCAGTCCTAACACAGCCTGTGTATATTTTGCTTCACCCACGCAATGCTGGATTATT

TAATTTTGCCCGGCTTAAGACAAATCTGAGTTACTTGTAAATTTGCTCTATGTTCAT

AATAAAAATGTATTATATATCACTGATAGCA (SEQ ID NO: 91)

>NP_001034274.1 carcinoembryonic antigen-related cell

adhesion molecule 1 isoform 1 precursor [Mus musculus]

MELASAHLHKGQVPWGGLLLTASLLASWSPATTAEVTIEAVPPQVAEDNNVLLLVHN

LPLALGAFAWYKGNTTAIDKEIARFVPNSNMNFTGQAYSGREIIYSNGSLLFQMITM

KDMGVYTLDMTDENYRRTQATVRFHVHPILLKPNITSNNSNPVEGDDSVSLTCDSYT

DPDNINYLWSRNGESLSEGDRLKLSEGNRTLTLLNVTRNDTGPYVCETRNPVSVNRS

DPFSLNIIYGPDTPIISPSDIYLHPGSNLNLSCHAASNPPAQYFWLINEKPHASSQE

LFIPNITTNNSGTYTCFVNNSVTGLSRTTVKNITVLEPVTQPFLQVTNTTVKELDSV

TLTCLSNDIGANIQWLFNSQSLQLTERMTLSQNNSILRIDPIKREDAGEYQCEISNP

VSVRRSNSIKLDIIFDPTQGGLSDGAIAGIVIGVVAGVALIAGLAYFLYSRKSGGGS

DQRDLTEHKPSASNHNLAPSDNSPNKVDDVAYTVLNFNSQQPNRPTSAPSSPRATET

VYSEVKKK (SEQ ID NO: 92)

Human
>NM_007048.6 Homo sapiens butyrophilin subfamily 3 member

BTN3A1
A1 (BTN3A1), transcript variant 1, mRNA

ATTCCTCACGATGACCCGACAGTCTCTGCTTTCTTTTTCCTTTCTTCCAGAAGGAGA

TTTAACCATAGTAGAAAGAATGGAGAACTATTAACTGCCTTTCTTCTGTGGGCTGTG

ATTTTCAGAGGGGAATGCTAAGAGGTGATTTTCAATGTTGGGACTCAAAGGTGAAGA

CACTGAAGGACAGAATTTTTGGCAGAGGAAAGATCTTCTTCGGTCACCATACTTGAG

TTAGCTCTAGGGAAGTGGAGGTTTCCATTTGGAATTCTATAGCTTCTTCCAGGTCAT

AGTGTCTGCCCCCCACCTTCCAGTATCTCCTGATATGCAGCATGAATGAAAATGGCA

AGTTTCCTGGCCTTCCTTCTGCTCAACTTTCGTGTCTGCCTCCTTTTGCTTCAGCTG

CTCATGCCTCACTCAGCTCAGTTTTCTGTGCTTGGACCCTCTGGGCCCATCCTGGCC

ATGGTGGGTGAAGACGCTGATCTGCCCTGTCACCTGTTCCCGACCATGAGTGCAGAG

ACCATGGAGCTGAAGTGGGTGAGTTCCAGCCTAAGGCAGGTGGTGAACGTGTATGCA

GATGGAAAGGAAGTGGAAGACAGGCAGAGTGCACCGTATCGAGGGAGAACTTCGATT

CTGCGGGATGGCATCACTGCAGGGAAGGCTGCTCTCCGAATACACAACGTCACAGCC

TCTGACAGTGGAAAGTACTTGTGTTATTTCCAAGATGGTGACTTCTATGAAAAAGCC

CTGGTGGAGCTGAAGGTTGCAGCACTGGGTTCTGATCTTCACGTTGATGTGAAGGGT

TACAAGGATGGAGGGATCCATCTGGAGTGCAGGTCCACTGGCTGGTACCCCCAACCC

CAAATACAGTGGAGCAACAACAAGGGAGAGAACATCCCGACTGTGGAAGCACCTGTG

GTTGCAGACGGAGTGGGCCTGTATGCAGTAGCAGCATCTGTGATCATGAGAGGCAGC

TCTGGGGAGGGTGTATCCTGTACCATCAGAAGTTCCCTCCTCGGCCTGGAAAAGACA

GCCAGCATTTCCATCGCAGACCCCTTCTTCAGGAGCGCCCAGAGGTGGATCGCCGCC

CTGGCAGGGACCCTGCCTGTCTTGCTGCTGCTTCTTGGGGGAGCCGGTTACTTCCTG

TGGCAACAGCAGGAGGAAAAAAAGACTCAGTTCAGAAAGAAAAAGAGAGAGCAAGAG

TTGAGAGAAATGGCATGGAGCACAATGAAGCAAGAACAAAGCACAAGAGTGAAGCTC

CTGGAGGAACTCAGATGGAGAAGTATCCAGTATGCATCTCGGGGAGAGAGACATTCA

GCCTATAATGAATGGAAAAAGGCCCTCTTCAAGCCTGCGGATGTGATTCTGGATCCA

AAAACAGCAAACCCCATCCTCCTTGTTTCTGAGGACCAGAGGAGTGTGCAGCGTGCC

AAGGAGCCCCAGGATCTGCCAGACAACCCTGAGAGATTTAATTGGCATTATTGTGTT

CTCGGCTGTGAGAGCTTCATATCAGGGAGACATTACTGGGAGGTGGAGGTAGGGGAC

AGGAAAGAGTGGCATATAGGGGTGTGCAGTAAGAATGTGCAGAGAAAAGGCTGGGTC

AAAATGACACCTGAGAATGGATTCTGGACTATGGGGCTGACTGATGGGAATAAGTAT

CGGACTCTAACTGAGCCCAGAACCAACCTGAAACTTCCTAAGCCCCCTAAGAAAGTG

GGGGTCTTCCTGGACTATGAGACTGGAGATATCTCATTCTACAATGCTGTGGATGGA

TCGCATATTCATACTTTCCTGGACGTCTCCTTCTCTGAGGCTCTATATCCTGTTTTC

AGAATTTTGACCTTGGAGCCCACGGCCCTGACTATTTGTCCAGCGTGAAAAGAAGAA

GAGAGTTCCTCCAATTCTGACCGAGTGCTGATCATTCCCTAGAGACACCAGTAACCC

CGGGCTTAGCTAACGAAAGTGGGGAGCCTCAGGCTGAAGTAACTTTTCTCTGCTTCT

CCCTGCCCAGCTCAGAGCTGAGGGCCTCCCCCTCCACAGCAACCAATCACAACCATA

AAGCTACAAGCACGCACTGAAGCACTTTACTGATACTCATTCAATTATTCATATGAC

AGTTGTTTGAGTTTGGTACCATCTTATTTTCCCCTTATACAGATAAGGAAACTGGGG

TGCAGAAAAGTGAATTGACTACAAAGTAGACATGACTAGTTAACAACACAGCTGGGA

TCTAAACAGCAATAACTAACATTAATGGAGAACTTAAAATGCTCTGAGTGCTGTGTT

ATGAGCTTTGGTGGATGTCACTCCTTTAATCCTCGCAACACCCTGTCGGGTAGTCTC

ATTTAGCAAGTATGGAAGTTGAGGCAGGGCAACATTAAGCAACTTACATAACTCATG

CAGTAATTTCTGCAGTTGGGAGATGTTCAGCTTCAGTCCCCGGCCCTATGGCCGTTC

TTTTCCACCCTGTTTCTTCCCCCATAGGAAGAACCCACCTGTAGCCCTGAGGTTCTT

TTCCCAGGATGGCTCCAGGATAAGGATCACTGTAGGTGGTTGTGGAGTTGACACCCC

TGTTGACTCCTTCCCAGCTGATTGTCAGAGCCTTAGACCCAGCACGCCTTGGATTAG

CTCTGCAGAGTGTCTTGGTTGAGAGAATAACCTCACCGTACCCACATGACACGTGAT

TTGGAAAGAGACTAGAGGCCACACTTGATAAATCATGGGGAACAGATGTGTTCCACC

CAACAAATGTGATAAGTGATCATGCAGCCAGAGCCAGCCTTCCTTCAATCAAGGTTT

CCAGGCAGAGCAAATACCCTAGAGATTCTCTGTGATATAGGAAATTTGGATGAAGGG

AGCTAGAAGAAATACAGGGATTTTTTTTTTTTTTTAAGATGGAGTCTTACTCTGTTG

CTAGGCTGGAGTGCAGTGGTGCGATCTCAGCTCCCTGCAACCTCCACCTCCTGGGTT

CAAACAATTCTCCTGCCTCAGCCTCCCGAGTACTGGGAATATAGGTGCACGCCACCA

CACCCAACAAATTTTTGTACTTTTAGTACAGATGAGGGTTCACTATGTTGGCCAGGA

TGGTCTCGATCTCTTGACCTCATGATCCACCCACCTCGGTCTCCCAAAGTGCTGGGA

TTACAGGCTTGAGCCACCGGGTGACCGGCTTACAGGGATATTTTTAATCCCGTTATG

GACTCTGTCTCCAGGAGAGGGGTCTATCCACCCCTGCTCATTGGTGGATGTTAAACC

AATATTCCTTTCAACTGCTGCCTGCTAGGGAAAAACTACTCCTCATTATCATCATTA

TTATTGCTCTCCACTGTATCCCCTCTACCTGGCATGTGCTTGTCAAGTTCTAGTTGT

TCAATAAATTTGTTAATAATGCTGA (SEQ ID NO: 93)

>NP_008979.3 butyrophilin subfamily 3 member A1 isoform a

precursor [Homo sapiens]

MKMASFLAFLLLNFRVCLLLLQLLMPHSAQFSVLGPSGPILAMVGEDADLPCHLFPT

MSAETMELKWVSSSLRQVVNVYADGKEVEDRQSAPYRGRTSILRDGITAGKAALRIH

NVTASDSGKYLCYFQDGDFYEKALVELKVAALGSDLHVDVKGYKDGGIHLECRSTGW

YPQPQIQWSNNKGENIPTVEAPVVADGVGLYAVAASVIMRGSSGEGVSCTIRSSLLG

LEKTASISIADPFFRSAQRWIAALAGTLPVLLLLLGGAGYFLWQQQEEKKTQFRKKK

REQELREMAWSTMKQEQSTRVKLLEELRWRSIQYASRGERHSAYNEWKKALFKPADV

ILDPKTANPILLVSEDQRSVQRAKEPQDLPDNPERFNWHYCVLGCESFISGRHYWEV

EVGDRKEWHIGVCSKNVQRKGWVKMTPENGFWTMGLTDGNKYRTLTEPRTNLKLPKP

PKKVGVFLDYFTGDISFYNAVDGSHIHTFLDVSFSEALYPVFRILTLEPTALTICPA

(SEQ ID NO: 94)

Human
>NM_007047.5 Homo sapiens butyrophilin subfamily 3 member

BTN3A2
A2 (BTN3A2), transcript variant 1, mRNA

GACTCTTACTGTTTCTCATGGTGAGAAGACAATATTTGCTTTCTCTTTTTCCTTTCT

TCCGGATGAGAGGCTAAGCCATAATAGAAAGAATGGAGAATTATTGATTGACCGTCT

TTATTCTGTGGGCTCTGATTCTCCAATGGGAATACCAAGGGATGGTTTTCCATACTG

GAACCCAAAGGTAAAGACACTCAAGGACAGACATTTTTGGCAGAGCATAGATGAAAA

TGGCAAGTTCCCTGGCTTTCCTTCTGCTCAACTTTCATGTCTCCCTCCTCTTGGTCC

AGCTGCTCACTCCTTGCTCAGCTCAGTTTTCTGTGCTTGGACCCTCTGGGCCCATCC

TGGCCATGGTGGGTGAAGACGCTGATCTGCCCTGTCACCTGTTCCCGACCATGAGTG

CAGAGACCATGGAGCTGAAGTGGGTAAGTTCCAGCCTAAGGCAGGTGGTGAACGTGT

ATGCAGATGGAAAGGAAGTGGAAGACAGGCAGAGTGCACCGTATCGAGGGAGAACTT

CGATTCTGCGGGATGGCATCACTGCAGGGAAGGCTGCTCTCCGAATACACAACGTCA

CAGCCTCTGACAGTGGAAAGTACTTGTGTTATTTCCAAGATGGTGACTTCTATGAAA

AAGCCCTGGTGGAGCTGAAGGTTGCAGCACTGGGTTCTAATCTTCACGTCGAAGTGA

AGGGTTATGAGGATGGAGGGATCCATCTGGAGTGCAGGTCCACCGGCTGGTACCCCC

AACCCCAAATACAGTGGAGCAACGCCAAGGGAGAGAACATCCCAGCTGTGGAAGCAC

CTGTGGTTGCAGATGGAGTGGGCCTATATGAAGTAGCAGCATCTGTGATCATGAGAG

GCGGCTCCGGGGAGGGTGTATCCTGCATCATCAGAAATTCCCTCCTCGGCCTGGAAA

AGACAGCCAGCATTTCCATCGCAGACCCCTTCTTCAGGAGCGCCCAGCCCTGGATCG

CAGCCCTGGCAGGGACCCTGCCTATCTTGCTGCTGCTTCTCGCCGGAGCCAGTTACT

TCTTGTGGAGACAACAGAAGGAAATAACTGCTCTGTCCAGTGAGATAGAAAGTGAGC

AAGAGATGAAAGAAATGGGATATGCTGCAACAGAGCGGGAAATAAGCCTAAGAGAGA

GCCTCCAGGAGGAACTCAAGAGGAAAAAAATCCAGTACTTGACTCGTGGAGAGGAGT

CTTCGTCCGATACCAATAAGTCAGCCTGATGCTCTAATGGAAAAATGGCCCTCTTCA

AGCCTGGTGAGGAAATGCTTCAGATGAGGCTCCACCTTGTTAAATAAATTGGATGTA

TGGAAAAATAGACTGCAGAAAAGGGGAACTCATTTAGCTCACGAGTGGTCGAGTGAA

GATTGAAAATTAACCTCTGAGGGCCAGCACAGCAGCTCATGCCTGTAATCCTAGCAC

TTTGGAAGGCTGAGGAGGGCGGATCACAAGGTCAGGAGATCAAGACCATCCTGGCTA

ACACGGTGAAACCCCGTCTCTACTAAAAATACAAAAAATAAAAAATTAGCCGGGCAT

GGTGACGGGCACCTGTAGTCCCAGCTACTCGGGAGGCTGAGGCAGGAGAATGGCATG

AACCCGGAAGGCAGAGCTTGCAGTGAGCCGAGATCACGCCACTGCACTCCAGCCTGG

GAGACAGAGCGAGACTCTGTCTCAAGAAAAAAAAAAAAAAAAAAAAAGAAAAGAAAA

TTAACCTCTGAGTATAAAGCATCAGTGGGCAGAATCAATGTGGGGAGGGAAACAACA

AAAATGTAGAAAGAGGATCCTTGTTGCTTCTTGGGGCCGCATCAGGGTATTGGGTTA

GGCAGATACTGACCTTACTTTCATTTCCCCTCTGGTCACTAGACCCCTGGGGCTTTC

ACCAATGACATTGATGAGAGAATCACATTCAGGGCAGGCTAGGGACACGGGGTTCTG

GAAGGACCTCCTCAGCATGGCCCAAGCCTTGCATGCTGTGGCTCTTAAATCCAGGAA

AAATGGCTGACCCCATGGACACCTCCTCAAACTCTCTGCAGCAGATGTAATTCTGTA

TCCAGACATGGCAAATGCCATCCTCCTTGTTTCTGAGGACCAGAGGAGTGTACAGCG

TGCTGAGGAGCCCCATGACCTACCAGACAACCCTGAGAGATTTGAATGGCGTTACTG

TGTGCTTGGCTGTGAAAGCTTCATGTCAGAGAGACACTACTGGGAGGTGGAAGTGGG

GGACAGAAAAGAGTGGCATATTGGGGTATGTAGTAAGAACGTGGAGAGGAAAAAAGT

TTGGGTCAAAATGACACCGGAGAACGGATACTGGACTATGGGCCTGACTGATGGGAA

TAAGTATCGGGCTCTCACTGAGCCCAGAACCAACCTGAAACTTCCTGAGCCTCCTAG

GAAAGTGGGGGTCATCCTGGACTATGAGACTGGACATATCTCGTTCTACAATGCCAC

GGATGGATCTCATATCTACACATTTCTGCACGCCTCTTCCTCTGAGCCTCTGTATCC

TGTATTCAGAATTTTGACCTTGGAGCCCACTGCCCTGACCGTTTGCCCAATACCAAA

AGTAGAGAGTTCCCCCGATCCCGACCTAGTGCCTGATCATTCCCTGGAGATACCACT

GACCCCAGGCTTAGCTAATGAAAGTGGGGAGCCTCAGGCTGAAGTAACATCTCTGCT

TCTCCCTGCCCAGCCTGGAGCTAAGGGTCTCACCCTCCACAACAGCCAGTCAGAACC

ATAAAGCTACAGGCACACACTGAAGCACTTTACTGATATTCATTCAATTATTCCATA

GGACAGTTGTTTGAGTTTGGTGCCACCTTATTGGCCCCTTTATACAGATAAGGAAAC

TGGGGTGTAGAAAAGTGTATTGACTTTACAAAGCAGACAGGAATAGTGAACAACAGA

GCTGGGATCTGAACAACAATGACTAACATTAATGGAGAATTTAAAACGTTCTGAGTG

CTGTGTTATGAGCTTTGGTGGGTGTCACTCCTTTAATCCTCACAACACCCTGTCAGG

TAGTCTCATTTGGCAAGTATGGAAGCAGAGGCAGGGCAACATTAAGTAGCTTACATA

ACTCACACGGTAATTTGTGCAGTTGGGAGATGTTCAGCTTCAGTCCCTGGCCAATTG

CCCGTTCTTTTCCAGCCTGATTTTTCCTGCATGGGAAGAGCCCACATGTAGCCCTGA

GGTTCCCTTCCCAGGACAGCTCCAGGATCGAGATCACTGTGAGTGGTTGTGGAGTTA

AGACCCCTATGGACTCCTTCCCAGCTGATTATCAGAGCCTTAGACCCAGCACTCCTT

GGATTGGCTCTGCAGAGTGTCTTGGTTGAGAGAATAACGTTGCAGTTCCCACAGGGC

ATGTGACTTTGAAAGAGACTAGAGGCCACACTCAGTTAATAATGGGGCACAGATGTG

TTCCCACCCAACAAATGTGATAAGTGATCGTGCAGCCAGAGCCAGCCTTCCTTCAGT

CAAGGTTTCCAGGCAGAGCAAATACCCTAGAGATTCTCTGTAATATTGGTAATTTGG

ATGAAGGAAGCTAGAAGAATTACAGGGATGTTTTTAATCCCACTATGGACTCAGTCT

CCTGGAAAAGGATCTGTCCACTCCTGGTCATTGGTGGATGTTAAACCCATATTCCTT

TCAACTGCTGCCTGCTAGGGAAAACTGCTCCTCATTATCATCACTATTATTGCTCAC

CACTGTATCCCCTCTACTGGGCAAGTGCTTGTCAAGTTCTAGTTGTTCAATAAATTT

GTTAATAATGCTGA (SEQ ID NO: 95)

>NP_008978.2 butyrophilin subfamily 3 member A2 isoform a

precursor [Homo sapiens]

MKMASSLAFLLLNFHVSLLLVQLLTPCSAQFSVLGPSGPILAMVGEDADLPCHLFPT

MSAETMELKWVSSSLRQVVNVYADGKEVEDRQSAPYRGRTSILRDGITAGKAALRIH

NVTASDSGKYLCYFQDGDFYEKALVELKVAALGSNLHVEVKGYEDGGIHLECRSTGW

YPQPQIQWSNAKGENIPAVEAPVVADGVGLYEVAASVIMRGGSGEGVSCIIRNSLLG

LEKTASISIADPFFRSAQPWIAALAGTLPILLLLLAGASYFLWRQQKEITALSSEIE

SEQEMKEMGYAATEREISLRESLQEELKRKKIQYLTRGEESSSDINKSA (SEQ ID

NO: 96)

Human
>NM_007049.5 Homo sapiens butyrophilin subfamily 2 member

BTN2A1
A1 (BTN2A1), transcript variant 1, mRNA

AGATTTCGTTTCCTGCATCTCCAAACATGGCGACCTAGGAGAAGGGGAAGAACAATT

TTTTCTCCTCTTTTGGGAAGGTTTGTGTCTAGTAGTGCCTGTGCCCCTGGGCAGATT

GGAGAGAAGAGGGACGACTGGAGAATCGTCGAGAACCAGCGGAGAAAAGAAAAAGCA

ACGTTTAATTCTAGAAGGCCTCCTGTCCCTGCCTGCTCTGGGTGCTCATGGAATCAG

CTGCTGCCCTGCACTTCTCCCGGCCAGCCTCCCTCCTCCTCCTCCTCCTCAGCCTGT

GTGCACTGGTCTCAGCCCAGTTTATTGTCGTGGGGCCCACTGATCCCATCTTGGCCA

CGGTTGGAGAAAACACTACGTTACGCTGCCATCTGTCACCCGAGAAAAATGCTGAGG

ACATGGAGGTGCGGTGGTTCCGGTCTCAGTTCTCCCCCGCAGTGTTTGTGTATAAAG

GTGGCAGAGAGAGAACAGAGGAGCAGATGGAGGAGTACCGAGGAAGAACCACCTTTG

TGAGCAAAGACATCAGCAGGGGCAGCGTGGCCCTGGTCATACACAACATCACAGCCC

AGGAAAACGGCACCTACCGCTGTTACTTCCAAGAAGGCAGGTCCTACGATGAGGCCA

TCCTGCACCTCGTAGTGGCAGGACTAGGCTCTAAGCCCCTCATTTCAATGAGGGGCC

ATGAAGACGGGGGCATCCGGCTGGAGTGCATATCTAGAGGGTGGTACCCAAAGCCCC

TCACAGTGTGGAGGGACCCCTACGGTGGGGTTGCGCCTGCCCTGAAAGAGGTCTCCA

TGCCTGATGCAGACGGCCTCTTCATGGTCACCACGGCTGTGATCATCAGAGACAAGT

CTGTGAGGAACATGTCCTGCTCTATCAACAACACCCTGCTCGGCCAGAAGAAAGAAA

GTGTCATTTTTATTCCAGAATCCTTTATGCCCAGTGTGTCTCCCTGTGCAGTGGCCC

TGCCTATCATTGTGGTTATTCTGATGATACCCATTGCCGTATGCATCTATTGGATCA

ACAAACTCCAAAAGGAAAAAAAGATTCTGTCAGGGGAAAAGGAGTTTGAACGGGAAA

CAAGAGAAATTGCTCTAAAGGAACTGGAGAAAGAACGTGTGCAAAAAGAGGAAGAAC

TTCAAGTAAAAGAGAAACTTCAAGAAGAATTGCGATGGAGAAGAACATTCTTACATG

CTGTTGATGTGGTCCTGGATCCAGACACCGCTCATCCCGATCTCTTCCTGTCAGAGG

ACCGGAGAAGTGTGAGAAGGTGCCCCTTCAGGCACCTAGGGGAGAGCGTGCCTGACA

ACCCAGAGAGATTCGACAGTCAGCCTTGTGTCCTAGGCCGGGAGAGCTTCGCTTCAG

GGAAACATTACTGGGAGGTGGAGGTGGAAAACGTGATTGAGTGGACTGTGGGGGTCT

GTAGAGACAGTGTTGAGAGGAAAGGGGAGGTCCTGCTGATTCCTCAGAATGGCTTCT

GGACCTTGGAGATGCATAAAGGGCAATACCGGGCCGTGTCCTCCCCTGATAGGATTC

TCCCTTTGAAGGAGTCCCTTTGCCGGGTGGGCGTCTTCCTGGACTATGAAGCTGGAG

ATGTCTCCTTCTACAACATGAGGGACAGATCGCACATCTACACATGTCCCCGTTCAG

CCTTTTCCGTGCCTGTGAGGCCCTTCTTCAGGTTGGGGTGTGAGGACAGCCCCATCT

TCATCTGCCCTGCACTCACAGGAGCCAATGGGGTCACGGTGCCTGAAGAGGGCCTGA

CACTTCACAGAGTGGGGACCCACCAGAGCCTATAGAATCAATTCCTTGGTCTCACAG

CCATGTAGACAAGCCCTGGTCATCTCAGCAGCCACCGCACAACACCCCTGGTGGAAG

ACACGCCCTCCTCCCCTCTGGTCACACAAGAGAACATCTTCCAGCTGCCTCTTTCAC

ACCCACTACAGACCTCAGCCCCAGTTTTCTCCTCCTCACTAGGCTGTGTTTTTAGTA

GTTCCTTTGCTTGTAACTATGGGATGGGATCCAGGCATAGGGAACTAGTTGTTACAC

AGCTCCCAGCCAAGAAGAAAGTGTGAGAAGTTGATGGGCAGCAAACCTGCTGTTTAA

CATCAGGGTGACCACATTAAGCCCAGTATTCCAGTTGGCACCAGAAGATATGGACTT

GGAATGAGGCCTACAGGGTTCACCAGGATGTAAGAGGAGAGAGGAATCCACAGGACC

ACCAGAGAGGAGAGGGAACCAGATATGCAGATCAGAGATAGAGGAAGTGGAACCAGA

GAGCTGGGAGGGACCAAGGTTGTAAGGGTGGCTAAGTCCCACCATAACAGCTAAGGG

GACCTGGGAGATGATGGCTCATTTCCACCCAGCCCCAGGATTTCCAGAGCGCACATC

CACAGGCCTGGACCTGGGATGAAGATGAATGAAGAACATGGATGCACGTGGATGTAG

TTTGGCTCAGGTGTCCCTGCAGTTGGCAAGGAGTCAGTACTCAGTCCCTGAGTGTGG

CTGAAATTTGAGGTCCTGGCTGAGCCAAGGAGTAATGGACCAGATCTACCTCAGTAT

TCAAGTTCAGTGGGGACACCAGTGGCTTCAAACTTCCTGGTTTCATGATATCTTGAG

ACGCCTTACAAATGATGGAGGATTCCAAAGAGTTTTTGTTTATTTGGGTTAATATTT

GTTGGTATTTATGGCATTTGAGATTGAAACTAAGAAATGTTTTAATTTATTACCTTT

ACAACATTTATTTACATTACATACATACATTTACAACATTTATTAATTTATATTAAA

ATAGCATGAATAAGCCAATTATAGGTTAATATAAGTAGAATGTTTGTGAAAAATAAG

TATGGTATCCAAAGCAAAATAAATTTTATTGTGAAGTGTG (SEQ ID NO: 97)

>NP_008980.1 butyrophilin subfamily 2 member A1 isoform 1

precursor [Homo sapiens]

MESAAALHFSRPASLLLLLLSLCALVSAQFIVVGPTDPILATVGENTTLRCHLSPEK

NAEDMEVRWFRSQFSPAVEVYKGGRERTEEQMEEYRGRTTFVSKDISRGSVALVIHN

ITAQENGTYRCYFQEGRSYDEAILHLVVAGLGSKPLISMRGHEDGGIRLECISRGWY

PKPLTVWRDPYGGVAPALKEVSMPDADGLFMVTTAVIIRDKSVRNMSCSINNTLLGQ

KKESVIFIPESFMPSVSPCAVALPIIVVILMIPIAVCIYWINKLQKEKKILSGEKEF

ERETREIALKELEKERVQKEEELQVKEKLQEELRWRRTFLHAVDVVLDPDTAHPDLF

LSEDRRSVRRCPFRHLGESVPDNPERFDSQPCVLGRESFASGKHYWEVEVENVIEWT

VGVCRDSVERKGEVLLIPQNGFWTLEMHKGQYRAVSSPDRILPLKESLCRVGVFLDY

EAGDVSFYNMRDRSHIYTCPRSAFSVPVRPFFRLGCEDSPIFICPALTGANGVTVPE

EGLTLHRVGTHQSL (SEQ ID NO: 98)

Human
>NM_001040462.3 Homo sapiens butyrophilin like 8 (BTNL8),

BTNL8
transcript variant 2, mRNA

AGAACAGCGCAGTTTGCCCTCCGCTCACGCAGAGCCTCTCCGTGGCTTCCGCACCTT

GAGCATTAGGCCAGTTCTCCTCTTCTCTCTAATCCATCCGTCACCTCTCCTGTCATC

CGTTTCCATGCCGTGAGGTCCATTCACAGAACACATCCATGGCTCTCATGCTCAGTT

TGGTTCTGAGTCTCCTCAAGCTGGGATCAGGGCAGTGGCAGGTGTTTGGGCCAGACA

AGCCTGTCCAGGCCTTGGTGGGGGAGGACGCAGCATTCTCCTGTTTCCTGTCTCCTA

AGACCAATGCAGAGGCCATGGAAGTGCGGTTCTTCAGGGGCCAGTTCTCTAGCGTGG

TCCACCTCTACAGGGACGGGAAGGACCAGCCATTTATGCAGATGCCACAGTATCAAG

GCAGGACAAAACTGGTGAAGGATTCTATTGCGGAGGGGCGCATCTCTCTGAGGCTGG

AAAACATTACTGTGTTGGATGCTGGCCTCTATGGGTGCAGGATTAGTTCCCAGTCTT

ACTACCAGAAGGCCATCTGGGAGCTACAGGTGTCAGCACTGGGCTCAGTTCCTCTCA

TTTCCATCACGGGATATGTTGATAGAGACATCCAGCTACTCTGTCAGTCCTCGGGCT

GGTTCCCCCGGCCCACAGCGAAGTGGAAAGGTCCACAAGGACAGGATTTGTCCACAG

ACTCCAGGACAAACAGAGACATGCATGGCCTGTTTGATGTGGAGATCTCTCTGACCG

TCCAAGAGAACGCCGGGAGCATATCCTGTTCCATGCGGCATGCTCATCTGAGCCGAG

AGGTGGAATCCAGGGTACAGATAGGAGATACCTTTTTCGAGCCTATATCGTGGCACC

TGGCTACCAAAGTACTGGGAATACTCTGCTGTGGCCTATTTTTTGGCATTGTTGGAC

TGAAGATTTTCTTCTCCAAATTCCAGTGGAAAATCCAGGCGGAACTGGACTGGAGAA

GAAAGCACGGACAGGCAGAATTGAGAGACGCCCGGAAACACGCAGTGGAGGTGACTC

TGGATCCAGAGACGGCTCACCCGAAGCTCTGCGTTTCTGATCTGAAAACTGTAACCC

ATAGAAAAGCTCCCCAGGAGGTGCCTCACTCTGAGAAGAGATTTACAAGGAAGAGTG

TGGTGGCTTCTCAGAGTTTCCAAGCAGGGAAACATTACTGGGAGGTGGACGGAGGAC

ACAATAAAAGGTGGCGCGTGGGAGTGTGCCGGGATGATGTGGACAGGAGGAAGGAGT

ACGTGACTTTGTCTCCCGATCATGGGTACTGGGTCCTCAGACTGAATGGAGAACATT

TGTATTTCACATTAAATCCCCGTTTTATCAGCGTCTTCCCCAGGACCCCACCTACAA

AAATAGGGGTCTTCCTGGACTATGAGTGTGGGACCATCTCCTTCTTCAACATAAATG

ACCAGTCCCTTATTTATACCCTGACATGTCGGTTTGAAGGCTTATTGAGGCCCTACA

TTGAGTATCCGTCCTATAATGAGCAAAATGGAACTCCCATAGTCATCTGCCCAGTCA

CCCAGGAATCAGAGAAAGAGGCCTCTTGGCAAAGGGCCTCTGCAATCCCAGAGACAA

GCAACAGTGAGTCCTCCTCACAGGCAACCACGCCCTTCCTCCCCAGGGGTGAAATGT

AGGATGAATCACATCCCACATTCTTCTTTAGGGATATTAAGGTCTCTCTCCCAGATC

CAAAGTCCCGCAGCAGCCGGCCAAGGTGGCTTCCAGATGAAGGGGGACTGGCCTGTC

CACATGGGAGTCAGGTGTCATGGCTGCCCTGAGCTGGGAGGGAAGAAGGCTGACATT

ACATTTAGTTTGCTCTCACTCCATCTGGCTAAGTGATCTTGAAATACCACCTCTCAG

GTGAAGAACCGTCAGGAATTCCCATCTCACAGGCTGTGGTGTAGATTAAGTAGACAA

GGAATGTGAATAATGCTTAGATCTTATTGATGACAGAGTGTATCCTAATGGTTTGTT

CATTATATTACACTTTCAGTAA (SEQ ID NO: 99)

>NP_001035552.1 butyrophilin-like protein 8 isoform 2

precursor [Homo sapiens]

MALMLSLVLSLLKLGSGQWQVFGPDKPVQALVGEDAAFSCFLSPKTNAEAMEVRFFR

GQFSSVVHLYRDGKDQPFMQMPQYQGRTKLVKDSIAEGRISLRLENITVLDAGLYGC

RISSQSYYQKAIWELQVSALGSVPLISITGYVDRDIQLLCQSSGWFPRPTAKWKGPQ

GQDLSTDSRTNRDMHGLFDVEISLTVQENAGSISCSMRHAHLSREVESRVQIGDTFF

EPISWHLATKVLGILCCGLFFGIVGLKIFFSKFQWKIQAELDWRRKHGQAELRDARK

HAVEVTLDPETAHPKLCVSDLKTVTHRKAPQEVPHSEKRFTRKSVVASQSFQAGKHY

WEVDGGHNKRWRVGVCRDDVDRRKEYVTLSPDHGYWVLRLNGEHLYFTLNPRFISVF

PRTPPTKIGVFLDYECGTISFFNINDQSLIYTLTCRFEGLLRPYIEYPSYNEQNGTP

IVICPVTQESEKEASWQRASAIPETSNSESSSQATTPFLPRGEM (SEQ ID NO:

100)

Human
>NM_006995.5 Homo sapiens butyrophilin subfamily 2 member

BTN2A2
A2 (BTN2A2), transcript variant 1, mRNA

GGGACTTTTTGGACACCCAGAGAACAGGTCCCAGATACCGAGTCCGCAACTCCAAAC

ATCGCGATTAATAGGAGGCCTCTGGTCTCTGCCTGCCCTGGGTGCTCATGGAACCAG

CTGCTGCTCTGCACTTCTCCCTGCCAGCCTCCCTCCTCCTCCTCCTGCTCCTCCTCC

TTCTCAGCCTGTGTGCACTGGTCTCAGCCCAGTTTACTGTCGTGGGGCCAGCTAATC

CCATCCTGGCCATGGTGGGAGAAAACACTACATTACGCTGCCATCTGTCACCCGAGA

AAAATGCTGAGGACATGGAGGTGCGGTGGTTCCGGTCTCAGTTCTCCCCCGCAGTGT

TTGTGTATAAGGGTGGGAGAGAGAGAACAGAGGAGCAGATGGAGGAGTACCGGGGAA

GAATCACCTTTGTGAGCAAAGACATCAACAGGGGCAGCGTGGCCCTGGTCATACATA

ACGTCACAGCCCAGGAGAATGGGATCTACCGCTGTTACTTCCAAGAAGGCAGGTCCT

ACGATGAGGCCATCCTACGCCTCGTGGTGGCAGGCCTTGGGTCTAAGCCCCTCATTG

AAATCAAGGCCCAAGAGGATGGGAGCATCTGGCTGGAGTGCATATCTGGAGGGTGGT

ACCCAGAGCCCCTCACAGTGTGGAGGGACCCCTACGGTGAGGTTGTGCCCGCCCTGA

AGGAGGTTTCCATCGCTGATGCTGACGGCCTCTTCATGGTCACCACAGCTGTGATCA

TCAGAGACAAGTATGTGAGGAATGTGTCCTGCTCTGTCAACAACACCCTGCTCGGCC

AGGAGAAGGAAACTGTCATTTTTATTCCAGAATCCTTTATGCCCAGCGCATCTCCCT

GGATGGTGGCCCTAGCTGTCATCCTGACCGCATCTCCCTGGATGGTGTCCATGACTG

TCATCCTGGCTGTTTTCATCATCTTCATGGCTGTCAGCATCTGTTGCATCAAGAAAC

TTCAAAGGGAAAAAAAGATTCTGTCAGGGGAAAAGAAAGTTGAACAAGAGGAAAAAG

AAATTGCACAGCAACTTCAAGAAGAATTGCGATGGAGAAGAACATTCTTACATGCTG

CTGATGTGGTCCTGGATCCAGACACCGCTCATCCCGAGCTCTTCCTGTCAGAGGACC

GGAGAAGTGTGAGGCGGGGCCCCTACAGGCAGAGAGTGCCTGACAACCCAGAGAGAT

TCGACAGTCAGCCTTGTGTCCTGGGATGGGAGAGCTTCGCCTCAGGGAAACATTACT

GGGAGGTGGAGGTGGAAAACGTGATGGTGTGGACTGTGGGGGTCTGCAGACACAGTG

TTGAGAGGAAAGGGGAGGTCCTGCTGATTCCTCAGAATGGCTTCTGGACCCTGGAGA

TGTTTGGAAACCAATACCGGGCCCTGTCCTCCCCTGAGAGGATTCTCCCTTTGAAGG

AGTCCCTTTGCCGGGTGGGCGTCTTCCTGGACTATGAAGCTGGAGATGTCTCCTTCT

ACAACATGAGGGACAGATCGCACATCTACACATGTCCCCGTTCAGCCTTTACTGTGC

CTGTGAGGCCCTTCTTCAGGTTAGGGTCTGATGACAGCCCCATCTTCATCTGCCCTG

CACTCACAGGAGCCAGTGGGGTCATGGTGCCTGAAGAGGGCCTGAAACTTCACAGAG

TGGGGACCCACCAGAGCCTATAGAATCAATTCCTTGGACTCACAGCCATGCAGATAA

GCCCTGGCCATCTCAGCAGCCACCGCACAACCCCCCTAATGAAAGACACGCCCTCCT

CCCCTCTGGTCACGTAAGAGAACATCTTCCAGCTGCCTTTTTCACACCCACTCCAGC

CCTCTGCCCCAGTTTTCTCCTCCTCACTAGTCTGTGGCTTTAGTAGTTCCTTTGCTT

GTAATTATGGGATGGGATCCAGGCATAGGGAACTAGTTGTTTCATAGCTCCCAGTCA

AAAAGAAAGTGAGAGAAGCTGTTGGGCAGCGAACCTACTGTTTAAAATCAGGATAAC

CACATTAAGCCCAATATGCCAGTTGGCACCAGATGCTGTGGACTTGGAATGAGGCCA

ACAGGGTTCACCAGGATGAGAGAGGAGAGAGGAATCCACAGGACCACCAGAAGGGAG

AGGGAACCAGATATGCAGATCAGAGATAGAGGAAGTGGAACCAGAGAGCTGGGAGGG

ACCAAGGTTGTAAGGATGGCTAAGTCCCACCATAAGAGCTAAAGGGTCCTGGGAGAT

GATGGCTCATTTCCACCCAACCCCAGGATTTCCACAGCACACACCCACAGGCCTGGA

CCTGGGATGAAGATGAATGAAGAACATGGACTCATGTGGATGTGGTTTGGCTCAGAT

GTCCCTGCAATAAACAAGGGGTCAGTACTTAGTCCCTGAGTGTGGTTGAGGTTTGAG

GTCCTGGTCGAGCAGGGCAGTACTGGACCAGGTCTACGTCAGCATTCAGGTTCAATG

GGGACACCAGTGGCTTCAAACTTCCTGATCTAATTATGTTTTTAGACACTTAGAAGT

TATTGAGGACTTTAAAGAGCTTTTGTTTATTTGGGTTAATATTTATGACATTTGACA

TTGAAACAAAAATTTAAAATGTTATCTTTTAATTTATGTTAAAATAGCATTAATAAA

TCAGTTATAGGTTAATGTAGATAGGATGTTTTGTGAAAAAGCAATCTATTGTGTCCA

AATAAAAAAACAAAAAGTGTGACACTGGTTAACTTTTTCCAGATCTCATGTCTGGCT

TAATAAGAGATATTTGTATTATCATATCTGCCTTTGTATTAAACCTATTGGTATATC

ATAGGTCATGTTAGCTCAAAAAAACTTTACTGCACACTACTGAGAGAATGAGATGAA

AAACGATTAATGTTTCATTATTATTATTGTGAAAATATTATTAACACTGGGGACTCC

TTAAGAGTACATCAGAGTTCTCTCTAGGAATCCCAAAACCACATTTTGAAACTAGAA

TAGTGGATCCTGGAAGTTAATCCATGTGCTGGTTAATTTTAGATGTCAACCTGACTG

GATTAAGGAATACCTAGACAGCTGGTACAACATTATTTCTGGGTGTGTCTGTGAGTG

TGTTTCCAGAAGAGATTGGCAAGTGAGTCAGTGGGAAATTCTCTCCTTCTGTTGGCT

GGGTGCCCAATACAACAAAAAGGCAGAGGAAAGGCAAATTCTTCTCTCCTCTGGAGC

TGAGACACTCTTCTTCTTCTGCCCTTGGACATCAGAACTCCTGGCTCTCCGGCCTTT

GAACTTCAGGACTTGTACCAGGAGGCCCTGGGTTCTCAGGCCTTTGGCTTTGGACTG

AGAGTTACACAATCAGCTTCCCTGGTTCTGAGGCTTTCAGACTTAAACTGAGCCATG

CTACCAGCATCCCAGGGTCTCCAGCCTACAGATGAGCTGTTGTGCGATTTCTTAGCC

TCCATAATCACATGAGCCAATCTCCTTAATAAATGCCTGCTCATAGATCTGTATCTA

CATCTATATCTGTATGTGCATCTATATCTATGCCTATATCTATATCTATATCATATT

GATTTTGTCTCTCTGGAGAACCCTGACTAATAAAATGAGGCATCTAAAA (SEQ ID

NO: 101)

>NP_008926.2 butyrophilin subfamily 2 member A2 isoform a

precursor [Homo sapiens]

MEPAAALHFSLPASLLLLLLLLLLSLCALVSAQFTVVGPANPILAMVGENTTLRCHL

SPEKNAEDMEVRWFRSQFSPAVFVYKGGRERTEEQMEEYRGRITFVSKDINRGSVAL

VIHNVTAQENGIYRCYFQEGRSYDEAILRLVVAGLGSKPLIEIKAQEDGSIWLECIS

GGWYPEPLTVWRDPYGEVVPALKEVSIADADGLFMVTTAVIIRDKYVRNVSCSVNNT

LLGQEKETVIFIPESFMPSASPWMVALAVILTASPWMVSMTVILAVFIIFMAVSICC

IKKLQREKKILSGEKKVEQEEKEIAQQLQEELRWRRTFLHAADVVLDPDTAHPELFL

SEDRRSVRRGPYRQRVPDNPERFDSQPCVLGWESFASGKHYWEVEVENVMVWTVGVC

RHSVERKGEVLLIPQNGFWTLEMFGNQYRALSSPERILPLKESLCRVGVFLDYEAGD

VSFYNMRDRSHIYTCPRSAFTVPVRPFFRLGSDDSPIFICPALTGASGVMVPEEGLK

LHRVGTHQSL (SEQ ID NO: 102)

Mouse
>NM_175938.3 Mus musculus butyrophilin, subfamily 2,

BTN2A2
member A2 (Btn2a2), transcript variant 1, mRNA

GAAATTGTGAGACTTGCACGCGGAATGGGTCCTCCGAGGTCTGCTGTCGCGAGTCCC

AGCACTTTGCAAGTAATGGAGAACAGAAAATTCTTTCCTCTCTACTGTAGCAGTTTG

TTCTCTGGTGGCGACTGTGCTCAGCGACAAGTTGGAGAGTAGAGAAAAGGCAAGATA

ATCAGCATTTGAGGGTCAGAGAAGAAAAGAAAACGCAGTTAATTCTAGAAGGTTTTC

TGTCCACACGTGACCTAGGTGACTCTGTCCTGAAGACCTATGGAGCCTACAACTTCC

CTGCGTTCTTGCCCGATAGCCTCCCTTCTCTTCTTCTTGGTCCTCAGCCTGTTTGTG

CTGGTCTCAGCCCAGTTTACTGTCATAGGACCAGCTGAGCCCATCCTGGCCATGGTA

GGAGAGAATACCACACTACACTGCCACCTGTCACCAGAGAGAAATGCCGAAGAGATG

GAGGTGCGGTGGTTCCGGTGGCGTTTCTTCCCTGCAGTGCTGGTGTACAGAGGCCAT

CAAGAGAGACCAGAGGAGCAGATGGTGGCATACCGAGGAAGAACCACCTTCATGCGC

ACAGACATCAGCAAGGGAAGAGTTGCGCTCATTATCCACAATGTCACAGCCTATGAC

AATGGCATCTACTGCTGTTACTTCCAGGAAGGCAGGTCCTATGACCAGGCAACCATG

AAGCTTATGGTGGCAAGCCTTGGCTCTGAGCCACTTATTAAAATGAAGACACTTGAG

GATGGGAGCATCTTGCTAGAGTGCACATCTGAAGGGTGGTACCCAGAGCCCCGAGCT

GTGTGGAGAGACCCCTATGATGAAGTTGTACCTGCCCTGGAGGAGGAGTATACAGCT

GACAGAGAAGGCCTCTTCACAGTCACCATGACTATAATCATCAGGGACTGCTCTGTG

AGGAACATGACCTGCTCTGTCAATAACACTCTGCTCAGCCAGGAGGTGGAAAGTGTG

ATTCTCATTCCAGAATCCTTCGTGCCCAGCCTTCCTCTGTGGATGGTGGCTGTGGCT

GTCACTCTGCCTGTAGTAATGCTGATTCTCCTCACATCTGGAAGCATCTGCCTTGTC

AAGAAACACCGCAGGAAGAAATCTATTCTGTCAGCTGAAAAAGAAGCCGAATATGAA

GAGAAGGAAGCTGCACGGCAACTTCAAGAGGAACTGCGATGGAGACGAACCCTCTTA

CATGCTGCTGACGTGGTCCTGGACCCAGATACAGCTCATCCTGAGCTCTTCCTGTCA

GATGACCAGAGAAGTGTAATACGAGGCTCTTCGAGGCAGAGTGTGCCTGACAACCCT

GAGAGATTTGACTGCCGTCCATGTGTCCTGGGCAGGGAAAGCTTCTCCTCAGGGAAG

CATTACTGGGAGGTGGAGGTGGAAAATGTAATGGTGTGGGCCATTGGTGTTTGTAGA

GACAGCGTGGAAAGGAAAGGGGAGGCCCTGTTGGTTCCTCAGAATGGCTTCTGGACC

CTGGAGATGTTTGGAAGCCAGTATCGAGCCCTGTCCTCCCCAGAAAAGATCATACCT

CTGAAAGAGCGTCTTCACCGTATAGCTGTCTTCCTGGACTGTGAGGGTGGAGATATT

TCTTTCTACAACATGAGAGACAGATCACACATTTACACATGTCCTCCTGTGACTTTC

ACTGGGCCCCTGAGACCCTTCTTTAGGCTTGGTTCTGATGACAGTCCCCTGTTCATC

TGTCCAGCATTCACAGGGGCACAGGGAGTTACAATACCTGAGGGTGGCTTATTCCTA

TATAAGACAAGACCAATTTCTCAGAGCCTTGTAAGGAAGCCATAGCTCTCTACACAG

TACCATCTGTTGGAGACTAGACCCCATGTCCTTCAGATCACATGGAGCATCTTCCAG

CTGCCACCTTCACACATACTTCAGGCCCAGTCCTCAGATTACTACATCATTTCTTCT

AACTATGGGCCTAGGTAGAGCCAGTCTTAGGGGACTATTGCTGTAATACAGCTCTCT

CCTGAGAAGAAAGTGTGAGAAGGGCAGAAAACTTGGAGTTTCAACATGCTGCTCTGG

TCACAGTGGATATCAGGCAAGAGCAACAGGGTGGATCAGGATGTAAGAAGTGAGAAC

TACAGAGGAAGGAGACAGATAAAGATGAATTGAGGCCGAAGATGGAGGAAATGGACT

GAAGAGCTCTGGGGTAAGCCCTATGTGACAGCTGTGGATAGGTAGGAGCTAATGGTC

CATTGATATCCAAAGCCAAAGATTTAAATATCACATAGTGTGTCTGGAGTGTATATC

TGTAGACCTACACATGAGAGGAAACAATCATAGTGATGAACTGGATGTAAGCTGGCT

CAGACGTCCCTACAATAAACACTTCTGAGTTCCATGTCTGTGCTCAGTAAGAATGGC

TTGAGGCTTGCGGTCCATGCTGAGCAGCCAGGTCCACATGAATCGGATTTACTAGAG

TAGGTAGCAGTTCAAGTTCCTTAGGCTCAGGATGTCTTCCTTTCCCCCAAGCCCTTC

CCCCTTCAAGATAGGTCTCACTATGTAGACCAGGCCAGCCTCCACCTCCAGAGTTCT

GGGATTAAAGACAAGCACAACCATGTCCAGTTTATGAGCTTGTGATATATACAGAAG

ATTAAGTTCTGTGTTCTTGGGTTAGTAACTGTTGAGATTTGTTTTGAGTCATGCTCT

CACTGGCTAGCACTGCTCTTGACTTTCTCTCCCCATCTTTTTGTTATTGCTTTTCAA

GACATGGTTTCACTGTGTATTTCTGGCTGATAAGCTGATTTTGAATTCACAGAGATC

TGCCTCTGCCTCCTGAGTGCTGGGATTAAAGGTGTGTTACACTACGCCTGGCTTCAC

TCTATCTCTTCAGTGTGGGGATTATAGGTTTATACTATCATGCCTAACTAATGTCTG

TTGCTGCATATGACATTTGAACTTTAGAACAGAAAAACAACTATACATATTAATATA

TATTAAACTAATAATAAGC (SEQ ID NO: 103)

>NP_787952.2 butyrophilin subfamily 2 member A2 isoform 1

precursor [Mus musculus]

MEPTTSLRSCPIASLLFFLVLSLFVLVSAQFTVIGPAEPILAMVGENTTLHCHLSPE

RNAEEMEVRWFRWRFFPAVLVYRGHQERPEEQMVAYRGRTTFMRTDISKGRVALIIH

NVTAYDNGIYCCYFQEGRSYDQATMKLMVASLGSEPLIKMKTLEDGSILLECTSEGW

YPEPRAVWRDPYDEVVPALEEEYTADREGLFTVTMTIIIRDCSVRNMTCSVNNTLLS

QEVESVILIPESFVPSLPLWMVAVAVTLPVVMLILLTSGSICLVKKHRRKKSILSAE

KEAEYEEKEAARQLQEELRWRRTLLHAADVVLDPDTAHPELFLSDDQRSVIRGSSRQ

SVPDNPERFDCRPCVLGRESFSSGKHYWEVEVENVMVWAIGVCRDSVERKGEALLVP

QNGFWTLEMFGSQYRALSSPEKIIPLKERLHRIAVFLDCEGGDISFYNMRDRSHIYT

CPPVTFTGPLRPFFRLGSDDSPLFICPAFTGAQGVTIPEGGLFLYKTRPISQSLVRK

P (SEQ ID NO: 104)

Human
>NM_001732.3 Homo sapiens butyrophilin subfamily 1 member

BTN1A1
A1 (BTN1A1), mRNA

AGCTTTCTCACTTGGTAGCAGTGGCCTCTTGTGCCTTTTTCTCCAAGATCACCCAGG

CTGAAGCTCCTGAGGGGACTCACATCAGTTATCTTGCTGCTCCAGAAGGGTGGGAGA

TGGCAGTTTTCCCAAGCTCCGGTCTCCCCAGATGTCTGCTCACCCTCATTCTCCTCC

AGCTGCCCAAACTGGATTCAGCTCCCTTTGACGTGATTGGACCCCCGGAGCCCATCC

TGGCCGTTGTGGGTGAGGACGCCGAGCTGCCCTGTCGCCTGTCTCCGAACGCGAGCG

CCGAGCACTTGGAGCTACGCTGGTTCCGAAAGAAGGTTTCGCCGGCCGTGCTGGTGC

ATAGGGACGGGCGCGAGCAGGAAGCCGAGCAGATGCCCGAGTACCGCGGGCGGGCGA

CGCTGGTCCAGGACGGCATCGCCAAGGGGCGCGTGGCCTTGAGGATCCGTGGCGTCA

GAGTCTCTGACGACGGGGAGTACACGTGCTTTTTCAGGGAGGATGGAAGCTACGAAG

AAGCCCTGGTGCATCTGAAGGTGGCTGCTCTGGGCTCTGACCCTCACATCAGTATGC

AAGTTCAAGAGAATGGAGAAATCTGTCTGGAGTGCACCTCAGTGGGATGGTACCCAG

AGCCCCAGGTGCAGTGGAGAACTTCCAAGGGAGAGAAGTTTCCATCTACATCAGAGT

CCAGGAATCCTGATGAAGAAGGTTTGTTCACTGTGGCTGCTTCAGTGATCATCAGAG

ACACTTCTGCGAAAAATGTGTCCTGCTACATCCAGAATCTCCTTCTTGGCCAGGAGA

AGAAAGTAGAAATATCCATACCAGCTTCCTCCCTCCCAAGGCTGACTCCCTGGATAG

TGGCTGTGGCTGTCATCCTGATGGTTCTAGGACTTCTCACCATTGGGTCCATATTTT

TCACTTGGAGACTATACAACGAAAGACCCAGAGAGAGGAGGAATGAATTCAGCTCTA

AAGAGAGACTCCTGGAAGAACTCAAATGGAAAAAGGCTACCTTGCATGCAGTTGATG

TGACTCTGGACCCAGACACAGCTCATCCCCACCTCTTTCTTTATGAGGATTCAAAAT

CTGTTCGACTGGAAGATTCACGTCAGAAACTGCCTGAGAAAACAGAGAGATTTGACT

CCTGGCCCTGTGTGTTGGGCCGTGAGACCTTCACCTCAGGAAGGCATTACTGGGAGG

TGGAGGTGGGAGACAGGACTGACTGGGCAATCGGCGTGTGTAGGGAGAATGTGATGA

AGAAAGGATTTGACCCCATGACTCCTGAGAATGGGTTCTGGGCTGTAGAGTTGTATG

GAAATGGGTACTGGGCCCTCACTCCTCTCCGGACCCCTCTCCCATTGGCAGGGCCCC

CACGCCGGGTTGGGATTTTCCTAGACTATGAATCAGGAGACATCTCCTTCTACAACA

TGAATGATGGATCTGATATCTATACTTTCTCCAATGTCACTTTCTCTGGCCCCCTCC

GGCCCTTCTTTTGCCTATGGTCTAGCGGTAAAAAGCCCCTGACCATCTGCCCAATTG

CTGATGGGCCTGAGAGGGTCACAGTCATTGCTAATGCCCAGGACCTTTCTAAGGAGA

TCCCATTGTCCCCCATGGGGGAGGACTCTGCCCCTAGGGATGCAGACACTCTCCATT

CTAAGCTAATCCCTACCCAACCCAGCCAAGGGGCACCTTAAGGAATATCTCAGCTCA

TCTGTTTTCCTTTCCTCTAACCCCTCTCCTCCATAGCCTTCTGAGGCTTCACCTGCT

AGCTTTACCCAGTCTGTTTCTTCCTGTTGGGTGGCAATTAATTAATCCTGTGAAGGT

TACATTGCTGCTGCTAGAGAGGGTGGGGATTGCACCTTCCAAATCTGTTTCTGTACC

AATATTTGGGGGATGGAGGGGTGACTCAAACTGCTTCTAGTGTTCTCCTAATCCCTT

AAGACTAGAACCTATAGGAAACTACTTGGAGCAAACTCAAAGGACAGATTAGGGATC

GAGATTGGGTCAGGTTAGCATGGGGTTGTGGTTGAAATATCTTGGTATCCAGGATAA

GGGTATGTGGAAAAACAGGCTTTAGGCAAGTGGAAAATTCAAAATGTGCTGTGAAAG

GACAATCTCAGGCTGAAATCCCATAAAGGAACTTGGAGGGAATATTATGATGGAGGG

AAGTGAGGTGAATCCAGGCACATGATGAACACCTGGCTCATCCATAGAGTTTTCACA

GCCTATATCGCAAATTTTCTAAGCCACGTCCTATAGGACAGAGGAGACTGGCCCCAC

TTCTATGGGTCTGAGCTGTGGAAAAGGGAGAGCAGAGAGGAACTGAGATGAGCAGGG

ATGAAGGGTCAGGCAGAAAGCGTGATAGAGGAGAGAATTTTTGACAAAACTCAAAAG

TTGTTTGCACAGCTGTTCTTTGTACCCTGTTCCTTTCTCTGCGCCCTCCTGTTTCTC

CCTTGCCTGGAAGTCATTCCACCCTCAATTTGTTGATCCACAAGTTTCCAGTTGTCC

TCTTCTTTTTGTTATAGCATCTCTCTATTTCAAAGACATTCCTAGAAGTCATCCTTC

AGTGATATCACCACTTGCTCAGTCACCATCTCAACCTTATGTCACCTCAGCCCTCAT

CTCAATGCCCAAACCCCTTACACACACCTTCAGTTAGCTTCAACTGCCTCCGTTTCC

ACACTGTGCACCTTTCACTTTCCCTACCCAGCTTTCCTACATGCTGCCTCTCCTCAG

GGTCCCCTGAATGCTGCATCATTGTGTTCAGTGCAGCTGGACTGATTGCACCTGTGT

ATTTGCCCCTGAGCACTTTCCTTTACACATGTGGCTTGTCTTGCCAATAGACTCCAG

GCTTATACCTTCCATTTCCATCGTATTCTCCAGTTTCCAGGATAGACGTTGCTCATC

GTCTTTACCTAATAAATAAGTTTGTCTGATTGCTGAAA (SEQ ID NO: 105)

>NP_001723.2 butyrophilin subfamily 1 member A1 precursor

[Homo sapiens]

MAVFPSSGLPRCLLTLILLQLPKLDSAPFDVIGPPEPILAVVGEDAELPCRLSPNAS

AEHLELRWFRKKVSPAVLVHRDGREQEAEQMPEYRGRATLVQDGIAKGRVALRIRGV

RVSDDGEYTCFFREDGSYEEALVHLKVAALGSDPHISMQVQENGEICLECTSVGWYP

EPQVQWRTSKGEKFPSTSESRNPDEEGLFTVAASVIIRDTSAKNVSCYIQNLLLGQE

KKVEISIPASSLPRLTPWIVAVAVILMVLGLLTIGSIFFTWRLYNERPRERRNEFSS

KERLLEELKWKKATLHAVDVTLDPDTAHPHLFLYEDSKSVRLEDSRQKLPEKTERFD

SWPCVLGRETFTSGRHYWEVEVGDRTDWAIGVCRENVMKKGFDPMTPENGFWAVELY

GNGYWALTPLRTPLPLAGPPRRVGIFLDYESGDISFYNMNDGSDIYTFSNVTFSGPL

RPFFCLWSSGKKPLTICPIADGPERVTVIANAQDLSKEIPLSPMGEDSAPRDADTLH

SKLIPTQPSQGAP (SEQ ID NO: 106)

Mouse
>NM_013483.3 Mus musculus butyrophilin, subfamily 1,

BTN1A1
member A1 (Btn1a1), mRNA

AACAGCACACAGCCTTCTTCCTTCTGAAGAGCTCTCTCTTTGGCCCCGGGGTGACAA

GCAGCCCTTTTCACTTGATCACTGTGGCTCTGGCTCCCTTTTCCTCTGGGTCTGTCG

AAATCGCCTGAAGCTCTTGGCGGGCTTCATTGCCCCAGTTAGCTCAGAGATGGCAGT

TCCCACCAACTCCTGCCTCCTGGTCTGTCTGCTCACCCTCACTGTCCTACAGCTGCC

CACGCTGGATTCGGCAGCTCCCTTCGATGTGACCGCACCTCAGGAGCCAGTGTTGGC

CCTAGTGGGCTCAGATGCCGAGCTGACCTGTGGCTTTTCCCCAAACGCGAGCTCAGA

ATACATGGAGCTGCTGTGGTTTCGACAGACGAGGTCGACAGCGGTACTTCTATACCG

GGATGGCCAGGAGCAGGAGGGCCAGCAGATGACGGAGTACCGCGGGAGGGCGACGCT

GGCGACAGCCGGGCTTCTAGACGGCCGCGCTACTCTGCTGATCCGAGATGTCAGGGT

CTCAGACCAGGGGGAGTACCGGTGCCTTTTCAAAGACAACGACGACTTCGAGGAGGC

CGCCGTATACCTCAAAGTGGCTGCTGTGGGTTCAGATCCTCAAATCAGTATGACGGT

TCAAGAGAATGGAGAAATGGAGCTGGAGTGCACCTCCTCTGGATGGTACCCAGAGCC

TCAGGTGCAGTGGAGAACAGGCAACAGAGAGATGCTACCATCCACGTCAGAGTCCAA

GAAGCATAATGAGGAAGGCCTGTTCACTGTGGCAGTTTCAATGATGATCAGAGACAG

CTCCATAAAGAACATGTCCTGCTGCATCCAGAATATCCTCCTTGGCCAGGGGAAGGA

AGTAGAGATCTCCTTACCAGCTCCCTTCGTGCCAAGGCTGACTCCCTGGATAGTAGC

TGTGGCTATCATCTTACTGGCCTTAGGATTTCTCACCATTGGGTCCATATTTTTCAC

TTGGAAACTATACAAGGAAAGATCCAGTCTGCGGAAGAAGGAATTTGGCTCTAAAGA

GAGACTTCTGGAAGAACTCAGATGCAAAAAGACTGTACTGCATGAAGTTGACGTGAC

TCTGGATCCAGACACAGCCCACCCCCACCTCTTCCTGTATGAAGATTCAAAGTCAGT

TCGATTGGAAGATTCACGTCAGATCCTGCCTGATAGACCAGAGAGATTTGACTCCTG

GCCCTGTGTGTTGGGCCGTGAGACCTTTACTTCAGGGAGACATTACTGGGAGGTGGA

GGTGGGAGATAGAACTGACTGGGCCATTGGTGTGTGTAGGGAGAATGTGGTGAAGAA

AGGGTTTGACCCCATGACTCCTGATAATGGGTTCTGGGCTGTGGAGTTGTATGGAAA

TGGGTACTGGGCCCTCACCCCACTCAGGACCTCTCTCCGATTAGCAGGGCCCCCTCG

CAGAGTTGGGGTTTTTCTGGACTATGACGCAGGAGACATTTCCTTCTACAACATGAG

TAACGGATCTCTTATCTATACTTTCCCTAGCATCTCTTTCTCTGGCCCCCTCCGTCC

CTTCTTTTGTCTGTGGTCCTGTGGTAAAAAGCCCCTGACCATCTGTTCAACTGCCAA

TGGGCCTGAGAAAGTCACAGTCATTGCTAATGTCCAGGACGACATTCCCTTGTCCCC

GCTGGGGGAAGGCTGTACTTCTGGAGACAAAGACACTCTCCATTCTAAACTGATCCC

GTTCTCACCTAGCCAAGCGGCACCATAACAAATATTCCAGCTTCACGACTTTGCCTT

CCTTTGACTAATCCCTCATGCCCCGAAGCTTCAGCTGTTGGCTTCTTGCAGCCCTGC

TTCTTCCTGGTGGATGGAGATTAATTCACATTGGGAAGGTTAGGTATGTTGCTGCCA

GACAAGGCAGGAAGAAAGGCCATCCTAGTTTGTTTCTGTACTAACAGTGGGGAGGAA

GAGAGCTGAATCCTAAACTATTTCCAGTGCTCATATTCCTTCAGGCCAGAGCCTATA

GAGAAGGATTTGGTACAATCACTCGAGGGATCAAGAGGCAATTAGGTTGGCATGGAA

TTATGGCAGAAACATCTGGAATAGGGGTATGTGGAATGACAGGTTTTAGGTAAGGGA

GAACAAAACCAAACCATAGGATGCTGAGAAAGAAAGATCTTGGACTAAACTCCTAAA

AAAGCACTTAGAGAAGATATGACAGGCAAATGAAGTGAATTTGGTCTAATTTGATAC

ACTTGCCCTGTCCCTAGGGTTTTTCAGTTATATCTCAATTTTTTTGTTGTTAATTAC

ATTTTTGACAGCTTCATACATGTATATAATGCATTCTAATTACTCTCACTCTCCTCT

ATTCTGTCTTATTTCCCTCCCCTCCCCTCATACCTTCCTTCTTGCTTCAAACCTGGC

ACACTGAGTTTAATGGGCTATCATGGGAACATGGATTTAGAGCTTTCCTCTGAGCTC

AAGAGAGCAGGTGTGACTGAATACAGTGATTTCCCCTCTCCTACAATCAATCAGCAG

TCAATAGCTCAGCTGGGAGGGGTAGGGCCTCATGAGACTTCCCCTATCAAGGCTAAA

TGTTGAAAGGGCCAGTTTTTAGCACCTGTGAGATCATGATTGCAAGAGCCCAGAAGA

CAGCATTGCTCGGTCATTCTCCCTACCCTTTGGCTTTTCTGGTCTTTTGTCCTCTCT

TTCAGGATGTGTCTGAACTCTGTATCTTAAGTTTTCTATGTCATGTTCTATAAGATA

GAGGAGACTGGCCCTGCTTGTTTGAGAGCAATGTGAGCAAGCTAGCAAGAGACAGAA

AGGAGCGGAGATGAATAGGGGTAGAGAAAATTTTTAAACAAACCCTCCAGGTGTGTG

TGTGTGTGTGTGTGTCTTCCTCTTTTTTGACCTCCCTAAAGGTCAATCCAACCTCAC

ATTATTGACTCCACTAGGTGGGGGTTCTGTGTGTGTGTGTGTGTGTGTGTGTGTGTG

TGTGTGTGTTTTAAGATAGAGGTTTACTATGTAGCTTAGGCTGGCTTTGAATTCCTG

ATCCTCCTGCCTCTACCTTCCAAGTGCTGGAAACATAGCCACATCCACCACCCCTAT

CCAGTCCACCTGGTTTGATTCAGCAACGCTCAGGTAGCATCGCTGTTTGATCTGGAG

CTGCCAGCTCCCTCGGCCCCCACTGCAATGCTTAACCCCCTCACAGGCACCTTCCCT

TGCCTAACACTGCCATCCTTTTCCACACTGAGCCATTTGCTCAATGTAGCCTACCCA

GGTATCCTGCTTTCTGGTCCCCAAAGTTACACCATGATGCTCAGCACAGCTGGACAG

TTTGTCCCAATTTGTGTGTGTCCTCCTGTTTGTATGGGACTTCTTTTTGTCAATGGC

CTGTGTGTGTATCCAAGCTCTTCCACTTCTATTGTATTTTTCCGGCTTCTAAAACAG

ATGTTACCAAATAAAGAAAGAGAAAGAAAAAAAA (SEQ ID NO: 107)

>NP_038511.1 butyrophilin subfamily 1 member A1 precursor

[Mus musculus]

MAVPTNSCLLVCLLTLTVLQLPTLDSAAPFDVTAPQEPVLALVGSDAELTCGFSPNA

SSEYMELLWFRQTRSTAVLLYRDGQEQEGQQMTEYRGRATLATAGLLDGRATLLIRD

VRVSDQGEYRCLFKDNDDFEEAAVYLKVAAVGSDPQISMTVQENGEMELECTSSGWY

PEPQVQWRTGNREMLPSTSESKKHNEEGLFTVAVSMMIRDSSIKNMSCCIQNILLGQ

GKEVEISLPAPFVPRLTPWIVAVAIILLALGFLTIGSIFFTWKLYKERSSLRKKEFG

SKERLLEELRCKKTVLHEVDVTLDPDTAHPHLFLYEDSKSVRLEDSRQILPDRPERF

DSWPCVLGRETFTSGRHYWEVEVGDRTDWAIGVCRENVVKKGFDPMTPDNGFWAVEL

YGNGYWALTPLRTSLRLAGPPRRVGVFLDYDAGDISFYNMSNGSLIYTFPSISFSGP

LRPFFCLWSCGKKPLTICSTANGPEKVTVIANVQDDIPLSPLGEGCTSGDKDTLHSK

LIPFSPSQAAP (SEQ ID NO: 108)

Human TIGIT
>NM_173799.4 Homo sapiens T cell immunoreceptor with Ig

and ITIM domains (TIGIT), mRNA

ACATCTGCTTCCTGTAGGCCCTCTGGGCAGAAGCATGCGCTGGTGTCTCCTCCTGAT

CTGGGCCCAGGGGCTGAGGCAGGCTCCCCTCGCCTCAGGAATGATGACAGGCACAAT

AGAAACAACGGGGAACATTTCTGCAGAGAAAGGTGGCTCTATCATCTTACAATGTCA

CCTCTCCTCCACCACGGCACAAGTGACCCAGGTCAACTGGGAGCAGCAGGACCAGCT

TCTGGCCATTTGTAATGCTGACTTGGGGTGGCACATCTCCCCATCCTTCAAGGATCG

AGTGGCCCCAGGTCCCGGCCTGGGCCTCACCCTCCAGTCGCTGACCGTGAACGATAC

AGGGGAGTACTTCTGCATCTATCACACCTACCCTGATGGGACGTACACTGGGAGAAT

CTTCCTGGAGGTCCTAGAAAGCTCAGTGGCTGAGCACGGTGCCAGGTTCCAGATTCC

ATTGCTTGGAGCCATGGCCGCGACGCTGGTGGTCATCTGCACAGCAGTCATCGTGGT

GGTCGCGTTGACTAGAAAGAAGAAAGCCCTCAGAATCCATTCTGTGGAAGGTGACCT

CAGGAGAAAATCAGCTGGACAGGAGGAATGGAGCCCCAGTGCTCCCTCACCCCCAGG

AAGCTGTGTCCAGGCAGAAGCTGCACCTGCTGGGCTCTGTGGAGAGCAGCGGGGAGA

GGACTGTGCCGAGCTGCATGACTACTTCAATGTCCTGAGTTACAGAAGCCTGGGTAA

CTGCAGCTTCTTCACAGAGACTGGTTAGCAACCAGAGGCATCTTCTGGAAGATACAC

TTTTGTCTTTGCTATTATAGATGAATATATAAGCAGCTGTACTCTCCATCAGTGCTG

CGTGTGTGTGTGTGTGTGTATGTGTGTGTGTGTTCAGTTGAGTGAATAAATGTCATC

CTCTTCTCCATCTTCATTTCCTTGGCCTTTTCGTTCTATTCCATTTTGCATTATGGC

AGGCCTAGGGTGAGTAACGTGGATCTTGATCATAAATGCAAAATTAAAAAATATCTT

GACCTGGTTTTAAATCTGGCAGTTTGAGCAGATCCTATGTCTCTGAGAGACACATTC

CTCATAATGGCCAGCATTTTGGGCTACAAGGTTTTGTGGTTGATGATGAGGATGGCA

TGACTGCAGAGCCATCCTCATCTCATTTTTTCACGTCATTTTCAGTAACTTTCACTC

ATTCAAAGGCAGGTTATAAGTAAGTCCTGGTAGCAGCCTCTATGGGGAGATTTGAGA

GTGACTAAATCTTGGTATCTGCCCTCAAGAACTTACAGTTAAATGGGGAGACAATGT

TGTCATGAAAAGGTATTATAGTAAGGAGAGAAGGAGACATACACAGGCCTTCAGGAA

GAGACGACAGTTTGGGGTGAGGTAGTTGGCATAGGCTTATCTGTGATGAAGTGGCCT

GGGAGCACCAAGGGGATGTTGAGGCTAGTCTGGGAGGAGCAGGAGTTTTGTCTAGGG

AACTTGTAGGAAATTCTTGGAGCTGAAAGTCCCACAAAGAAGGCCCTGGCACCAAGG

GAGTCAGCAAACTTCAGATTTTATTCTCTGGGCAGGCATTTCAAGTTTCCTTTTGCT

GTGACATACTCATCCATTAGACAGCCTGATACAGGCCTGTAGCCTCTTCCGGCCGTG

TGTGCTGGGGAAGCCCCAGGAAACGCACATGCCCACACAGGGAGCCAAGTCGTAGCA

TTTGGGCCTTGATCTACCTTTTCTGCATCAATACACTCTTGAGCCTTTGAAAAAAGA

ACGTTTCCCACTAAAAAGAAAATGTGGATTTTTAAAATAGGGACTCTTCCTAGGGGA

AAAAGGGGGGCTGGGAGTGATAGAGGGTTTAAAAAATAAACACCTTCAAACTAACTT

CTTCGAACCCTTTTATTCACTCCCTGACGACTTTGTGCTGGGGTTGGGGTAACTGAA

CCGCTTATTTCTGTTTAATTGCATTCAGGCTGGATCTTAGAAGACTTTTATCCTTCC

ACCATCTCTCTCAGAGGAATGAGCGGGGAGGTTGGATTTACTGGTGACTGATTTTCT

TTCATGGGCCAAGGAACTGAAAGAGAATGTGAAGCAAGGTTGTGTCTTGCGCATGGT

TAAAAATAAAGCATTGTCCTGCTTCCTAAGACTTAGACTGGGGTTGACAATTGTTTT

AGCAACAAGACAATTCAACTATTTCTCCTAGGATTTTTATTATTATTATTTTTTCAC

TTTTCTACCAAATGGGTTACATAGGAAGAATGAACTGAAATCTGTCCAGAGCTCCAA

GTCCTTTGGAAGAAAGATTAGATGAACGTAAAAATGTTGTTGTTTGCTGTGGCAGTT

TACAGCATTTTTCTTGCAAAATTAGTGCAAATCTGTTGGAAATAGAACACAATTCAC

AAATTGGAAGTGAACTAAAATGTAATGACGAAAAGGGAGTAGTGTTTTGATTTGGAG

GAGGTGTATATTCGGCAGAGGTTGGACTGAGAGTTGGGTGTTATTTAACATAATTAT

GGTAATTGGGAAACATTTATAAACACTATTGGGATGGTGATAAAATACAAAAGGGCC

TATAGATGTTAGAAATGGGTCAGGTTACTGAAATGGGATTCAATTTGAAAAAAATTT

TTTTAAATAGAACTCACTGAACTAGATTCTCCTCTGAGAACCAGAGAAGACCATTTC

ATAGTTGGATTCCTGGAGACATGCGCTATCCACCACGTAGCCACTTTCCACATGTGG

CCATCAACCACTTAAGATGGGGTTAGTTTAAATCAAGATGTGCTGTTATAATTGGTA

TAAGCATAAAATCACACTAGATTCTGGAGATTTAATATGAATAATAAGAATACTATT

TCAGTAGTTTTGGTATATTGTGTGTCAAAAATGATAATATTTTGGATGTATTGGGTG

AAATAAAATATTAACATTA (SEQ ID NO: 109)

>NP_776160.2 T-cell immunoreceptor with Ig and ITIM

domains precursor [Homo sapiens]

MRWCLLLIWAQGLRQAPLASGMMTGTIETTGNISAEKGGSIILQCHLSSTTAQVTQV

NWEQQDQLLAICNADLGWHISPSFKDRVAPGPGLGLTLQSLTVNDTGEYFCIYHTYP

DGTYTGRIFLEVLESSVAEHGARFQIPLLGAMAATLVVICTAVIVVVALTRKKKALR

IHSVEGDLRRKSAGQEEWSPSAPSPPGSCVQAEAAPAGLCGEQRGEDCAELHDYFNV

LSYRSLGNCSFFTETG (SEQ ID NO: 110)

Mouse TIGIT
>NM_001146325.1:98-823 Mus musculus T cell immunoreceptor

with Ig and ITIM domains (Tigit), mRNA

ATGCATGGCTGGCTGCTCCTGGTCTGGGTCCAGGGGCTGATACAGGCTGCCTTCCTC

GCTACAGGAGCCACAGCAGGCACGATAGATACAAAGAGGAACATCTCTGCAGAGGAA

GGTGGCTCTGTCATCTTACAGTGTCACTTCTCCTCTGACACAGCTGAAGTGACCCAA

GTCGACTGGAAGCAGCAGGACCAGCTTCTGGCCATTTATAGTGTTGACCTGGGGTGG

CATGTCGCTTCAGTCTTCAGTGATCGGGTGGTCCCAGGCCCCAGCCTAGGCCTCACC

TTCCAGTCTCTGACAATGAATGACACGGGAGAGTACTTCTGTACCTATCATACGTAT

CCTGGTGGGATTTACAAGGGGAGAATATTCCTGAAGGTCCAAGAAAGCTCAGTGGCT

CAGTTCCAGACTGCCCCGCTTGGAGGAACCATGGCTGCTGTGCTGGGACTCATTTGC

TTAATGGTCACAGGAGTGACTGTACTGGCTAGAAAGAAGTCTATTAGAATGCATTCT

ATAGAAAGTGGCCTTGGGAGAACAGAAGCGGAGCCACAGGAATGGAACCTGAGGAGT

CTCTCATCCCCTGGAAGCCCTGTCCAGACACAAACTGCCCCTGCTGGTCCCTGTGGA

GAGCAGGCAGAAGATGACTATGCTGACCCACAGGAATACTTTAATGTCCTGAGCTAC

AGAAGCCTAGAGAGCTTCATTGCTGTATCGAAGACTGGCTAA (SEQ ID NO:

111)

>NP_001139797.1 T-cell immunoreceptor with Ig and ITIM

domains precursor [Mus musculus]

MHGWLLLVWVQGLIQAAFLATGATAGTIDTKRNISAEEGGSVILQCHFSSDTAEVTQ

VDWKQQDQLLAIYSVDLGWHVASVFSDRVVPGPSLGLTFQSLTMNDTGEYFCTYHTY

PGGIYKGRIFLKVQESSVAQFQTAPLGGTMAAVLGLICLMVTGVTVLARKKSIRMHS

IESGLGRTEAEPQEWNLRSLSSPGSPVQTQTAPAGPCGEQAEDDYADPQEYFNVLSY

RSLESFIAVSKTG (SEQ ID NO: 112)

Human
>NM_001252.5 Homo sapiens CD70 molecule (CD70),

CD27L
transcript variant 1, mRNA

(CD70)
AGAGAGGGGCAGGCTGGTCCCCTGACAGGTTGAAGCAAGTAGACGCCCAGGAGCCCC

GGGAGGGGGCTGCAGTTTCCTTCCTTCCTTCTCGGCAGCGCTCCGCGCCCCCATCGC

CCCTCCTGCGCTAGCGGAGGTGATCGCCGCGGCGATGCCGGAGGAGGGTTCGGGCTG

CTCGGTGCGGCGCAGGCCCTATGGGTGCGTCCTGCGGGCTGCTTTGGTCCCATTGGT

CGCGGGCTTGGTGATCTGCCTCGTGGTGTGCATCCAGCGCTTCGCACAGGCTCAGCA

GCAGCTGCCGCTCGAGTCACTTGGGTGGGACGTAGCTGAGCTGCAGCTGAATCACAC

AGGACCTCAGCAGGACCCCAGGCTATACTGGCAGGGGGGCCCAGCACTGGGCCGCTC

CTTCCTGCATGGACCAGAGCTGGACAAGGGGCAGCTACGTATCCATCGTGATGGCAT

CTACATGGTACACATCCAGGTGACGCTGGCCATCTGCTCCTCCACGACGGCCTCCAG

GCACCACCCCACCACCCTGGCCGTGGGAATCTGCTCTCCCGCCTCCCGTAGCATCAG

CCTGCTGCGTCTCAGCTTCCACCAAGGTTGTACCATTGCCTCCCAGCGCCTGACGCC

CCTGGCCCGAGGGGACACACTCTGCACCAACCTCACTGGGACACTTTTGCCTTCCCG

AAACACTGATGAGACCTTCTTTGGAGTGCAGTGGGTGCGCCCCTGACCACTGCTGCT

GATTAGGGTTTTTTAAATTTTATTTTATTTTATTTAAGTTCAAGAGAAAAAGTGTAC

ACACAGGGGCCACCCGGGGTTGGGGTGGGAGTGTGGTGGGGGGTAGTGGTGGCAGGA

CAAGAGAAGGCATTGAGCTTTTTCTTTCATTTTCCTATTAAAAAATACAAAAATCA

(SEQ ID NO: 113)

>NP_001243.1 CD70 antigen isoform 1 [Homo sapiens]

MPEEGSGCSVRRRPYGCVLRAALVPLVAGLVICLVVCIQRFAQAQQQLPLESLGWDV

AELQLNHTGPQQDPRLYWQGGPALGRSFLHGPELDKGQLRIHRDGIYMVHIQVTLAI

CSSTTASRHHPTTLAVGICSPASRSISLLRLSFHQGCTIASQRLTPLARGDTLCTNL

TGTLLPSRNTDETFFGVQWVRP (SEQ ID NO: 114)

Mouse CD27L
>NM_011617.2 Mus musculus CD70 antigen (Cd70), mRNA

(CD70)
GAAGGTGCCAAAAGCTCCAGGGGATTTCCCTGCCCTCCGAGAAGAGGCCCAGTTCTT

CCCCTGCATCGGACATCCCCGAGGTTCTAAGGGCAGGTCAAGGCAGGCAGAAGCTTC

AAAAGCTCGGCTGAGGAGGCTACAGCTTCCCGCTGCCTTCAGGCCGCTGCTTCCGTG

CAGGGATGCCGGAGGAAGGTCGCCCTTGCCCCTGGGTTCGCTGGAGCGGGACCGCGT

TCCAGCGCCAATGGCCATGGCTGCTGCTGGTGGTGTTTATTACTGTGTTTTGCTGTT

GGTTTCATTGTAGCGGACTACTCAGTAAGCAGCAACAGAGGCTGCTGGAGCACCCTG

AGCCGCACACAGCTGAGTTACAGCTGAATCTCACAGTTCCTCGGAAGGACCCCACAC

TGCGCTGGGGAGCAGGCCCAGCCTTGGGAAGGTCCTTCACACACGGACCAGAGCTGG

AGGAGGGCCATCTGCGTATCCATCAAGATGGCCTCTACAGGCTGCATATCCAGGTGA

CACTGGCCAACTGCTCTTCCCCAGGCAGCACCCTGCAGCACAGGGCCACCCTGGCTG

TGGGCATCTGCTCCCCCGCTGCGCACGGCATCAGCTTGCTGCGTGGGCGCTTTGGAC

AGGACTGTACAGTGGCATTACAGCGCCTGACATACCTGGTCCACGGAGATGTCCTCT

GTACCAACCTCACCCTGCCTCTGCTGCCGTCCCGCAACGCTGATGAGACCTTCTTTG

GAGTTCAGTGGATATGCCCTTGACCACAACTCCAGGATGACTTGTGAATATTTTTTT

TCTTTTCAAGTTCTACGTATTTATAAATGTATATAGTACACATA (SEQ ID NO:

115)

>NP_035747.1 CD70 antigen [Mus musculus]

MPEEGRPCPWVRWSGTAFQRQWPWLLLVVFITVFCCWFHCSGLLSKQQQRLLEHPEP

HTAELQLNLTVPRKDPTLRWGAGPALGRSFTHGPELEEGHLRIHQDGLYRLHIQVTL

ANCSSPGSTLQHRATLAVGICSPAAHGISLLRGRFGQDCTVALQRLTYLVHGDVLCT

NLTLPLLPSRNADETFFGVQWICP (SEQ ID NO: 116)

Human
>NM_001244.4 Homo sapiens TNF superfamily member 8

CD30L
(TNFSF8), transcript variant 1, mRNA

(CD153)
GTCATTTTCCTACGCGCCCTCTGACATCAGCCACCTTCTCTGTAGCTAGTTTCTCTG

CACACAACTTAATCCCTGGCAATGAAAAATGAACCTCTCCCCCACCCTTGCTGCCGC

CTCTCGCCTCACGCCCCCAGAGAAGAGTTTCTCCACCAGGCAGCAGGTGAAGGTTTT

TTTCCAAGTCACATGATTCAGGATTCAGGGGGAGAATCCTTCTTGGAACAGAGATGG

GCCCAGAACTGAATCAGATGAAGAGAGATAAGGTGTGATGTGGGGAAGACTATATAA

AGAATGGACCCAGGGCTGCAGCAAGCACTCAACGGAATGGCCCCTCCTGGAGACACA

GCCATGCATGTGCCGGCGGGCTCCGTGGCCAGCCACCTGGGGACCACGAGCCGCAGC

TATTTCTATTTGACCACAGCCACTCTGGCTCTGTGCCTTGTCTTCACGGTGGCCACT

ATTATGGTGTTGGTCGTTCAGAGGACGGACTCCATTCCCAACTCACCTGACAACGTC

CCCCTCAAAGGAGGAAATTGCTCAGAAGACCTCTTATGTATCCTGAAAAGGGCTCCA

TTCAAGAAGTCATGGGCCTACCTCCAAGTGGCAAAGCATCTAAACAAAACCAAGTTG

TCTTGGAACAAAGATGGCATTCTCCATGGAGTCAGATATCAGGATGGGAATCTGGTG

ATCCAATTCCCTGGTTTGTACTTCATCATTTGCCAACTGCAGTTTCTTGTACAATGC

CCAAATAATTCTGTCGATCTGAAGTTGGAGCTTCTCATCAACAAGCATATCAAAAAA

CAGGCCCTGGTGACAGTGTGTGAGTCTGGAATGCAAACGAAACACGTATACCAGAAT

CTCTCTCAATTCTTGCTGGATTACCTGCAGGTCAACACCACCATATCAGTCAATGTG

GATACATTCCAGTACATAGATACAAGCACCTTTCCTCTTGAGAATGTGTTGTCCATC

TTCTTATACAGTAATTCAGACTGAACAGTTTCTCTTGGCCTTCAGGAAGAAAGCGCC

TCTCTACCATACAGTATTTCATCCCTCCAAACACTTGGGCAAAAAGAAAACTTTAGA

CCAAGACAAACTACACAGGGTATTAAATAGTATACTTCTCCTTCTGTCTCTTGGAAA

GATACAGCTCCAGGGTTAAAAAGAGAGTTTTTAGTGAAGTATCTTTCAGATAGCAGG

CAGGGAAGCAATGTAGTGTGGTGGGCAGAGCCCCACACAGAATCAGAAGGGATGAAT

GGATGTCCCAGCCCAACCTCTAATTCACTGTATGGTCTTGATCTATTTCTTCTGTTT

TGAGAGCCTCCAGTTAAAATGGGGCTCCAGTACCAGAGCAGCTAGCAACTCTGCCCT

AATGGGAAATGAAGGGGAGCTGGGTGTGAGTGTTTACACTGTGCCCTTCACGGGATA

CTTCTTTTATCTGCAGATGGCCTAATACTTAGTTGTCCAAGTCGCGATCAAGGACTC

TCTCACACAGGAAACTTCCCTATACTGGCAGATACACTTGTGACTGAACCATGCCCA

GTTTATGCCTGTCTGACTGTCACTCTGGCACTAGGAGGCTGATCTTGTACTCCATAT

GACCCCACCCCTAGGAACCCCCAGGGAAAACCAGGCTGGGACAGCCCCCTGTTCCTG

AGATGGAAAGCACAAATTTAATACACCACCACAATGGAAAACAAGTTCAAAGACTTT

TACTTACAGATCCTGGACAGAAAGGGCATAATGAGTCTGAAGGGCAGTCCTCCTTCT

CTAGGTTACATGAGGCAGGAATAAGAAGTCAGACAGAGACAGCAAGACAGTTAACAA

TGTAGGTAAAGAAATAGGGTGTGGTCACTCTCAATTCACTGGCAAATGCCTGAATGG

TCTGTCTGAAGGAAGCAACAGAGAAGTGGGGAATCCAGTCTGCTAGGCAGGAAAGAT

GCCTCTAAGTTCTTGTCTCTGGCCAGAGGTGTGGTATAGAACCAGAAACCCATATCA

AGGGTGACTAAGCCCGGCTTCTGGTATGAGAAATTAAACTTGTATACAAAATGGTTG

CCAAGGCAACATAAAATTATAAGAATTCACTATACCTTCCCCTCCCTGGAACTCAGG

ATCCAAGTCTAGAAAATGAAAGGACTGGGTTTGAATTGCTTCAAAACCTCTTCCATC

TCAGAAGACCAGACCCTGGGAACTGAGATTCCAGACACAATTTTGGAAGCTCTCCAA

CCAAAATAAGGCCCCCCTACCCCAGTATATAATTGAAGACACTAGTAACACCTGACT

GCATCTCATCTCAGCAGAGCCAGAATATGGGGACAAGGTTCAGGGTGCCCTGCTGAA

TGGTGTGAACAGCAGGATCTCAAGGATGTAATGGAAAGAACTACCACACTGACCATC

CAGAATCTAAGAGACCATCTGGGTGTTTGGGAAACCATCTGACGAGGCCTGACTCTA

TTCCAGTTAGATTGACAATAATTGAGCAGCAGGCATTTTTCATTTCTGGTCAGGAAA

GCATTGTGCCTTTAGCAAACAATCAGTGTGCAACAGTGATGTGGTCATCTAGCCAGG

GAATGGCTGCTCCATCCCCTGCATAATATATTCCTGCTTCAAACACCTCTCAGAAAA

CCAGTTCCGCGAGGGTTTTTATATCCCCACAAAGTTGTTGAGAGACAATGATGACCC

TGGAAGTGGGGAGGAGGACTTCTGAGAAACAGCAACCTCTCTCCTGATTGGGGTAGC

CATGAGATTTCTCTAGCTATATCCAACTTGGCATCTGTACATCATCTTTGGAGGAAC

ATCTTATTTGTGGAAGGACCTTGACAAGCCGTTTGAGATGGAATGTAGGCCCTGATG

TTATGCTTCAGTAAAAAAAGATGGAAGCTTCCCTGCTATACCAAAACATGGAGCAAA

ATTTGCATTTTTCTCAAGAAGGAGAGAAAAGGAGTAGGACTCCAGCAAAGTTTGTCA

GAAGGAAAGCTAGAAAAGATTTAAAAGAAAAAAAGAAAGAACAAATCAGCAGTGGTG

GTATGGATGAAAGGGACTTGAGAGAACAAAAATGGCTAAGGGAAAATTTTAAGTCAT

CTGCTGAGCAGTGTGCTGTGTCAACCTCCTCCTAGGTCTCCTCTATGAAATATTTAG

TAAAGTCTACATTTCTCTTTAACTCTTTCTGTGAGTAGATTCTTTGGGAGAAGCAGG

CATTGGAAGAGGTGTTGAATTCAGCAAGCCAAATGGTCTGTGGTAAAAAACAAAACA

GACTTTGAGACTCAAGGCTAAAAAAACAGGGAAATGGCTGGCATTTGAGTCACACAC

TAACTGCATAGGACAAATGAATCTTGCTTAAACCAACTCATGCATTCTTGAAAAGGT

ATATGCAACCCAACTGTGTGTTAACTAAGCAATTTTTTTGCCATCTCACATTCTAAC

TCGAGAAAGATTCCATTTTCATTTTTCACCAACTGTTCTCTGAGCAGAGGTACCTGA

CTTTTGCACTGTGAGTGGTTTCTAATCTCAGTCTCTGTCAAGCAATGCTAAGAAAGC

CAACACCTAAAGACACAAGGGGTACATCATTTAAATGAATAATGTAACCAAACAAAC

AAAAAAAGAGAATAATCATTAATAACTCAACTGATAGATATGTAGGGAGTAGGCAAC

CCAGGAAGTTTAAAACTAAATTCTGTTACTCTTGAGGGTTAACCAGCCCCTGGGAAT

GTTATGAGCAAATGATACTCCATGAGTAAAATGATATCTATGCAAGTAAAATAAATA

ATTTATCTAACTGGGAA (SEQ ID NO: 117)

>NP_001235.1 tumor necrosis factor ligand superfamily

member 8 isoform 1 [Homo sapiens]

MDPGLQQALNGMAPPGDTAMHVPAGSVASHLGTTSRSYFYLTTATLALCLVFTVATI

MVLVVQRTDSIPNSPDNVPLKGGNCSEDLLCILKRAPFKKSWAYLQVAKHLNKTKLS

WNKDGILHGVRYQDGNLVIQFPGLYFIICQLQFLVQCPNNSVDLKLELLINKHIKKQ

ALVTVCESGMQTKHVYQNLSQFLLDYLQVNTTISVNVDTFQYIDTSTEPLENVLSIF

LYSNSD (SEQ ID NO: 118)

Mouse CD30L
>NM_009403.3 Mus musculus tumor necrosis factor (ligand)

(CD153)
superfamily, member 8 (Tnfsf8), mRNA

AGATTAATCCCAGGCGATGAAAAATGAACCTCTCCCCCACCCTTGCAGCCACCCTTC

GCCTCACGCCCCCAGAGAAGAGTTTCTCCATCCGGCAACTGGTGAAGGCTTTTTTCC

AAGTCACATGATCCAGGATGCAGGGGAAAATCCTTCTTGGAACAGAGCTGGGTACAG

AACCGAATCAGATGAGGAGAGATAAGGTGTGATGTGGGACAGACTATATAAAGCATG

GAGCCAGGGCTGCAACAAGCAGGCAGCTGTGGGGCTCCTTCCCCTGACCCAGCCATG

CAGGTGCAGCCCGGCTCGGTAGCCAGCCCCTGGAGAAGCACGAGGCCCTGGAGAAGC

ACAAGTCGCAGCTACTTCTACCTCAGCACCACCGCACTGGTGTGCCTTGTTGTGGCA

GTGGCGATCATTCTGGTACTGGTAGTCCAGAAAAAGGACTCCACTCCAAATACAACT

GAGAAGGCCCCCCTTAAAGGAGGAAATTGCTCAGAGGATCTCTTCTGTACCCTGAAA

AGTACTCCATCCAAGAAGTCATGGGCCTACCTCCAAGTGTCAAAGCATCTCAACAAT

ACCAAACTGTCATGGAACGAAGATGGCACCATCCACGGACTCATATACCAGGACGGG

AACCTGATAGTCCAATTCCCTGGCTTGTACTTCATCGTTTGCCAACTGCAGTTCCTC

GTGCAGTGCTCAAATCATTCTGTGGACCTGACATTGCAGCTCCTCATCAATTCCAAG

ATCAAAAAGCAGACGTTGGTAACAGTGTGTGAGTCTGGAGTTCAGAGTAAGAACATC

TACCAGAATCTCTCTCAGTTTTTGCTGCATTACTTACAGGTCAACTCTACCATATCA

GTCAGGGTGGATAATTTCCAGTATGTGGATACAAACACTTTCCCTCTTGATAATGTG

CTATCCGTCTTCTTATATAGTAGCTCAGACTGAATAGTTGTTCTTAACCTTTATGAA

AATGCTGTCTACCATACAGTACTTCATCTGTCCAAACATGGGCCAAAGAAAATATTA

GGACAACTCAAACTAAGCATGTGAGTTAGTGCACTTCTCTTTCTGTCCTTTGGAAAA

ATACAAACCCAGGATTTAGAAAGTGGAGTCTCCTTCAGATGCACAAACAGGAAAGAA

TGTGATATGTGCACAGAGACCTACTTGGGCACTAGAAGGGGTTGAGTTGTCCCAGTA

TAACCACTAATTCACTGACCTTGAGCCATTTTTCCTTCCCCTGGAACTTGGGGTCTG

AATCTGGAAAAGTAGGAGATGAGATTTACATTTCCCCAATATTTTCTTCAACTCAGA

AGACGAGACTGTGGAGCTGAGCTCCCTACACAGATGAAGGCCTCCCATGGCATGAGG

AAAATGATGGTACCAGTAATGTCTGTCTGACTGTCATCTCAGCAAGTCCTAAGGACT

TCCATGCTGCCTTGTTGAAAGATACTCTAACCTCTTGTAATGGGCAAAGTGATCCTG

TCTCTCACTGAGGGGAGTAGCTGCTGCCATCTCCTGAGACATACATGGAGACATTTT

CTGCCCAAATTCCATTCTGTGTGCAGTTTTTAAGTATTCCCCCAAAAGTTCTTGACA

ATGAGAACTTTGAATGTGGGAAGAGCTTCTGGACAGCAAACATTAACAGCTTCTCCT

GACCAGAGAGACCATGCAAGCTTGGTCTTAGACCCATCAAGCTTGAGGTTTCTACAT

TGTGGGAGACAGACTTTTGACAAACCATTTGAGTTGATGTCTGGGCCCCTGGGAGTT

CTCCTTCAGTAAGGAGAGCAAGCCGTTCTAGTGCTGTGTCAGAGGATGGAGTAAAAT

AGACACTTTTCTGAAGGAAAGGAGAACAAAGTTCCAGAAAAAGGCTAGAAAATGTTT

AAAAGGAAAAGAAAAAACTCAGCTTTTCTCATATGAGAGGAACCCAGAAAAACAACA

CTGAAAAAGAAGAGTGGCTCTGTCAACCTCCTCTTAGGTCTCCTCCTCTCTAGTTAT

TGGGAAAGGAGTTGCATGGTACAGGACAAGTTCTGGTGTGTGGTCAAATAGAATCAG

ATGTGGAGAACACCATGCAGAGAATAAGGAGACCTGTCATATTTGTGTTGTACTCAA

ATGAGGGGCAAATGAATCTTAGGCTAAATCAAATAACAGTCTCTGTCAAGCTGTGCT

CAGAAAGTCAACCACTGAAGATGGAGGGTGAGGCACGTCATTTAAAAAAAGTGAAAT

GTAGC (SEQ ID NO: 119)

>NP_033429.1 tumor necrosis factor ligand superfamily

member 8 [Mus musculus]

MEPGLQQAGSCGAPSPDPAMQVQPGSVASPWRSTRPWRSTSRSYFYLSTTALVCLVV

AVAIILVLVVQKKDSTPNTTEKAPLKGGNCSEDLFCTLKSTPSKKSWAYLQVSKHLN

NTKLSWNEDGTIHGLIYQDGNLIVQFPGLYFIVCQLQFLVQCSNHSVDLTLQLLINS

KIKKQTLVTVCESGVQSKNIYQNLSQFLLHYLQVNSTISVRVDNFQYVDTNTFPLDN

VLSVFLYSSSD (SEQ ID NO: 120)

Human
>NM_005092.4 Homo sapiens TNF superfamily member 18

GITRL
(TNFSF18), mRNA

ATCACTTGTGAATTTTTGTTTTCCACAGCTCTCATTTCTCCAAAAATGTGTTTGAGC

CACTTGGAAAATATGCCTTTAAGCCATTCAAGAACTCAAGGAGCTCAGAGATCATCC

TGGAAGCTGTGGCTCTTTTGCTCAATAGTTATGTTGCTATTTCTTTGCTCCTTCAGT

TGGCTAATCTTTATTTTTCTCCAATTAGAGACTGCTAAGGAGCCCTGTATGGCTAAG

TTTGGACCATTACCCTCAAAATGGCAAATGGCATCTTCTGAACCTCCTTGCGTGAAT

AAGGTGTCTGACTGGAAGCTGGAGATACTTCAGAATGGCTTATATTTAATTTATGGC

CAAGTGGCTCCCAATGCAAACTACAATGATGTAGCTCCTTTTGAGGTGCGGCTGTAT

AAAAACAAAGACATGATACAAACTCTAACAAACAAATCTAAAATCCAAAATGTAGGA

GGGACTTATGAATTGCATGTTGGGGACACCATAGACTTGATATTCAACTCTGAGCAT

CAGGTTCTAAAAAATAATACATACTGGGGTATCATTTTACTAGCAAATCCCCAATTC

ATCTCCTAGAGACTTGATTTGATCTCCTCATTCCCTTCAGCACATGTAGAGGTGCCA

GTGGGTGGATTGGAGGGAGAAGATATTCAATTTCTAGAGTTTGTCTGTCTACAAAAA

TCAACACAAACAGAACTCCTCTGCACGTGAATTTTCATCTATCATGCCTATCTGAAA

GAGACTCAGGGGAAGAGCCAAAGACTTTTGGTTGGATCTGCAGAGATACTTCATTAA

TCCATGATAAAACAAATATGGATGACAGAGGACATGTGCTTTTCAAAGAATCTTTAT

CTAATTCTTGAATTCATGAGTGGAAAAATGGAGTTCTATTCCCATGGAAGATTTACC

TGGTATGCAAAAAGGATCTGGGGCAGTAGCCTGGCTTTGTTCTCATATTCTTGGGCT

GCTGTAATTCATTCTTCTCATACTCCCATCTTCTGAGACCCTCCCAATAAAAAGTAG

ACTGATAGGATGGCCACAGATATGCCTACCATACCCTACTTTAGATATGGTGGTGTT

AGAAGATAAAGAACAATCTGAGAACTATTGGAATAGAGGTACAAGTGGCATAAAATG

GAATGTACGCTATCTGGAAATTTCTCTTGGTTTTATCTTCCTCAGGATGCAGGGTGC

TTTAAAAAGCCTTATCAAAGGAGTCATTCCGAACCCTCACGTAGAGCTTTGTGAGAC

CTTACTGTTGGTGTGTGTGTCTAAACATTGCTAATTGTAAAGAAAGAGTAACCATTA

GTAATCATTAGGTTTAACCCCAGAATGGTATTATCATTACTGGATTATGTCATGTAA

TGATTTAGTATTTTTAGCTAGCTTTCCACAGTTTGCAAAGTGCTTTCGTAAAACAGT

TAGCAATTCTATGAAGTTAATTGGGCAGGCATTTGGGGGAAAATTTTAGTGATGAGA

ATGTGATAGCATAGCATAGCCAACTTTCCTCAACTCATAGGACAAGTGACTACAAGA

GGCAATGGGTAGTCCCCTGCATTGCACTGTCTCAGCTTTAGAATTGTTATTTCTGCT

ATCGTGTTATAAGACTCTAAAACTTAGCGAATTCACTTTTCAGGAAGCATATTCCCC

TTTAGCCCAAGGTGAGCAGAGTGAAGCTACAACAGATCTTTCCTTTACCAGCACACT

TTTTTTTTTTTTCCTGCCTGAATCAGGGAGATCCAGGATGCTGTTCAGGCCTTATCC

CAACCAAATTCCCCTCTTCACTTTGCAGGGCCCATCTTAGTCAAATGTGCTAACTTC

TAAAATAATAAATAGCACTAATTCAAAATTTTTGGACTCTTAAATTAGCTACTTGCA

GGTTCTTGTTGAAAGGTATATAATATTACATTGTAAACAAATTTAAAATATTTATGG

ATATTTGTGAAAAGCTGCATTATGTTAAATAATATTACATGTAAAGCTATTTAAAAG

AGGTTTTTTTTGTATTTTGTTTAACAAAAATTGCTCAGGAGCATGCTAAGCCTGAGG

CCAAGTTGTTTCTTAGTATGACTTTTTAAAAAAACATCTGCTGAGTAGCTACAGGGC

CAAAGACTTGGAGAGCTTGTTTCTGTTGCATTTGCATATCTTCTCAGGAAATTAAAG

TGTGTCATACATATGTGTGTGTGTGTGTGTGTGTGTGTGTATATGTGTGTGTGTATA

TATATGTATACTTATAAAATCTTGGTGTTCTTGATCTTTGTTGTGTTATAAGCAATG

TGTGCTGGAGTGGGCTGGTGCTAGCTTATAAGCACATATTATTAAATTTTCAGGAAT

GTTGCACTTTAGTTATTAACTATAGGCATTCTTGAAATTGGCTATGGTGGGAGTATT

TATACCATGTAAATTGGCAAACACTACACATTTTCCTTTTGGACAGCTAGTTCACCA

GCACACCACTGTGAAACTCTCCTTAATGACTCCTCTCTGCCCCCGCTTCATTCCTGG

GATAATCATAGCAGACTAAGGGAGAAAATGAAATTGTAAAAATTTGGCATACTGGTG

ATTTCTCAGGGCAAGCAGAGGTTACTACAGCTGCAGCTAGAGGGATGACTACCAACA

GGTGACCTTTACATTTTCCTGATGTTATAATTTTAGCTTTTGTTTTCAATGTATACT

GTTTTCCTGTTTCTCCACATAGTAGTCTGCATTTTAAATCTATAATAAAACATGCTG

ATAACTGG (SEQ ID NO: 121)

>NP_005083.3 tumor necrosis factor ligand superfamily

member 18 [Homo sapiens]

MCLSHLENMPLSHSRTQGAQRSSWKLWLFCSIVMLLELCSESWLIFIFLQLETAKEP

CMAKFGPLPSKWQMASSEPPCVNKVSDWKLEILQNGLYLIYGQVAPNANYNDVAPFE

VRLYKNKDMIQTLTNKSKIQNVGGTYELHVGDTIDLIFNSEHQVLKNNTYWGIILLA

NPQFIS (SEQ ID NO: 122)

Mouse GITRL
>NM_183391.3 Mus musculus tumor necrosis factor (ligand)

superfamily, member 18 (Tnfsf18), mRNA

TTGTGGGTATCTGCTTTCCCCAGTTCTCATTCCATCAGAGAACGAGTTCTAGCCTCA

TGGAGGAAATGCCTTTGAGAGAATCAAGTCCTCAAAGGGCAGAGAGGTGCAAGAAGT

CATGGCTCTTGTGCATAGTGGCTCTGTTACTGATGTTGCTCTGTTCTTTGGGTACAC

TGATCTATACTTCACTCAAGCCAACTGCCATCGAGTCCTGCATGGTTAAGTTTGAAC

TATCATCCTCAAAATGGCACATGACATCTCCCAAACCTCACTGTGTGAATACGACAT

CTGATGGGAAGCTGAAGATACTGCAGAGTGGCACATATTTAATCTACGGCCAAGTGA

TTCCTGTGGATAAGAAATACATAAAAGACAATGCCCCCTTCGTAGTACAGATATATA

AAAAGAATGATGTCCTACAAACTCTAATGAATGATTTTCAAATCTTGCCTATAGGAG

GGGTTTATGAACTGCATGCTGGAGATAACATATATCTGAAGTTCAACTCTAAAGACC

ATATTCAGAAAACTAACACATACTGGGGGATCATCTTAATGCCTGATCTACCATTCA

TCTCTTAGAGATTGGGTTTGGTCTCCTCATCTTCTTCTTTGTATCCCGAGATGCTGG

TGGGTGGGTTGGAGGGGGATGATTGATGGCAATGCACACAGTTTGTGAGGGCTTACA

AATTGACACAATCAGAGCCTCTTGGCATATAAAATTTTAGCCCTCATATCTGTCTGA

AGAGGACTCAGCAAATGGGCCAATCCCTAATGTTGGGTCTGCAAATGGACTTGTACA

ATCCATGATAAAAAGGAGTATGGGCCACAGAAGACAGAAACTCTTCCAAAGAATGTC

TTTCTAACCTTGATCCCTGGGTAGAATGAGATCCTGTTTCCATGGGAGTCTTACTTG

GCTTGCAAAAAAGGGTGTAGGGCAGTAGCTTGGCCTTTTTTCCATCATAATTTCCTT

GAGCTGTTTTACCTTAATCCCTCCAAACTCTCACCTTCTGAGAGCCTCCTAATGAAA

CATTGTTAGACTGGTGGGGTGGCCAAGACATGCCAACAACACCCTTCTTTAGAGGTG

GTGTTTTTAGAGGACAGAGAACATTATGAAGCCTAGAGCAGCAGAGGTCAAGATGCC

ACGAAATGGAATTGATCTGGGAATTTTTTTTTTTTTTCATTCTCAGGATGCAGGTTC

ATTCTGAACTTTCCCCTAGGCCTTCATTGCTTTTGTGTGTATGTGTGCATAAATTCT

GCAAATAGAAAAATGAGAGTTTGCACCAGTACTCACTAGATTTAACACCAGAAAGTG

GTACTTTTCTGGCTGTATTATGCCATGATAGCACATTTTCTGTTGGTGTTCCCTAAC

TGACAAGTATAACAGTTTTCCTAAACCACACAACAATGCTATGATGTTAATGGGGTA

GATATTTTTGGAAAAAAATTGCACAGTGAGAACATGGGTAGATGAACCCTAAGACTC

TTACCTCAATTCAGAACTCGCAAGGAGTTAAGTGAGTGGGGTCTTCATTAGACCATT

CACATGGTCTCTGCTTTGAAACTGGCGTTGCTACTGTCTCATTATACATCACTAAAA

TGGAATTAACTCAACTTTGAAATGGATGCATCGACTTTACCCCAAGGTGTCCAGAAT

GAAGCTACAAGACTTTTACCAGCAGTCATTTTCCTTTTGCCTGGAGCAAGAAGATCC

AGGATACTGTTGGAAGAGTTCATCTCACTCAACCATGCTGACTTTCCAAAGTAATAA

TGAACATTTGTGTTCAAATTTTGGATTCTGTTAAATTTAGCCAGCTTGTGAGTTCTT

GTCGAAAAGTATTTTAAACCAATTTACACTATTTATGGGTATTTGTGAAAAGCTATA

TAGTGATATTTTATATATAACTAATTTAAAATATTTTTATTTTATGTAACAAAAATA

CTATAGGCTAAGCTATTTCTTCTTATTTTTTTATGAATACTTGCTGAATTGCCATAG

GGCACAAAGACTCTTCTGTTTGCATATCTTCTCAGGAAATTAAAATTGTATCACATG

TATTTATAAGAA (SEQ ID NO: 123)

>NP_899247.3 tumor necrosis factor ligand superfamily

member 18 [Mus musculus]

MEEMPLRESSPQRAERCKKSWLLCIVALLLMLLCSLGTLIYTSLKPTAIESCMVKFE

LSSSKWHMTSPKPHCVNTTSDGKLKILQSGTYLIYGQVIPVDKKYIKDNAPFVVQIY

KKNDVLQTLMNDFQILPIGGVYELHAGDNIYLKENSKDHIQKTNTYWGIILMPDLPF

IS (SEQ ID NO: 124)

Human
>NM_000074.3 Homo sapiens CD40 ligand (CD40LG), mRNA

CD40L
AATCCTGAGTAAGGTGGCCACTTTGACAGTCTTCTCATGCTGCCTCTGCCACCTTCT

(CD154)
CTGCCAGAAGATACCATTTCAACTTTAACACAGCATGATCGAAACATACAACCAAAC

TTCTCCCCGATCTGCGGCCACTGGACTGCCCATCAGCATGAAAATTTTTATGTATTT

ACTTACTGTTTTTCTTATCACCCAGATGATTGGGTCAGCACTTTTTGCTGTGTATCT

TCATAGAAGGTTGGACAAGATAGAAGATGAAAGGAATCTTCATGAAGATTTTGTATT

CATGAAAACGATACAGAGATGCAACACAGGAGAAAGATCCTTATCCTTACTGAACTG

TGAGGAGATTAAAAGCCAGTTTGAAGGCTTTGTGAAGGATATAATGTTAAACAAAGA

GGAGACGAAGAAAGAAAACAGCTTTGAAATGCAAAAAGGTGATCAGAATCCTCAAAT

TGCGGCACATGTCATAAGTGAGGCCAGCAGTAAAACAACATCTGTGTTACAGTGGGC

TGAAAAAGGATACTACACCATGAGCAACAACTTGGTAACCCTGGAAAATGGGAAACA

GCTGACCGTTAAAAGACAAGGACTCTATTATATCTATGCCCAAGTCACCTTCTGTTC

CAATCGGGAAGCTTCGAGTCAAGCTCCATTTATAGCCAGCCTCTGCCTAAAGTCCCC

CGGTAGATTCGAGAGAATCTTACTCAGAGCTGCAAATACCCACAGTTCCGCCAAACC

TTGCGGGCAACAATCCATTCACTTGGGAGGAGTATTTGAATTGCAACCAGGTGCTTC

GGTGTTTGTCAATGTGACTGATCCAAGCCAAGTGAGCCATGGCACTGGCTTCACGTC

CTTTGGCTTACTCAAACTCTGAACAGTGTCACCTTGCAGGCTGTGGTGGAGCTGACG

CTGGGAGTCTTCATAATACAGCACAGCGGTTAAGCCCACCCCCTGTTAACTGCCTAT

TTATAACCCTAGGATCCTCCTTATGGAGAACTATTTATTATACACTCCAAGGCATGT

AGAACTGTAATAAGTGAATTACAGGTCACATGAAACCAAAACGGGCCCTGCTCCATA

AGAGCTTATATATCTGAAGCAGCAACCCCACTGATGCAGACATCCAGAGAGTCCTAT

GAAAAGACAAGGCCATTATGCACAGGTTGAATTCTGAGTAAACAGCAGATAACTTGC

CAAGTTCAGTTTTGTTTCTTTGCGTGCAGTGTCTTTCCATGGATAATGCATTTGATT

TATCAGTGAAGATGCAGAAGGGAAATGGGGAGCCTCAGCTCACATTCAGTTATGGTT

GACTCTGGGTTCCTATGGCCTTGTTGGAGGGGGCCAGGCTCTAGAACGTCTAACACA

GTGGAGAACCGAAACCCCCCCCCCCCCCCCGCCACCCTCTCGGACAGTTATTCATTC

TCTTTCAATCTCTCTCTCTCCATCTCTCTCTTTCAGTCTCTCTCTCTCAACCTCTTT

CTTCCAATCTCTCTTTCTCAATCTCTCTGTTTCCCTTTGTCAGTCTCTTCCCTCCCC

CAGTCTCTCTTCTCAATCCCCCTTTCTAACACACACACACACACACACACACACACA

CACACACACACACACACACACACAGAGTCAGGCCGTTGCTAGTCAGTTCTCTTCTTT

CCACCCTGTCCCTATCTCTACCACTATAGATGAGGGTGAGGAGTAGGGAGTGCAGCC

CTGAGCCTGCCCACTCCTCATTACGAAATGACTGTATTTAAAGGAAATCTATTGTAT

CTACCTGCAGTCTCCATTGTTTCCAGAGTGAACTTGTAATTATCTTGTTATTTATTT

TTTGAATAATAAAGACCTCTTAACATTA (SEQ ID NO: 125)

>NP_000065.1 CD40 ligand [Homo sapiens]

MIETYNQTSPRSAATGLPISMKIFMYLLTVFLITQMIGSALFAVYLHRRLDKIEDER

NLHEDFVFMKTIQRCNTGERSLSLLNCEEIKSQFEGFVKDIMLNKEETKKENSFEMQ

KGDQNPQIAAHVISEASSKTTSVLQWAEKGYYTMSNNLVTLENGKQLTVKRQGLYYI

YAQVTFCSNREASSQAPFIASLCLKSPGRFERILLRAANTHSSAKPCGQQSIHLGGV

FELQPGASVFVNVTDPSQVSHGTGFTSFGLLKL (SEQ ID NO: 126)

Mouse CD40L
>NM_011616.2 Mus musculus CD40 ligand (Cd401g), mRNA

CTTTCAGTCAGCATGATAGAAACATACAGCCAACCTTCCCCCAGATCCGTGGCAACT

GGACTTCCAGCGAGCATGAAGATTTTTATGTATTTACTTACTGTTTTCCTTATCACC

CAAATGATTGGATCTGTGCTTTTTGCTGTGTATCTTCATAGAAGATTGGATAAGGTC

GAAGAGGAAGTAAACCTTCATGAAGATTTTGTATTCATAAAAAAGCTAAAGAGATGC

AACAAAGGAGAAGGATCTTTATCCTTGCTGAACTGTGAGGAGATGAGAAGGCAATTT

GAAGACCTTGTCAAGGATATAACGTTAAACAAAGAAGAGAAAAAAGAAAACAGCTTT

GAAATGCAAAGAGGTGATGAGGATCCTCAAATTGCAGCACACGTTGTAAGCGAAGCC

AACAGTAATGCAGCATCCGTTCTACAGTGGGCCAAGAAAGGATATTATACCATGAAA

AGCAACTTGGTAATGCTTGAAAATGGGAAACAGCTGACGGTTAAAAGAGAAGGACTC

TATTATGTCTACACTCAAGTCACCTTCTGCTCTAATCGGGAGCCTTCGAGTCAACGC

CCATTCATCGTCGGCCTCTGGCTGAAGCCCAGCAGTGGATCTGAGAGAATCTTACTC

AAGGCGGCAAATACCCACAGTTCCTCCCAGCTTTGCGAGCAGCAGTCTGTTCACTTG

GGCGGAGTGTTTGAATTACAAGCTGGTGCTTCTGTGTTTGTCAACGTGACTGAAGCA

AGCCAAGTGATCCACAGAGTTGGCTTCTCATCTTTTGGCTTACTCAAACTCTGAACA

GTGCGCTGTCCTAGGCTGCAGCAGGGCTGATGCTGGCAGTCTTCCCTATACAGCAAG

TCAGTTAGGACCTGCCCTGTGTTGAACTGCCTATTTATAACCCTAGGATCCTCCTCA

TGGAGAACTATTTATTATGTACCCCCAAGGCACATAGAGCTGGAATAAGAGAATTAC

AGGGCAGGCAAAAATCCCAAGGGACCCTGCTCCCTAAGAACTTACAATCTGAAACAG

CAACCCCACTGATTCAGACAACCAGAAAAGACAAAGCCATAATACACAGATGACAGA

GCTCTGATGAAACAACAGATAACTAATGAGCACAGTTTTGTTGTTTTATGGGTGTGT

CGTTCAATGGACAGTGTACTTGACTTACCAGGGAAGATGCAGAAGGGCAACTGTGAG

CCTCAGCTCACAATCTGTTATGGTTGACCTGGGCTCCCTGCGGCCCTAGTAGG

(SEQ ID NO: 127)

>NP_035746.2 CD40 ligand [Mus musculus]

MIETYSQPSPRSVATGLPASMKIFMYLLTVFLITQMIGSVLFAVYLHRRLDKVEEEV

NLHEDFVFIKKLKRCNKGEGSLSLLNCEEMRRQFEDLVKDITLNKEEKKENSFEMQR

GDEDPQIAAHVVSEANSNAASVLQWAKKGYYTMKSNLVMLENGKQLTVKREGLYYVY

TQVTFCSNREPSSQRPFIVGLWLKPSSGSERILLKAANTHSSSQLCEQQSVHLGGVF

ELQAGASVFVNVTEASQVIHRVGFSSFGLLKL (SEQ ID NO: 128)

Human
>NM_003807.5 Homo sapiens TNF superfamily member 14

LIGHT
(TNFSF14), transcript variant 1, mRNA

(CD258)
CGAGACTCCATCTCAAAAACAAAACAAATAAACGAACAAAAAAACCCACAACGTATT

ATTTTCTTGTTTACGAGGTTTCTTGTCTCTCTGGCTCCACCAGAAGAGGAGCAGGGA

CCCTTCTTGCTGTTGTTCATTGCTGCATCCCCCACACCGAGAGCAGAGCCTGGCATG

GGCAGAAAGTCCTCAGTCGATATTTGGTGGCCCCAAGCGAATGAAGCATCCAAGAAG

GGAAAGCTGGGGGCTCCCCACTGCACTTGCCACCTGAGTCACATTTTCAGAAGCCTC

TGGAAAGTCGTGCACAGCCCAGGAGTGTTGAGCAATTTCGGTTTCCTCTGAGGTTGA

AGGACCCAGGCGTGTCAGCCCTGCTCCAGACACCTTGGGCATGGAGGAGAGTGTCGT

ACGGCCCTCAGTGTTTGTGGTGGATGGACAGACCGACATCCCATTCACGAGGCTGGG

ACGAAGCCACCGGAGACAGTCGTGCAGTGTGGCCCGGGTGGGTCTGGGTCTCTTGCT

GTTGCTGATGGGGGCCGGGCTGGCCGTCCAAGGCTGGTTCCTCCTGCAGCTGCACTG

GCGTCTAGGAGAGATGGTCACCCGCCTGCCTGACGGACCTGCAGGCTCCTGGGAGCA

GCTGATACAAGAGCGAAGGTCTCACGAGGTCAACCCAGCAGCGCATCTCACAGGGGC

CAACTCCAGCTTGACCGGCAGCGGGGGGCCGCTGTTATGGGAGACTCAGCTGGGCCT

GGCCTTCCTGAGGGGCCTCAGCTACCACGATGGGGCCCTTGTGGTCACCAAAGCTGG

CTACTACTACATCTACTCCAAGGTGCAGCTGGGCGGTGTGGGCTGCCCGCTGGGCCT

GGCCAGCACCATCACCCACGGCCTCTACAAGCGCACACCCCGCTACCCCGAGGAGCT

GGAGCTGTTGGTCAGCCAGCAGTCACCCTGCGGACGGGCCACCAGCAGCTCCCGGGT

CTGGTGGGACAGCAGCTTCCTGGGTGGTGTGGTACACCTGGAGGCTGGGGAGAAGGT

GGTCGTCCGTGTGCTGGATGAACGCCTGGTTCGACTGCGTGATGGTACCCGGTCTTA

CTTCGGGGCTTTCATGGTGTGAAGGAAGGAGCGTGGTGCATTGGACATGGGTCTGAC

ACGTGGAGAACTCAGAGGGTGCCTCAGGGGAAAGAAAACTCACGAAGCAGAGGCTGG

GCGTGGTGGCTCTCGCCTGTAATCCCAGCACTTTGGGAGGCCAAGGCAGGCGGATCA

CCTGAGGTCAGGAGTTCGAGACCAGCCTGGCTAACATGGCAAAACCCCATCTCTACT

AAAAATACAAAAATTAGCCGGACGTGGTGGTGCCTGCCTGTAATCCAGCTACTCAGG

AGGCTGAGGCAGGATAATTTTGCTTAAACCCGGGAGGCGGAGGTTGCAGTGAGCCGA

GATCACACCACTGCACTCCAACCTGGGAAACGCAGTGAGACTGTGCCTCAAAAAAAA

GAAAGGAAGAAAAAAGAAAACTCAGGAAACAGATCTTGGGGGACACTCCAGGGAACC

CAAAACTCAAAGGCGGAGAGCTCAGTGGGCACCACCAAGGCGAGATGAAGCCCCAGC

AGGCACCTTCAGAAGACCCACGTAGACTGCAGACCCTGCCACGGACAATACTAAGGA

CAAAAACCCAGAGACTTGGGGTCTGTGGGCCCCCAAACATGGGGTAAAGTTGATTTG

CCTGATATTCAGGAAGAAGGGGTGAGGGGTGGGTATTTATGCTTTTGATTCAGAAGA

AAGTGGGGCTTGGGATTCCAGGGACTTGGCTGGGGGTGGGAAACTTCATCCACTTCC

CTACTCTCATCATGAGTACGGACAGGGTGGGCGGGAGACTGATCATCGGGACTCATC

ATGAAGAGCCCAGCCCCACCCCACATACTCAGATCCCACCCACAGACTGGTGGCCAC

ACCTCAGCCTGGTCACAAAGAGTTACACTCAGATACATGAGCACGGCAGCGTGCTCA

TAACTGTTTAACAACCAGCTGTCCTGGGAGGGGGACAGCTTTGTAATGTTTGCCAAT

TTCCATGGTGTAAATGCTACCACCATGGCTGATTTCATCACTGCCAAGCATAGACAT

CCCTAATAGGACACCACGGATCTGTCCCCGGCATCCGGCCCAGGGCCTGGCACAAAG

CATGCTCTAGGGAAATGCTTGCTGATTGAAAGGAAGGAAGAATGACTCTACAGTCAC

ACCTATGGCATCCCACAAAATCTGTCACATGGCTGCATAATCTCAGCCACTCTTTCA

CAACTATAGACTCATACACGCGAAGTGCCAGATTCATGCACAACCACACAATCACAT

GGAAGTCACAGACGGCATCACAGACAGTCACAGCACTGTGTGTATGTTATAACACAA

GCACACAAAACTCAGACAGCATCCCAGCTACACAGCCACTCCCAGAGGTGTCACCGT

CACACTTGGTAATTAATACTCATTACATTAGACACAGACAGACCAAGTTATAGTCAG

ACCTGGTTACACACATACACACACACAATATCACCATGACAAATACACATTACACAC

ACACAACATCACAATGACAAACACACATTACACACACAACATCACGATGACAAACAC

ACATTACACACACAACATCACGATGACAAACACACATTACACACACATCACAATGAC

AAACACAACATTACACACACACAACATCACAATGACACACACATCACACACACATCA

CAATGACAAACACACAACATTACACACATATACACACAGCCTGAGGGCCCTCCCCAG

CCCAGACTAACACATCTCGGGGTGAGGACCAGACCTTGTTCATAACCCTGGGCCTCT

TAACCACTGATCTTTGAAATAAATGGCAAATAGTTGTACCTGGATCTGTCTAGTTCT

TAGGGGAACAAACTGAAGAAGGGTGGAGAGGAATTGTCAGGCCTAAAGAGCCCCACA

GGGAAAGGGAGGAGTCGGATGGGGGGCAACCATCAGCAACAAGTGGTGGCTCCTAGA

GGCAGAGGGATGGAGGTAATGACCCATGGAGGTCATTCTACAGATGAGGAACCTGGA

CCCAGTTGGCTCAAGTCCATGCAGGAAATGTGGGGGAAACCAGAGACCTCACGTCTG

GATCTGGCTTCCTCTCCAATCCACAATTCCTGAGGAAGTAGAGGCTACATCCCGCAA

GACGCCCTTATTAGACACATCCAGGACAGAATGACAATCCGCCAAGCCAGCTGGAAG

CATAAAACACAGGGAGCTGGTGGGTTGGGTGGGGGCAGATAATGATATGCATACAAA

TTAGAGGGTCTATGCAAATGAGCATTGCTGCAGTGTGGCTGGAGGGAATCCTTAGTT

CCTAGGATTCTAGGATATGGGTTTCGACCCCAGAGGTGAATGTATTGTTATTATTGT

TTTGTTGTTGTTGTGAATGACAAGTCAAAATTTGTGGGTTATTGTTGTTATCGCCAA

TAGTATTCTTGTCATTGTTGCACAGTACAGAGATGAAGGAAACAGATTTTGCAATCA

GATGATCCTGGGTTCTGAGTCCACTCTGCCACTCACCAGCTATATGACCTCCAGCAA

TTTCCATCACCTCTCAATGCTTCAGTTTCCCCATCGGCAAGATGGTTGTGGGGGGAG

AGGAACAACAGTACAGATTCACCATCCCAAATTCAAAATGCTCCAAAATCTAGGCCG

GGCGTGGTGGCTCATACCTGTAATCCCAGCACTTTGGGAGGTCAAAGTGGACGGATA

ACCTGAGGTCAGGAGCTCCAGACCAGCCTGGCCAACATGGCGAAACCCCATCTCTAC

TAAAAATACAAAAAATTACCTGGGTGTGGTGGGGGGCACCTGTAACCCCAGCTACTC

GGGAGGCTGAGGCAGGAACCCTGGAGGTTGAGGTTGCAGTGAGCTGAGATCACACCA

CTGCACTCCAGCCTGGGTGACAGAGCAAGGCTCCCATCTCAAAAAACAAAAAAACAT

GCTCCAAAATCTGAAACTCTTTGAGCCCCAGTGTGATGCCACAAGTGGGAAATTCCA

CAACTCATCACATGTGATAGATTGCAGTGGAAATGCAGGCACACACCACGAAGTTTA

CTCAGCATCCTCAAAGGAAATCCCCGTCAGTAGCTATATATCATTTTCTCACATGCC

AGATAGGTATCTCTCATCTTTTACTGTTAGGTACTTCTGTGTTGAATAGGTGGAGGA

AAATGATTGCTGGTTAGTAGTATATAAATTCAGAGTCAGGAAGGATGGTGATGTCGG

CTGGGTGCAGTGGCTCATGCCTGTAATTCCAATGTGATACCCTACCTTGTGTTTAAC

GTGATTGACTCTCCCTTAGCTGAGAGGGCCAGGCAGACTCTATTTTGGCTTCTTCGC

TTGCAGTCTCTCACCCACCCCCCTTCCTCAAGGACTTAAGCTGACTCCCAGCACATC

CAAGAATGCGATTACTGATAAGATACTGTGACAAGCTATATCCACAATTCCCAGGAA

TTCGTCCGGTTGATAGCACCCAAAGCCCCCGCGTCTATCACCTTGTGATAGATTTAA

AGCCCCTGCACCTGGAACTGTTTGTTTTTCTGTTACCATTTATCTTTTTCACTTTCT

TGCCTGTTTTGCTTCTGTAAAATTGCTTCAGCTCGGCTCCCTCTTCCCCTTCTAAAC

CAAGGTATAAAAAGAAACCTAGCCCCTTCTTTGGGGTGGAGAGAATTTTGAGCGCTA

GCCGTCTCTCAGTCGCCGGCTAATAAAGGACTCCTGAATTAGTCTAA (SEQ ID

NO: 129)

>NP_003798.2 tumor necrosis factor ligand superfamily

member 14 isoform 1 [Homo sapiens]

MEESVVRPSVFVVDGQTDIPFTRLGRSHRRQSCSVARVGLGLLLLLMGAGLAVQGWF

LLQLHWRLGEMVTRLPDGPAGSWEQLIQERRSHEVNPAAHLTGANSSLTGSGGPLLW

ETQLGLAFLRGLSYHDGALVVTKAGYYYIYSKVQLGGVGCPLGLASTITHGLYKRTP

RYPEELELLVSQQSPCGRATSSSRVWWDSSFLGGVVHLEAGEKVVVRVLDERLVRLR

DGTRSYFGAFMV (SEQ ID NO: 130)

Mouse LIGHT
>NM_019418.3 Mus musculus tumor necrosis factor (ligand)

superfamily, member 14 (Tnfsf14), mRNA

TTTTGCAGTTTGCACAGCCCGAGCGTGTTGGGCAATTGTGGTTTCCTCCGGAGAGGA

GGAACTCAGGCTTGCCAACCCTTTCCCTGGGCTTCGGAGCCTCAGCTGCTCTGGCAT

GGAGAGTGTGGTACAGCCTTCAGTGTTTGTGGTGGATGGACAGACGGACATCCCATT

CAGGCGGCTGGAACAGAACCACCGGAGACGGCGCTGTGGCACTGTCCAGGTCAGCCT

GGCCCTGGTGCTGCTGCTAGGTGCTGGGCTGGCCACTCAGGGCTGGTTTCTCCTGAG

ACTGCATCAACGTCTTGGAGACATAGTAGCTCATCTGCCAGATGGAGGCAAAGGCTC

CTGGGAGAAGCTGATACAAGATCAACGATCTCACCAGGCCAACCCAGCAGCACATCT

TACAGGAGCCAACGCCAGCTTGATAGGTATTGGTGGACCTCTGTTATGGGAGACACG

ACTTGGCCTGGCCTTCTTGAGGGGCTTGACGTATCATGATGGGGCCCTGGTGACCAT

GGAGCCCGGTTACTACTATGTGTACTCCAAAGTGCAGCTGAGCGGCGTGGGCTGCCC

CCAGGGGCTGGCCAATGGCCTCCCCATCACCCATGGACTATACAAGCGCACATCCCG

CTACCCGAAGGAGTTAGAACTGCTGGTCAGTCGGCGGTCACCCTGTGGCCGGGCCAA

CAGCTCCCGAGTCTGGTGGGACAGCAGCTTCCTGGGCGGCGTGGTACATCTGGAGGC

TGGGGAAGAGGTGGTGGTCCGCGTGCCTGGAAACCGCCTGGTCAGACCACGTGACGG

CACCAGGTCCTATTTCGGAGCTTTCATGGTCTGAAGGCTGCGGTGACAATGTATTTT

GTGGAGGGACCTCTCCAGGACTCACCTCAAACCCAGCAATAGGGTTTGAAGTCCTCC

CTTTAAGGAGCCCTGAACTCTGCAGTGCTCGGGGCGGTGTAGACTGCTGACCTGCTT

TGGGCAATCTTCAAATCAGAGACCTGGAGACTTGGGGCGTGGAGCCCAGGAGCGAGG

GGTCAGCTCATTTGCCTGATATTCAGGAAGAAAGAATCAAGCTGGGGTATTTATGCT

TCTGATGCAAACACTGAGATTTCGGCTTTCTGGGTTTTGAGCTGGAGGCAAGAAACC

TTCCCAGAGTGTCATCAGGACCATGTTGGCAGGACTTGGGGCTCCAGACTTGCCACC

ACACTCTGGCCTCTCCCATCCATCCGCTGCATTGGTTTCCAGCCACCAAAACAGCAC

TGGCCCCCTGGCTGCAACTGGCCAGGTACGAGCTTCTGAGCACCTACATTCCTCAGG

GACATCTTGATGAGATCTCAGTACTCAGTCCAATGCGCAGCAGCGACAGACATGCCA

GGAATGGTTGGTCAGAAGGGAAGGGAGGAAAGGGAGGAAAGAAGGGAATGCAGAAGA

GAAGGGGGGAAAACAAGACCAAAACAAAACAGCAACAACAAAGCGGCAGGGAGGAGG

TGACACCCTTGGGGATACTTTAGTCAACACACTTAGAACAGATTGTGCCAGGCCTGT

TGGATTCCTGGAGTTGATGGGATCGTGGGAAGGCACAATGGGGAGCAAGTGGGCTTG

GGTTATGGCTCAGTGGGTAAAGTGCAATTATGGGGATCTGAGTTTGAATCCCTGGTA

CCCATATAAAGACACAGATGCGGTGATGGGCACTTGTGACAATGAGATCATCAATAG

GGAATGGAGACAGGAGGGACCTCTGGGGTTCACTGGCCAGGCAGTCTAGCTGAATCA

AAGAGCTCCAAGTTCAGTCGATAGCTCCTGAAGATGACAACTGAGGCTATTCTCCAA

ACCCCACACGCAGGACACATGCGTAATAAATAAAATTTTAAAAAT (SEQ ID NO:

131)

>NP_062291.1 tumor necrosis factor ligand superfamily

member 14 [Mus musculus]

MESVVQPSVFVVDGQTDIPFRRLEQNHRRRRCGTVQVSLALVLLLGAGLATQGWFLL

RLHQRLGDIVAHLPDGGKGSWEKLIQDQRSHQANPAAHLTGANASLIGIGGPLLWET

RLGLAFLRGLTYHDGALVTMEPGYYYVYSKVQLSGVGCPQGLANGLPITHGLYKRTS

RYPKELELLVSRRSPCGRANSSRVWWDSSFLGGVVHLEAGEEVVVRVPGNRLVRPRD

GTRSYFGAFMV (SEQ ID NO: 132)

Human TL1
>NM_005118.4 Homo sapiens TNF superfamily member 15

(TNFSF15), transcript variant 1, mRNA

AGAGGTGCCTCCAGGAGCAGCAGGAGCATGGCCGAGGATCTGGGACTGAGCTTTGGG

GAAACAGCCAGTGTGGAAATGCTGCCAGAGCACGGCAGCTGCAGGCCCAAGGCCAGG

AGCAGCAGCGCACGCTGGGCTCTCACCTGCTGCCTGGTGTTGCTCCCCTTCCTTGCA

GGACTCACCACATACCTGCTTGTCAGCCAGCTCCGGGCCCAGGGAGAGGCCTGTGTG

CAGTTCCAGGCTCTAAAAGGACAGGAGTTTGCACCTTCACATCAGCAAGTTTATGCA

CCTCTTAGAGCAGACGGAGATAAGCCAAGGGCACACCTGACAGTTGTGAGACAAACT

CCCACACAGCACTTTAAAAATCAGTTCCCAGCTCTGCACTGGGAACATGAACTAGGC

CTGGCCTTCACCAAGAACCGAATGAACTATACCAACAAATTCCTGCTGATCCCAGAG

TCGGGAGACTACTTCATTTACTCCCAGGTCACATTCCGTGGGATGACCTCTGAGTGC

AGTGAAATCAGACAAGCAGGCCGACCAAACAAGCCAGACTCCATCACTGTGGTCATC

ACCAAGGTAACAGACAGCTACCCTGAGCCAACCCAGCTCCTCATGGGGACCAAGTCT

GTATGCGAAGTAGGTAGCAACTGGTTCCAGCCCATCTACCTCGGAGCCATGTTCTCC

TTGCAAGAAGGGGACAAGCTAATGGTGAACGTCAGTGACATCTCTTTGGTGGATTAC

ACAAAAGAAGATAAAACCTTCTTTGGAGCCTTCTTACTATAGGAGGAGAGCAAATAT

CATTATATGAAAGTCCTCTGCCACCGAGTTCCTAATTTTCTTTGTTCAAATGTAATT

ATAACCAGGGGTTTTCTTGGGGCCGGGAGTAGGGGGCATTCCACAGGGACAACGGTT

TAGCTATGAAATTTGGGGCCCAAAATTTCACACTTCATGTGCCTTACTGATGAGAGT

ACTAACTGGAAAAAGGCTGAAGAGAGCAAATATATTATTAAGATGGGTTGGAGGATT

GGCGAGTTTCTAAATATTAAGACACTGATCACTAAATGAATGGATGATCTACTCGGG

TCAGGATTGAAAGAGAAATATTTCAACACCTTCCTGCTATACAATGGTCACCAGTGG

TCCAGTTATTGTTCAATTTGATCATAAATTTGCTTCAATTCAGGAGCTTTGAAGGAA

GTCCAAGGAAAGCTCTAGAAAACAGTATAAACTTTCAGAGGCAAAATCCTTCACCAA

TTTTTCCACATACTTTCATGCCTTGCCTAAAAAAAATGAAAAGAGAGTTGGTATGTC

TCATGAATGTTCACACAGAAGGAGTTGGTTTTCATGTCATCTACAGCATATGAGAAA

AGCTACCTTTCTTTTGATTATGTACACAGATATCTAAATAAGGAAGTATGAGTTTCA

CATGTATATCAAAAATACAACAGTTGCTTGTATTCAGTAGAGTTTTCTTGCCCACCT

ATTTTGTGCTGGGTTCTACCTTAACCCAGAAGACACTATGAAAAACAAGACAGACTC

CACTCAAAATTTATATGAACACCACTAGATACTTCCTGATCAAACATCAGTCAACAT

ACTCTAAAGAATAACTCCAAGTCTTGGCCAGGCGCAGTGGCTCACACCTGTAATCCC

AACACTTTGGGAGGCCAAGGTGGGTGGATCATCTAAGGCCGGGAGTTCAAGACCAGC

CTGACCAACGTGGAGAAACCCCATCTCTACTAAAAATACAAAATTAGCCGGGCGTGG

TAGCGCATGGCTGTAATCCTGGCTACTCAGGAGGCCGAGGCAGAAGAATTGCTTGAA

CTGGGGAGGCAGAGGTTGCGGTGAGCCCAGATCGCGCCATTGCACTCCAGCCTGGGT

AACAAGAGCAAAACTCTGTCCAAAAAAAAAAAAATAAAATAATAACTCCAAGCCTTT

AAAAAATATCATCTGAAACTGTTACATCAGATTTCTGGCACTCTACTGACTGTGGAA

GATAGCCAGCTGACTGGAAGATAGCCAGCTGATTAGTTCCCTGAAGAAACCTGAAGA

CAGATACCTGGTTAACTAGATCAACTACACTGCCAACTTGTTTGATGCTGAGAGACA

ATGGACTTATTCCATGGGGGAAGGGAAAAAAGAAGTCAATCACCAAATCTGAAGAAG

TTAACCTAGATCTTTGAGGTTTGATTTGCAACTTTATATGCAGAGTATTATGTGGGT

ATTTTCCCTTAAAATATTCAAAGGGATTTACATATGGGATTAGCTAATGAGCCTAGC

CAAGACCTTCCCTGGAGGACAGGCTGGTCATTGCGGAGGTCCCTTCTGTGCTTCAGT

GGGTTCATATCCTCTAGTCCGTATGATTTTCCTACGCTAATATGTCAAGGGCAGGAG

AGGCAGCTCTGTTCTCCTAGCCTTTGTTGACTTGTCTGCAAAGCAGGAATCTGCCCA

TTTGTTTCCAAGGAGCAAATGAGCTCATGAGAATGAAAGATGTTAACTTCATGCATT

CTGTGCCATCTGAGCATTTCGGTATTATATGACTGGTGACCCTTGGCCCGTATTATA

AATGCTTCCTATCCTGGGAGACCTCATGGATGAGTCTGAGAGGAAATTTGGCACCAA

AATCACTCTCACTCTGGTTTCCAGTAGACTATAGAGGCAGAGAGGCATTTGAGAGGC

TCCTGAGCAAAGTGTCCAGTGTAGCAGGAGCACTTCATTAATATTTATTGAGTTATA

ATTAAATAAAAATTAATTTCTGATTTCTCAGTTTGGAGGTTAAGGCTCTAAATATAT

TTTCTAACCTCTGCTAGGCTAACTTAAGCCAGGCCTTTTTCTTGCCTTCCCTTTCTC

AAAACAGTCAGCACAGACTCAGTGGGAGCACAGAGGAGTGTGGTCACCTCCACCTGG

CTCACCAGAGTCTTCATAGAGGAAGTGAAGCCTGGAAGAAACTGGGCGGGCCCCAGA

TGACCACAGGGAAAGGGCATCTCAGATGGAGGAATTACCCTTGACTTAAAGCAGAAA

AGAAAGATTTCTCAGTAACTCCAAAACTTGCTTGATAGGAGAATATTCCCTCAACCA

ATTCCTAGGACAATATTTATTGGTAGATCAAGAATGTTTCCTCAATAACTCTAGTCT

AGCTCCATGATCAGAACTAACACCCATTAAAAACATAAAATGTTCTTTCTGAACCGG

TCTTCATGGTGCGTGAGAGCACCAAGCAGCTTTGGTATGCAGGAGGAGTTTTGCACA

GAAGAGTGGCCTGCTCAAACCTGCCCACTGTTCTGTAGGTGATCTGGTGGATCTGGA

AATTTATCCCAAGACAGGAATTTCCTAATATTCGAAGACATTTGAGGCTTTGGGAAA

TTCTCTGCTGTGCATTTATTTGGCTCCTGTCATAAGCTTGTTTTTTAAAGAATGTAT

CATAGCTCAAGTTTTTACTGCTGATTTTGTTAAATTCTGTATAGTATATTTTTTACG

GAAAGGCACAGTCAGACATTCCTAATAGGGCTCATGTCAGAACTTCTGTTCCCAAGG

CATTATCTCCATAGCAAAAATTAGTGCACTGTTTTCAAAAGTGAGGTGGGAAAATGC

TTTTAAGATCATGTGATGTTCCCCTAAAAGGGGTTAATGGGGTGTATTCAGGGTTTG

GGAGGGAGGAAGAAGCATGCTTTAGAAAACAGTAAATTTAGGGAGAAAATGCTTTGT

TGGTTAAATGTCACTCAAAAGGCTGAATTCAAATCAATTCCACAAACATTTACTGAG

TACCTACTGCCCCTGGGGACACAGAGATAAATTATTTAGTCTCAGACACACTCATTC

TAACTTCCCAGCACCTCTACTGTCTGCAGATTCTTTAATTTATTTTGGTTGTATTAG

CTAATTAATTCGTAAACTTTAGGCACATGGATCTATTCTCATTATGAAAATGGATGC

CATTTGATTAAGGCTGATGACTAACAAAATGATTTGTGTTTACTCGAAGTGTTTTTT

TAAAAATAGCTACTCAAGGATAGTTTTCCATAAATCAAGAAGGTAAAAAAGTTCCCA

TTTTTTATTGTAGAATCCATTATTTAAACTACATGTAGAGACAGGTTATTATTTGCT

ATATTCAAGTTTGGTCATCAATACCCTTAAAAATATTAGAATTTTATGGATGACCCA

GAAATGCTTTGAAAATCTGTGTTCCTCAGCAAATACAGAGACCATGATCAAAATGCA

CAGAATCACTAACATTTTGATGCTAGCATGGTTTCAGTCTATTTGGCAGAACAGAAT

TGATTATGCTACTAAAATTTCTTTTTCTTTTTTTTTTTTTTTTTTTTTGAGACAGAG

TCTTGCTTTGTCACCCAGGCTGAAGTGCAGTGGCAGGATCTCAGTTCACTGCAACCT

CTGCCTCCCAGGTTCACGCCATTCTCCTGCTTCAGCCTCCCGAGTAGCTGGGACTAC

AGGCTCCCACCACCATGCCCGGCTAATTTTTTGCATTTTTAGTAGAGACGGGGTTTC

ACCGTGTTAGCCAGGATGGTCTCGATCTCCTGACCTCGTGATCCGCCCGCCTCAGCC

TTCCAAAGTGCTGGGATTACAGGCGTGAGCCACTGTGCCCGGACTCTGATTTTTTTT

TTACTAAGGTACAGTAAGAAAAGGGAAAAGTGTACGTTTTCACTTCCTGAAATATGT

CAGGTTGAATCAATAATAGAGCACACCAGAACTCTTGGCTCCATTTCAACCTAAACT

ATTCAGTTCTCATCACCCCAGAGGAAATTCCGCCTCTGTGCTGGTCAGTAATCCCCC

TGGATTATAAAAGTTTAACTAACTCACTGTGCACAAGGCACGGCCATTGCCAACATT

CTCTTGCAAGGTATTTTCCCAAGCCCTTACCCAATTCTGTTTCCATGATTGTGACAT

TGGGGATTAATTCTGCAAGACAGAACTGTTTATATTCTGTACCTTAAAAACACATGC

AAACATCTCTTGCCTTAAGATTTCTGGCTTTCCTATGGCCCAGAGTCCTAGAAGTGT

TTTGATATTTGTAGCAGAATTTTCAAGTGTACATCCTTATCCTGGATATTAACATTT

TTGCATCATATTGGCAGCTGGACCTACAGAGAATTTAGTAGACTGTTAACCTAATAA

GCCTTGAATCCTTTTGCACCAGTGGTGAGAGAATGTGGATCAGAGCCATCACCTCCA

TGCCCCGTCACCCTCTAACAACCACATTTACAACTTCCCCAGCTCTGAGACACACTT

GCCTCCACCCCTTCCATCACCCCATTTTAAGATGAAAATACCACACCAGCCTGGAAG

GAAGAAGTTACTTGCCCAGGGCCACATAGTGAGTTAAGGGCTGATCTAGAGCTAGGA

AGCTGTCTTCCTGAACCATAATCCTGGACTCTTCTAACCTCTCTACTCATCGCAAAT

AGAGTTCATTTTAGTGATTTGAAGGAAGATGGGACAAGTATTTTCAAACACCTGTAG

GACAACATGGAAGTGGGAGGAGACTTCTACTGTAGCTCCCCAGAGAAGAGAGCTAGG

GCTACAGAGTTGCAGTTACAAGGTTGCCCTCTCTGGCTTGATCCCCAAAGGAATTTT

CTACTCCAAAATAGAATTTTTCTAGGATGCTATTTCTCAGTCCCTGGAGATACTCAA

ACAAAGGGCTTGTCACAAGGGTTTTTGTAGAAGCTATTCTTCACAGAGGTTGGGGGA

GAGATTAAGCCAAAGGATCTCTGAGGTCTTTTTCAAATCTATAATTATGTGGCCTTT

TGTTCATTGACTTCCATGTGTTCTAGTTGATCATTACAAACCTGGCAGGCCTTCTCA

AGGGTTCAGTAATTAGCTGTCATTTCCCATTTGTCCAGAGAGTGTCCAACACAAAAT

ACCCCTAAGATCTTGGCCAATAGAGAAATGTCATGGAATTTTAGAAATGACAGTATC

TGCGGAGTTTATTCCAAGTTATATCATTTCAAAGATGAAGAAACCCAGGCTCAGAGG

GAGCCATCACATCCACACCCTGTCACCCTTCGTGGCCAGTGCCAGACAGTAGCTAGT

TGGATGCTAAAAGTAGAATTTAGATATCTTAACAATAAGCCCAGCAGTCTTTCAACT

TCATTCGTAAATCATTTTTGTTTTGAGCATCTGTCACGTGGCAGCACTTGCCTGGAT

ACTGGAGAGCTGAGAAGGAATGCGACAGGCAAGTCCTACTCTCACAGTGTATACATT

CAGGAGGAACAAGACACACAGTGCCAAGTAAATAAAGTAGCTGAACTTCATCAAATG

ATTTTATTCTTAAAGTCATTAAAGCATGTAATGTTCCCCTTTTTTTGTTTCAGGGGT

GTACAGATTGAAGAAGTGTAGGTGTTTATGTGGTTTTAGTGACAAACCCCATGTGCT

TTCATTGATTTTATGTTTTATGTTAAAACATCAACCGCAAGGTAAAATGCATATTGT

ATGTTGTTGGATACGTACTTAACTGGTATGCATCCCATGTCTTTGGGTACTAGTGTA

TGAATTCTAATCTCTGTAAATGAAATGTTGTATGTGTTAATATATTTAATAGATGTA

ACTTAATAAACTGGCATTGAAGACTGAA (SEQ ID NO: 133)

>NP_005109.2 tumor necrosis factor ligand superfamily

member 15 isoform VEGI-251 precursor [Homo sapiens]

MAEDLGLSFGETASVEMLPEHGSCRPKARSSSARWALTCCLVLLPFLAGLTTYLLVS

QLRAQGEACVQFQALKGQEFAPSHQQVYAPLRADGDKPRAHLTVVRQTPTQHFKNQF

PALHWEHELGLAFTKNRMNYTNKFLLIPESGDYFIYSQVTFRGMTSECSEIRQAGRP

NKPDSITVVITKVTDSYPEPTQLLMGTKSVCEVGSNWFQPIYLGAMESLQEGDKLMV

NVSDISLVDYTKEDKTFFGAFLL (SEQ ID NO: 134)

Mouse TL1
>NM_177371.4 Mus musculus tumor necrosis factor (ligand)

superfamily, member 15 (Tnfsf15), mRNA

ATCAGAAGTCTCTCCAAGACAGCAGAAGGATGGCAGAGGAGCTGGGGTTGGGCTTCG

GAGAAGGAGTCCCAGTGGAAGTGCTGCCGGAAGGCTGTAGACACAGGCCAGAGGCCA

GGGCCGGGCTAGCTGCCAGGAGCAAAGCCTGCCTGGCTCTCACCTGCTGCCTGTTGT

CATTTCCCATCCTCGCAGGACTTAGCACCCTCCTAATGGCTGGCCAGCTCCGGGTCC

CCGGAAAAGACTGTATGCTTCGGGCCATAACAGAAGAGAGATCTGAGCCTTCACCAC

AGCAAGTTTACTCACCTCCCAGAGGCAAGCCGAGAGCACACCTGACAATTAAGAAAC

AAACCCCAGCACCACATCTGAAAAATCAGCTCTCTGCTCTACACTGGGAACATGACC

TAGGGATGGCCTTCACCAAGAACGGGATGAAGTACATCAACAAATCCCTGGTGATCC

CAGAGTCAGGAGACTATTTCATCTACTCCCAGATCACATTCCGAGGGACCACATCTG

TGTGTGGTGACATCAGTCGGGGGAGACGACCAAACAAGCCAGACTCCATCACCATGG

TTATCACCAAGGTAGCAGACAGCTACCCTGAGCCTGCCCGCCTACTAACAGGGTCCA

AGTCTGTGTGTGAAATAAGCAACAACTGGTTCCAGTCCCTCTACCTTGGGGCCACGT

TCTCCTTGGAAGAAGGAGACAGACTAATGGTAAACGTCAGTGACATCTCCTTGGTGG

ATTACACAAAAGAAGATAAAACTTTCTTTGGAGCTTTCTTGCTATAAGGAGGAGAAA

ACCATCATTCCAAGGGGCTCCCCTGCCTCCTACTTTCCAATTTCCTTTTCTCATATG

GATCTATAAACAGGGGCTTTAGAGGGATCAGGGAAGGGGACAGTGGTTTAGCTATAT

AATTTAGGAACCCAATATTGATCCGTATATGCCTTATGGACTAAAATAGTAAATGGA

AAACCCAGTACAGCTCATGTTTGATAGAGACCTGCTGGGTTTTAAAAATTGAAACAC

GCCTCATCCAATGGCACAATCTACTGATTTCAGGACAGAACCTTTCCACAGTGCCCT

CTGTCCAAGTCCTTTCTGAATTCAGCAGTTCAGTTAGAGCTGAATTCGACAATGAAC

TTACTCCAGATCAAGAGCTAAAGACAGAATCCAAAGAAAGACTGAGAAAATGATGTT

ATTTCTCCAAGAGGCAATGCATTTCCACATTCTTTTGTGCCTAACCTAAAAAATAAG

AAAGAAGAAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGAAGGA

AGGAAGGAAGGAAGGAAGGAAGGGACAAGAAAAGACAAGACAAGACAAGAAAAAAGA

AAAAATGGTATTTCTCGTGAATATTCCCTAAAAGGAATTGGTTTTCTGCTGTGAAGG

AGAAACCTCACCTTTCTTCTGATTGCATCCTTTAGTATCCAAACATACAAGTGGGAA

TTCCAAATGCACATGGAACATAGAACACTTTTATTATTGTGAGAACATGTTTATTGA

GTACCTACTATGCTCTGGGCACTCAGCCCACAGGACCATGAAGAGAAAGTCAAATTT

TCTTAAAAACTAAATGAATCCTCAATACATACTTCCTGATCAACTACCACTCAAAAT

GTATAACTTCCAAAGTATAACTTCAAGTCAGCCATCTAGGTGGTTTCTTGGGTAAAG

GTGCTTGTCATTAAGCCTGACACCTGGGTTTGACCTCCCAGAACCCAAAAGCTGGAA

GGAGAGAATTGGTTCCCACAAATTATCCTCAAACCCCCATACAAATGATGTGGCATG

CACACATGTAACTAAATAAATAAGTGTAAAACAAAAACAAAAACAAAATTTTAAAGA

AAAATTTCAAGTCCTGAAAGACAGCATTCCTGAGAATGTTGTCTCCATCGTTGTCCA

GTATAGGCTAACCAGCTGATAGAGACACTGAAGGAATTTAAAGACAGACATCAAGTG

AAATGGAGCACTGTAGAAACACTTGATTCATGCCAGGAGTCAATGTACTATGAAGAC

CAACAACAAAGTGTCAGTCATCAAATCCAGAGGTGTTTATCTAGATCTGCTTTCAAG

TTTGGTTTGCAGCCTTTATATAGTCTCTATTACAAATGCTCGTGTCATGGTAGATGC

CACAAGGAGTCAGAGGGTAAACTTAGCCCCAAACCACTGCTGAGCCATCTTCTAGGA

AACCTTCGAAGCAGAGCTGGGCAGCGTGACTCCCACACAATGACTGGGAAAGTAGTA

GCTGATCAAAATTTGTTGAGTAATAATTTGTTAGAAAATTCATCTCCACTGCCTACT

AAACCTAAGTTGTATACTATCTAGCTTCTGCTAAGCCAACTTACATTGGCCACTTTT

TCTGTCTTCAACTTCTTGAAGTATCACAGGTCTCAGTGAGAACACAGGGAAAGGTGA

GGTCGCCTTCCCCTGGTTCTTCATAGGGGAAACCACACCTGAAAGAAGATGAGCAGC

CTGAGGTGACCTGGAGGAAGGGCTGTCTCAGAAGAAGGACTTATTTTTTGGCTTAGG

TCTAAAACCTTGAGAGTAATGCTCACTGGTCAATTGAGGATGCTTTATCAATGACTC

CAGTCTGACTCCAAGGTCAGAAAGGAGAGTGAGATGCTCTCTCTGCCTGCATATATC

TTCATGGAACATGAGAATATTGAGCAACATAGACTTATAGGAAAACACTTGCCCAAA

AGTAGCCAGAGTGACCTGGTCATCCCCTCTACTAAACCCAAGCTTTGTGTCAAGGGC

CTTCAAAGCTGCCCAGAAGTGATCTGGATGGCTTGGGAATTTATCCAAGACAGGAAT

TTCCTGACAGCCAAAGATGCTTGAGTCCTTGTGCCTGACATGCATTTATTTTGCCCC

TGTTTATTGAAGACTGTAACTGTTGATTTGTGGGTATACATACATACATACATACAT

ACATACATACATACATACATATGCTGTCATGAAGGCAGCATCAAACATTACTAATTG

GACTCAAACCAGCATTTCTGTTTCCAAGATACTAAGTATTCCCATGCAAACAGGAGC

ATGCTATTTTTCTAAAGCAAAATGAAAAAAATAGTTTTGAAAGTATATATATGATGG

AGTCAAGTGTAATGGCATACATCTGTAAACCCAGCACATGGGATGCTGAGCCAGGAG

GATTGCCGTGAGTTTGAGGAGAACAGGGGCTAAATAGTAATTTTCAGGAAAGCCTTG

CCTATATAACAAGACCTTGTCTCAAATGAAAAAAAAAAAAAAAATAGACCCCAGGCT

GGTCCTTGGAGATAAGGTAATATATTCATTGGGTGAGGGGGTGTGTGTTTTGGAAAA

TAGTTAATTTAGTGAGAAATGCTTTTCGGTCAAATGCATCTCAAAGGCTGCTGAATT

CAAATCGGGTCTGTAAATGCTTACCTAGTGCTTGCTTGCCCTGGGGACAGAGACATA

AATTACTTTAGTCTCAGATCCACTCGTTCTAACAGATTGGCATCTCCATCGTCTGTG

GAGCTTTTAATCACTCTGTTTGTATTAGCTAATTAATTAGCTAACTTGAGACACACT

GATATTTTCTTATTATAAACATGGGTGCCATTTGATAAAAGACAATCATTAACAAAA

TGGTTCGAATTTCCGCTTAAGTGATCTTCTTTTTTCCTTTTCATTTTTTTTAACTAG

CTAATCAAAGGTAGTTTCCCAAAAATAAATGCAAAGGGAGTATAAAGAAAAAATTCC

CTGTGGTGGGAGCTAGTATTGAAACAACAGTATCAAAGAGGCTGTTACCTACTGGCC

TCAAATTTTGGCAGGAACGCCTTTGAAAATGTTAGAACTTTACGGACAGCCTAGAGG

TGCTTTGAAAAGTCTCTGTTGCCAACAAAAGCCATTAATCAGCATGCGGCACAGGTT

ACTCAAATTTTGACCTTGACTGTTTTTTAGATCTGTTACACAGAACACAACTTCTGG

GCTGTAATCTCTGATGTGGATTTGGTGATTTACTAAGGTACCGTGGGAAACAAGGAA

AGTGTACTTGTACCACATCGTTTCTCAGTGCATGTCAGAGTCTACTCAACAGCAGGG

CATGCCAGAGCCTTGGATACATTCCGGGACAAACTATGTCACTCCTAAGGAAATTCC

AAGTGTGTGCCTGTCAAGCACTCTGGATCATAGAAGCCCACGAGTTCACTGTGCACA

AGGCACAGCCATGGCCAGCACTCTCTTGCATGGTATTTCTCTTAAGCTCTTACTCAA

TCACGGTCCCATGATTGTGACATTGGGGATTAATTGCTTGAGCAGGTTTATTTACAG

TCTGTTCCTTGCAAAATACATGCAGATATGTCTGGCCTCAAAATCCCCTGATTGTTT

TAGGGCTTAGAGAATACTGGGGATGTTTTTGCTGTTTTCAGATGTACTTTATTTAAG

CTTGCAGAATTACCCTGAATATTAACAGTGTTCTAAGATATTGCCTGCTAGCTTCTG

GCTAATTTACTAGTGGTGACAGTATCAGATCAGAGTATCTATATTTATGTCTTGCTA

TTATAGTTAAAACTTCCTGATCTCTGTAACACACTCACCCCTACCTCATCTATCTAC

CCATCTTGTGGATGTAGCTGTGAGAAGACTCACAAGCCCGAGTTGCAGTTACTTTTC

TGAAGCAACATAGTATGTTAATGGAATGGCCAGAACTCTACTCTTGGCACATGGCAC

TGAATTTGATGCCACTAAAAGAAAAATTGAAGGCAGAAATATTTTTTACTATGCATG

GGACAACGTAGAAGAGCAAGGAGACTGCTTACACATGGTGGTCACATCTCTGGCTTC

ATCCCTAAACCAATTTTCTGACCCCAAGTCGATTTTTTTTCATGTAGTTATTGTTCA

TTTTCTGGAAAGAGTCAAGCAAAAAGAGAGTTTTATAGAAACCATTGCATCATGGAG

GTCAGGGGAGGGATTAAGCCAAAGAATTCCTTCTCCAAATCTATAGCCATATGGCCA

CCCTTTGGTGTACTTCTATTTGATCATGACAAACCTGAGAGCCCTGCCCAGAGTTCA

GTGGATCCTAATGAACTCCAAGAGTAATTCATTCCCTCACCAACTCTAGGGGCTTGG

CCAGTGCAGAAAATGTCATGGGATTTTAAAGTTAACATGAGCTGCTATCCAAACTTA

TGTCTCTTTAAGAATGGAGAGACACAGGCCAGGAGAGGTAACATATGAAGCCTGGTA

TTGGGCAGTAGCTTGATGGAGTATTGAGGCTAAAAGTAGACTTCCTGCCCCTGACCA

TACACAACACCCTTTCAGTTTGATCCATGGTGGTCTTATTCTACTTTATTTTGAGCA

CCTGTCACACCTAGTTACTGTCATGCCAAGAAGGTCCATAACAGGCAAATCCTACTC

TGCTGTGTGCACACAAGAGGAAGGAGGCTCACAGTAGCAAGTAAACAGATAAGCAAA

CGTACACGATTTTCGTCTTAAAGTCATTAAGACACACGCGTACCCCTCTTTTGTTTC

AGAGGGTATACAGGCTGAACAGATGTCAGTGTTCACCTATTCTTATTGATAAGCCCC

ATGTGCTTTCATTGGTTGAATGTTTTATGTTAAAACGTCATATTGCCATCGTAAAAT

GCATATTGTATGTTGTTGGGTATATAATTAACTAATATGCATCGCATGTATGAATTC

TAATCTCTGTAAATGAAAACTTATATATGTTAACATATGTAATAGTTATAATTTAAT

AAACTGACACTGGAGACTAC (SEQ ID NO: 135)

>NP_796345.4 tumor necrosis factor ligand superfamily

member 15 [Mus musculus]

MAEELGLGFGEGVPVEVLPEGCRHRPEARAGLAARSKACLALTCCLLSFPILAGLST

LLMAGQLRVPGKDCMLRAITEERSEPSPQQVYSPPRGKPRAHLTIKKQTPAPHLKNQ

LSALHWEHDLGMAFTKNGMKYINKSLVIPESGDYFIYSQITFRGTTSVCGDISRGRR

PNKPDSITMVITKVADSYPEPARLLTGSKSVCEISNNWFQSLYLGATFSLEEGDRLM

VNVSDISLVDYTKEDKTFFGAFLL (SEQ ID NO: 136)

Human CD80
>NM_005191.4 Homo sapiens CD80 molecule (CD80), mRNA

AAACCCTCTGTAAAGTAACAGAAGTTAGAAGGGGAAATGTCGCCTCTCTGAAGATTA

CCCAAAGAAAAAGTGATTTGTCATTGCTTTATAGACTGTAAGAAGAGAACATCTCAG

AAGTGGAGTCTTACCCTGAAATCAAAGGATTTAAAGAAAAAGTGGAATTTTTCTTCA

GCAAGCTGTGAAACTAAATCCACAACCTTTGGAGACCCAGGAACACCCTCCAATCTC

TGTGTGTTTTGTAAACATCACTGGAGGGTCTTCTACGTGAGCAATTGGATTGTCATC

AGCCCTGCCTGTTTTGCACCTGGGAAGTGCCCTGGTCTTACTTGGGTCCAAATTGTT

GGCTTTCACTTTTGACCCTAAGCATCTGAAGCCATGGGCCACACACGGAGGCAGGGA

ACATCACCATCCAAGTGTCCATACCTCAATTTCTTTCAGCTCTTGGTGCTGGCTGGT

CTTTCTCACTTCTGTTCAGGTGTTATCCACGTGACCAAGGAAGTGAAAGAAGTGGCA

ACGCTGTCCTGTGGTCACAATGTTTCTGTTGAAGAGCTGGCACAAACTCGCATCTAC

TGGCAAAAGGAGAAGAAAATGGTGCTGACTATGATGTCTGGGGACATGAATATATGG

CCCGAGTACAAGAACCGGACCATCTTTGATATCACTAATAACCTCTCCATTGTGATC

CTGGCTCTGCGCCCATCTGACGAGGGCACATACGAGTGTGTTGTTCTGAAGTATGAA

AAAGACGCTTTCAAGCGGGAACACCTGGCTGAAGTGACGTTATCAGTCAAAGCTGAC

TTCCCTACACCTAGTATATCTGACTTTGAAATTCCAACTTCTAATATTAGAAGGATA

ATTTGCTCAACCTCTGGAGGTTTTCCAGAGCCTCACCTCTCCTGGTTGGAAAATGGA

GAAGAATTAAATGCCATCAACACAACAGTTTCCCAAGATCCTGAAACTGAGCTCTAT

GCTGTTAGCAGCAAACTGGATTTCAATATGACAACCAACCACAGCTTCATGTGTCTC

ATCAAGTATGGACATTTAAGAGTGAATCAGACCTTCAACTGGAATACAACCAAGCAA

GAGCATTTTCCTGATAACCTGCTCCCATCCTGGGCCATTACCTTAATCTCAGTAAAT

GGAATTTTTGTGATATGCTGCCTGACCTACTGCTTTGCCCCAAGATGCAGAGAGAGA

AGGAGGAATGAGAGATTGAGAAGGGAAAGTGTACGCCCTGTATAACAGTGTCCGCAG

AAGCAAGGGGCTGAAAAGATCTGAAGGTCCCACCTCCATTTGCAATTGACCTCTTCT

GGGAACTTCCTCAGATGGACAAGATTACCCCACCTTGCCCTTTACGTATCTGCTCTT

AGGTGCTTCTTCACTTCAGTTGCTTTGCAGGAAGTGTCTAGAGGAATATGGTGGGCA

CAGAAGTAGCTCTGGTGACCTTGATCAAGGTGTTTTGAAATGCAGAATTCTTGAGTT

CTGGAAGGGACTTTAGAGAATACCAGTGTTATTAATGACAAAGGCACTGAGGCCCAG

GGAGGTGACCCGAATTATAAAGGCCAGCGCCAGAACCCAGATTTCCTAACTCTGGTG

CTCTTTCCCTTTATCAGTTTGACTGTGGCCTGTTAACTGGTATATACATATATATGT

CAGGCAAAGTGCTGCTGGAAGTAGAATTTGTCCAATAACAGGTCAACTTCAGAGACT

ATCTGATTTCCTAATGTCAGAGTAGAAGATTTTATGCTGCTGTTTACAAAAGCCCAA

TGTAATGCATAGGAAGTATGGCATGAACATCTTTAGGAGACTAATGGAAATATTATT

GGTGTTTACCCAGTATTCCATTTTTTTCATTGTGTTCTCTATTGCTGCTCTCTCACT

CCCCCATGAGGTACAGCAGAAAGGAGAACTATCCAAAACTAATTTCCTCTGACATGT

AAGACGAATGATTTAGGTACGTCAAAGCAGTAGTCAAGGAGGAAAGGGATAGTCCAA

AGACTTAACTGGTTCATATTGGACTGATAATCTCTTTAAATGGCTTTATGCTAGTTT

GACCTCATTTGTAAAATATTTATGAGAAAGTTCTCATTTAAAATGAGATCGTTGTTT

ACAGTGTATGTACTAAGCAGTAAGCTATCTTCAAATGTCTAAGGTAGTAACTTTCCA

TAGGGCCTCCTTAGATCCCTAAGATGGCTTTTTCTCCTTGGTATTTCTGGGTCTTTC

TGACATCAGCAGAGAACTGGAAAGACATAGCCAACTGCTGTTCATGTTACTCATGAC

TCCTTTCTCTAAAACTGCCTTCCACAATTCACTAGACCAGAAGTGGACGCAACTTAA

GCTGGGATAATCACATTATCATCTGAAAATCTGGAGTTGAACAGCAAAAGAAGACAA

CATTTCTCAAATGCACATCTCATGGCAGCTAAGCCACATGGCTGGGATTTAAAGCCT

TTAGAGCCAGCCCATGGCTTTAGCTACCTCACTATGCTGCTTCACAAACCTTGCTCC

TGTGTAAAACTATATTCTCAGTGTAGGGCAGAGAGGTCTAACACCAACATAAGGTAC

TAGCAGTGTTTCCCGTATTGACAGGAATACTTAACTCAATAATTCTTTTCTTTTCCA

TTTAGTAACAGTTGTGATGACTATGTTTCTATTCTAAGTAATTCCTGTATTCTACAG

CAGATACTTTGTCAGCAATACTAAGGGAAGAAACAAAGTTGAACCGTTTCTTTAATA

A (SEQ ID NO: 137)

>NP_005182.1 T-lymphocyte activation antigen CD80

precursor [Homo sapiens]

MGHTRRQGTSPSKCPYLNFFQLLVLAGLSHFCSGVIHVTKEVKEVATLSCGHNVSVE

ELAQTRIYWQKEKKMVLTMMSGDMNIWPEYKNRTIFDITNNLSIVILALRPSDEGTY

ECVVLKYEKDAFKREHLAEVTLSVKADFPTPSISDFEIPTSNIRRIICSTSGGFPEP

HLSWLENGEELNAINTTVSQDPETELYAVSSKLDFNMTTNHSFMCLIKYGHLRVNQT

FNWNTTKQEHFPDNLLPSWAITLISVNGIFVICCLTYCFAPRCRERRRNERLRRESV

RPV (SEQ ID NO: 138)

Mouse CD80
>NM_009855.2 Mus musculus CD80 antigen (Cd80), transcript

variant 2, mRNA

GAGTTTTATACCTCAATAGACTCTTACTAGTTTCTCTTTTTCAGGTTGTGAAACTCA

ACCTTCAAAGACACTCTGTTCCATTTCTGTGGACTAATAGGATCATCTTTAGCATCT

GCCGGGTGGATGCCATCCAGGCTTCTTTTTCTACATCTCTGTTTCTCGATTTTTGTG

AGCCTAGGAGGTGCCTAAGCTCCATTGGCTCTAGATTCCTGGCTTTCCCCATCATGT

TCTCCAAAGCATCTGAAGCTATGGCTTGCAATTGTCAGTTGATGCAGGATACACCAC

TCCTCAAGTTTCCATGTCCAAGGCTCATTCTTCTCTTTGTGCTGCTGATTCGTCTTT

CACAAGTGTCTTCAGATGTTGATGAACAACTGTCCAAGTCAGTGAAAGATAAGGTAT

TGCTGCCTTGCCGTTACAACTCTCCTCATGAAGATGAGTCTGAAGACCGAATCTACT

GGCAAAAACATGACAAAGTGGTGCTGTCTGTCATTGCTGGGAAACTAAAAGTGTGGC

CCGAGTATAAGAACCGGACTTTATATGACAACACTACCTACTCTCTTATCATCCTGG

GCCTGGTCCTTTCAGACCGGGGCACATACAGCTGTGTCGTTCAAAAGAAGGAAAGAG

GAACGTATGAAGTTAAACACTTGGCTTTAGTAAAGTTGTCCATCAAAGCTGACTTCT

CTACCCCCAACATAACTGAGTCTGGAAACCCATCTGCAGACACTAAAAGGATTACCT

GCTTTGCTTCCGGGGGTTTCCCAAAGCCTCGCTTCTCTTGGTTGGAAAATGGAAGAG

AATTACCTGGCATCAATACGACAATTTCCCAGGATCCTGAATCTGAATTGTACACCA

TTAGTAGCCAACTAGATTTCAATACGACTCGCAACCACACCATTAAGTGTCTCATTA

AATATGGAGATGCTCACGTGTCAGAGGACTTCACCTGGGAAAAACCCCCAGAAGACC

CTCCTGATAGCAAGAACACACTTGTGCTCTTTGGGGCAGGATTCGGCGCAGTAATAA

CAGTCGTCGTCATCGTTGTCATCATCAAATGCTTCTGTAAGCACAGAAGCTGTTTCA

GAAGAAATGAGGCAAGCAGAGAAACAAACAACAGCCTTACCTTCGGGCCTGAAGAAG

CATTAGCTGAACAGACCGTCTTCCTTTAGTTCTTCTCTGTCCATGTGGGATACATGG

TATTATGTGGCTCATGAGGTACAATCTTTCTTTCAGCACCGTGCTAGCTGATCTTTC

GGACAACTTGACACAAGATAGAGTTAACTGGGAAGAGAAAGCCTTGAATGAGGATTT

CTTTCCATCAGGAAGCCTACGGGCAAGTTTGCTGGGCCTTTGATTGCTTGATGACTG

AAGTGGAAAGGCTGAGCCCACTGTGGGTGGTGCTAGCCCTGGGCAGGGGCAGGTGAC

CCTGGGTGGTATAAGAAAAAGAGCTGTCACTAAAAGGAGAGGTGCCTAGTCTTACTG

CAACTTGATATGTCATGTTTGGTTGGTGTCTGTGGGAGGCCTGCCCTTTTCTGAAGA

GAAGTGGTGGGAGAGTGGATGGGGTGGGGGCAGAGGAAAAGTGGGGGAGAGGGCCTG

GGAGGAGAGGAGGGAGGGGGACGGGGTGGGGGTGGGGAAAACTATGGTTGGGATGTA

AAAACGATAATAATATAAATATTAAATAAAAAGAGAGTATTGAGCAAA (SEQ ID

NO: 139)

>NP_033985.3 T-lymphocyte activation antigen CD80

precursor [Mus musculus]

MACNCQLMQDTPLLKFPCPRLILLFVLLIRLSQVSSDVDEQLSKSVKDKVLLPCRYN

SPHEDESEDRIYWQKHDKVVLSVIAGKLKVWPEYKNRTLYDNTTYSLIILGLVLSDR

GTYSCVVQKKERGTYEVKHLALVKLSIKADESTPNITESGNPSADTKRITCFASGGF

PKPRFSWLENGRELPGINTTISQDPESELYTISSQLDENTTRNHTIKCLIKYGDAHV

SEDFTWEKPPEDPPDSKNTLVLFGAGFGAVITVVVIVVIIKCFCKHRSCFRRNEASR

ETNNSLTFGPEEALAEQTVFL (SEQ ID NO: 140)

Human CD86
>NM_175862.5 Homo sapiens CD86 molecule (CD86),

transcript variant 1, mRNA

AGTCATTGCCGAGGAAGGCTTGCACAGGGTGAAAGCTTTGCTTCTCTGCTGCTGTAA

CAGGGACTAGCACAGACACACGGATGAGTGGGGTCATTTCCAGATATTAGGTCACAG

CAGAAGCAGCCAAAATGGATCCCCAGTGCACTATGGGACTGAGTAACATTCTCTTTG

TGATGGCCTTCCTGCTCTCTGGTGCTGCTCCTCTGAAGATTCAAGCTTATTTCAATG

AGACTGCAGACCTGCCATGCCAATTTGCAAACTCTCAAAACCAAAGCCTGAGTGAGC

TAGTAGTATTTTGGCAGGACCAGGAAAACTTGGTTCTGAATGAGGTATACTTAGGCA

AAGAGAAATTTGACAGTGTTCATTCCAAGTATATGGGCCGCACAAGTTTTGATTCGG

ACAGTTGGACCCTGAGACTTCACAATCTTCAGATCAAGGACAAGGGCTTGTATCAAT

GTATCATCCATCACAAAAAGCCCACAGGAATGATTCGCATCCACCAGATGAATTCTG

AACTGTCAGTGCTTGCTAACTTCAGTCAACCTGAAATAGTACCAATTTCTAATATAA

CAGAAAATGTGTACATAAATTTGACCTGCTCATCTATACACGGTTACCCAGAACCTA

AGAAGATGAGTGTTTTGCTAAGAACCAAGAATTCAACTATCGAGTATGATGGTGTTA

TGCAGAAATCTCAAGATAATGTCACAGAACTGTACGACGTTTCCATCAGCTTGTCTG

TTTCATTCCCTGATGTTACGAGCAATATGACCATCTTCTGTATTCTGGAAACTGACA

AGACGCGGCTTTTATCTTCACCTTTCTCTATAGAGCTTGAGGACCCTCAGCCTCCCC

CAGACCACATTCCTTGGATTACAGCTGTACTTCCAACAGTTATTATATGTGTGATGG

TTTTCTGTCTAATTCTATGGAAATGGAAGAAGAAGAAGCGGCCTCGCAACTCTTATA

AATGTGGAACCAACACAATGGAGAGGGAAGAGAGTGAACAGACCAAGAAAAGAGAAA

AAATCCATATACCTGAAAGATCTGATGAAGCCCAGCGTGTTTTTAAAAGTTCGAAGA

CATCTTCATGCGACAAAAGTGATACATGTTTTTAATTAAAGAGTAAAGCCCATACAA

GTATTCATTTTTTCTACCCTTTCCTTTGTAAGTTCCTGGGCAACCTTTTTGATTTCT

TCCAGAAGGCAAAAAGACATTACCATGAGTAATAAGGGGGCTCCAGGACTCCCTCTA

AGTGGAATAGCCTCCCTGTAACTCCAGCTCTGCTCCGTATGCCAAGAGGAGACTTTA

ATTCTCTTACTGCTTCTTTTCACTTCAGAGCACACTTATGGGCCAAGCCCAGCTTAA

TGGCTCATGACCTGGAAATAAAATTTAGGACCAATACCTCCTCCAGATCAGATTCTT

CTCTTAATTTCATAGATTGTGTTTTTTTTTTAAATAGACCTCTCAATTTCTGGAAAA

CTGCCTTTTATCTGCCCAGAATTCTAAGCTGGTGCCCCACTGAATTTTGTGTGTACC

TGTGACTAAACAACTACCTCCTCAGTCTGGGTGGGACTTATGTATTTATGACCTTAT

AGTGTTAATATCTTGAAACATAGAGATCTATGTACTGTAATAGTGTGATTACTATGC

TCTAGAGAAAAGTCTACCCCTGCTAAGGAGTTCTCATCCCTCTGTCAGGGTCAGTAA

GGAAAACGGTGGCCTAGGGTACAGGCAACAATGAGCAGACCAACCTAAATTTGGGGA

AATTAGGAGAGGCAGAGATAGAACCTGGAGCCACTTCTATCTGGGCTGTTGCTAATA

TTGAGGAGGCTTGCCCCACCCAACAAGCCATAGTGGAGAGAACTGAATAAACAGGAA

AATGCCAGAGCTTGTGAACCCTGTTTCTCTTGAAGAACTGACTAGTGAGATGGCCTG

GGGAAGCTGTGAAAGAACCAAAAGAGATCACAATACTCAAAAGAGAGAGAGAGAGAA

AAAAGAGAGATCTTGATCCACAGAAATACATGAAATGTCTGGTCTGTCCACCCCATC

AACAAGTCTTGAAACAAGCAACAGATGGATAGTCTGTCCAAATGGACATAAGACAGA

CAGCAGTTTCCCTGGTGGTCAGGGAGGGGTTTTGGTGATACCCAAGTTATTGGGATG

TCATCTTCCTGGAAGCAGAGCTGGGGAGGGAGAGCCATCACCTTGATAATGGGATGA

ATGGAAGGAGGCTTAGGACTTTCCACTCCTGGCTGAGAGAGGAAGAGCTGCAACGGA

ATTAGGAAGACCAAGACACAGATCACCCGGGGCTTACTTAGCCTACAGATGTCCTAC

GGGAACGTGGGCTGGCCCAGCATAGGGCTAGCAAATTTGAGTTGGATGATTGTTTTT

GCTCAAGGCAACCAGAGGAAACTTGCATACAGAGACAGATATACTGGGAGAAATGAC

TTTGAAAACCTGGCTCTAAGGTGGGATCACTAAGGGATGGGGCAGTCTCTGCCCAAA

CATAAAGAGAACTCTGGGGAGCCTGAGCCACAAAAATGTTCCTTTATTTTATGTAAA

CCCTCAAGGGTTATAGACTGCCATGCTAGACAAGCTTGTCCATGTAATATTCCCATG

TTTTTACCCTGCCCCTGCCTTGATTAGACTCCTAGCACCTGGCTAGTTTCTAACATG

TTTTGTGCAGCACAGTTTTTAATAAATGCTTGTTACATTCA (SEQ ID NO:

141)

>NP_787058.5 T-lymphocyte activation antigen CD86 isoform

1 precursor [Homo sapiens]

MDPQCTMGLSNILFVMAFLLSGAAPLKIQAYFNETADLPCQFANSQNQSLSELVVFW

QDQENLVLNEVYLGKEKFDSVHSKYMGRTSFDSDSWTLRLHNLQIKDKGLYQCIIHH

KKPTGMIRIHQMNSELSVLANFSQPEIVPISNITENVYINLTCSSIHGYPEPKKMSV

LLRTKNSTIEYDGVMQKSQDNVTELYDVSISLSVSFPDVTSNMTIFCILETDKTRLL

SSPFSIELEDPQPPPDHIPWITAVLPTVIICVMVFCLILWKWKKKKRPRNSYKCGTN

TMEREESEQTKKREKIHIPERSDEAQRVFKSSKTSSCDKSDTCF (SEQ ID NO:

142)

Mouse CD86
>NM_019388.3 Mus musculus CD86 antigen (Cd86), mRNA

ATTGCTGAGGAAGAAAGAGGAGCAAGCAGACGCGTAAGAGTGGCTCCTGTAGGCAGC

ACGGACTTGAACAACCAGACTCCTGTAGACGTGTTCCAGAACTTACGGAAGCACCCA

CGATGGACCCCAGATGCACCATGGGCTTGGCAATCCTTATCTTTGTGACAGTCTTGC

TGATCTCAGATGCTGTTTCCGTGGAGACGCAAGCTTATTTCAATGGGACTGCATATC

TGCCGTGCCCATTTACAAAGGCTCAAAACATAAGCCTGAGTGAGCTGGTAGTATTTT

GGCAGGACCAGCAAAAGTTGGTTCTGTACGAGCACTATTTGGGCACAGAGAAACTTG

ATAGTGTGAATGCCAAGTACCTGGGCCGCACGAGCTTTGACAGGAACAACTGGACTC

TACGACTTCACAATGTTCAGATCAAGGACATGGGCTCGTATGATTGTTTTATACAAA

AAAAGCCACCCACAGGATCAATTATCCTCCAACAGACATTAACAGAACTGTCAGTGA

TCGCCAACTTCAGTGAACCTGAAATAAAACTGGCTCAGAATGTAACAGGAAATTCTG

GCATAAATTTGACCTGCACGTCTAAGCAAGGTCACCCGAAACCTAAGAAGATGTATT

TTCTGATAACTAATTCAACTAATGAGTATGGTGATAACATGCAGATATCACAAGATA

ATGTCACAGAACTGTTCAGTATCTCCAACAGCCTCTCTCTTTCATTCCCGGATGGTG

TGTGGCATATGACCGTTGTGTGTGTTCTGGAAACGGAGTCAATGAAGATTTCCTCCA

AACCTCTCAATTTCACTCAAGAGTTTCCATCTCCTCAAACGTATTGGAAGGAGATTA

CAGCTTCAGTTACTGTGGCCCTCCTCCTTGTGATGCTGCTCATCATTGTATGTCACA

AGAAGCCGAATCAGCCTAGCAGGCCCAGCAACACAGCCTCTAAGTTAGAGCGGGATA

GTAACGCTGACAGAGAGACTATCAACCTGAAGGAACTTGAACCCCAAATTGCTTCAG

CAAAACCAAATGCAGAGTGAAGGCAGTGAGAGCCTGAGGAAAGAGTTAAAAATTGCT

TTGCCTGAAATAAGAAGTGCAGAGTTTCTCAGAATTCAAAAATGTTCTCAGCTGATT

GGAATTCTACAGTTGAATAATTAAAGAACAAAATACACAACAGTGTCCATATTTTAT

CCTGTTTCCTTTCCAAGTTTTTGGGCAATGTCAATTGTGTCCCCTATGCCAGGAGCA

GACATCTATTTTGTCTTGCTTTGTTTAACTCAGTGCACACTCATAGGCCAAGAGCAC

TGAAATGGCTTCTTTCCCAGGAATAACATTTTGGATCAATCTCTCCTACTTGAGATC

AGATTCTTCTTCTAATTTTGCATAGTGTGTTTTTATATGGAACTCCTTGTTGTAGGA

ATACTGGCTTTTATCTGTCTTGCACACTTGCATACTTATATACTTATACCTGGACAG

CTACCTCTTCAGTCAGGATGGGAGTGGTATATTTGGTGATGTTATTTGATGTGTTCG

TGTTGCTATCTTAAAACAGCAAAGAGCATATACTATAGTAGCTCAACTACAATGATC

TAGAGAAAGACCCAGCACTTATAAGAAACACTGTCCCTCCATCAGGGTCAATAATGA

ATACAATGACCTAAGTAATATACAGGTGACAGCAACAGCACAGAGTTCTCAGTGCTG

GCAAATCAAGAAACACAAATATGGAACCATCTCTAGATCCAAGAGCCACTCCTACCT

GGGCTGCCACAGATACTGGAAGAATCCACCTGCCTGGCCAGCAAGTCACAACTTAGC

AGGCAGCACTGAAGAAAGCAAGATGTACTGTATGCCCTTTTAAGAAAATGCCTGGAA

AGGTCTGGAGAATGCTGTGCAAGGATAAGACAGCCAAGCACTCAAAACCAGGAGACA

TCACTAGAATCCAACCAACAAATGTTTATGGAAGGACTGATCTGCCCAGTCCATTGA

AAAGTCAAGAGGTCAGAGATAGACCAGTGTGTGTCTCAATGGATGTAGATATCAGCC

ACCTCGGTGCTCAACAGGTATTTTATGATCTCCTTGTTTCAAATTCATCTAGATGTA

GAACTAGGGAGAGAGCAGTCACATTGATGAAAGGCTAGGACTCTTTCAGCTCATGGC

TTGTGTGGAAGGAGGGAAAGCAGAAATCACAACACTCTGAGACTACTGTAGTCTGCA

GATACCTGAGTGGGTGTGGCTTGGCCTTTCAAAGGACAAAGAGCAACTAATGCTGAA

AGCACATAGTGTATCTATACGGCATGGAATAGTCATCACCCAGACTTAAAGAGAACT

TTGGCAGGTCTGAGCAGCAAAATATTGTTGTTTCCATTTTACATAAAGGGCCCTGGA

GGGCTATAGACTATTCCGCTGGCAGGGCTCATGCTTGTAATGTGTCCATCTTGATTC

ACCCTGTGCAGACTCTTAAGATCTGGCCAGTTACCAACATGTTCTGTACAGAGTGGA

TTTCAATAAAGTTTTCTTGAATTTTTTCAAG

(SEQ ID NO: 143)

>NP_062261.3 T-lymphocyte activation antigen CD86

precursor [Mus musculus]

MDPRCTMGLAILIFVTVLLISDAVSVETQAYFNGTAYLPCPFTKAQNISLSELVVFW

QDQQKLVLYEHYLGTEKLDSVNAKYLGRTSFDRNNWTLRLHNVQIKDMGSYDCFIQK

KPPTGSIILQQTLTELSVIANFSEPEIKLAQNVTGNSGINLTCTSKQGHPKPKKMYF

LITNSTNEYGDNMQISQDNVTELFSISNSLSLSFPDGVWHMTVVCVLETESMKISSK

PLNFTQEFPSPQTYWKEITASVTVALLLVMLLIIVCHKKPNQPSRPSNTASKLERDS

NADRETINLKELEPQIASAKPNAE (SEQ ID NO: 144)

Human LFA-3
>NM_001779.3 Homo sapiens CD58 molecule (CD58),

(CD58)
transcript variant 1, mRNA

GAACTTAGGGCTGCTTGTGGCTGGGCACTCGCGCAGAGGCCGGCCCGACGAGCCATG

GTTGCTGGGAGCGACGCGGGGCGGGCCCTGGGGGTCCTCAGCGTGGTCTGCCTGCTG

CACTGCTTTGGTTTCATCAGCTGTTTTTCCCAACAAATATATGGTGTTGTGTATGGG

AATGTAACTTTCCATGTACCAAGCAATGTGCCTTTAAAAGAGGTCCTATGGAAAAAA

CAAAAGGATAAAGTTGCAGAACTGGAAAATTCTGAATTCAGAGCTTTCTCATCTTTT

AAAAATAGGGTTTATTTAGACACTGTGTCAGGTAGCCTCACTATCTACAACTTAACA

TCATCAGATGAAGATGAGTATGAAATGGAATCGCCAAATATTACTGATACCATGAAG

TTCTTTCTTTATGTGCTTGAGTCTCTTCCATCTCCCACACTAACTTGTGCATTGACT

AATGGAAGCATTGAAGTCCAATGCATGATACCAGAGCATTACAACAGCCATCGAGGA

CTTATAATGTACTCATGGGATTGTCCTATGGAGCAATGTAAACGTAACTCAACCAGT

ATATATTTTAAGATGGAAAATGATCTTCCACAAAAAATACAGTGTACTCTTAGCAAT

CCATTATTTAATACAACATCATCAATCATTTTGACAACCTGTATCCCAAGCAGCGGT

CATTCAAGACACAGATATGCACTTATACCCATACCATTAGCAGTAATTACAACATGT

ATTGTGCTGTATATGAATGGTATTCTGAAATGTGACAGAAAACCAGACAGAACCAAC

TCCAATTGATTGGTAACAGAAGATGAAGACAACAGCATAACTAAATTATTTTAAAAA

CTAAAAAGCCATCTGATTTCTCATTTGAGTATTACAATTTTTGAACAACTGTTGGAA

ATGTAACTTGAAGCAGCTGCTTTAAGAAGAAATACCCACTAACAAAGAACAAGCATT

AGTTTTGGCTGTCATCAACTTATTATATGACTAGGTGCTTGCTTTTTTTGTCAGTAA

ATTGTTTTTACTGATGATGTAGATACTTTTGTAAATAAATGTAAATATGTACACAAG

TGA (SEQ ID NO: 145)

>NP_001770.1 lymphocyte function-associated antigen 3

isoform 1 [Homo sapiens]

MVAGSDAGRALGVLSVVCLLHCFGFISCFSQQIYGVVYGNVTFHVPSNVPLKEVLWK

KQKDKVAELENSEFRAFSSFKNRVYLDTVSGSLTIYNLTSSDEDEYEMESPNITDTM

KFFLYVLESLPSPTLTCALTNGSIEVQCMIPEHYNSHRGLIMYSWDCPMEQCKRNST

SIYFKMENDLPQKIQCTLSNPLFNTTSSIILTTCIPSSGHSRHRYALIPIPLAVITT

CIVLYMNGILKCDRKPDRINSN (SEQ ID NO: 146)

Human SLAM
>NM_003037.5 Homo sapiens signaling lymphocytic

(CD150)
activation molecule family member 1 (SLAMF1), transcript

variant 1, mRNA

AGACAGCCTCTGCTGCATGACACGAAGCTTGCTTCTGCCTGGCATCTGTGAGCAGCT

GCCAGGCTCCGGCCAGGATCCCTTCCTTCTCCTCATTGGCTGATGGATCCCAAGGGG

CTCCTCTCCTTGACCTTCGTGCTGTTTCTCTCCCTGGCTTTTGGGGCAAGCTACGGA

ACAGGTGGGCGCATGATGAACTGCCCAAAGATTCTCCGGCAGTTGGGAAGCAAAGTG

CTGCTGCCCCTGACATATGAAAGGATAAATAAGAGCATGAACAAAAGCATCCACATT

GTCGTCACAATGGCAAAATCACTGGAGAACAGTGTCGAGAACAAAATAGTGTCTCTT

GATCCATCCGAAGCAGGCCCTCCACGTTATCTAGGAGATCGCTACAAGTTTTATCTG

GAGAATCTCACCCTGGGGATACGGGAAAGCAGGAAGGAGGATGAGGGATGGTACCTT

ATGACCCTGGAGAAAAATGTTTCAGTTCAGCGCTTTTGCCTGCAGTTGAGGCTTTAT

GAGCAGGTCTCCACTCCAGAAATTAAAGTTTTAAACAAGACCCAGGAGAACGGGACC

TGCACCTTGATACTGGGCTGCACAGTGGAGAAGGGGGACCATGTGGCTTACAGCTGG

AGTGAAAAGGCGGGCACCCACCCACTGAACCCAGCCAACAGCTCCCACCTCCTGTCC

CTCACCCTCGGCCCCCAGCATGCTGACAATATCTACATCTGCACCGTGAGCAACCCT

ATCAGCAACAATTCCCAGACCTTCAGCCCGTGGCCCGGATGCAGGACAGACCCCTCA

GAAACAAAACCATGGGCAGTGTATGCTGGGCTGTTAGGGGGTGTCATCATGATTCTC

ATCATGGTGGTAATACTACAGTTGAGAAGAAGAGGTAAAACGAACCATTACCAGACA

ACAGTGGAAAAAAAAAGCCTTACGATCTATGCCCAAGTCCAGAAACCAGGTCCTCTT

CAGAAGAAACTTGACTCCTTCCCAGCTCAGGACCCTTGCACCACCATATATGTTGCT

GCCACAGAGCCTGTCCCAGAGTCTGTCCAGGAAACAAATTCCATCACAGTCTATGCT

AGTGTGACACTTCCAGAGAGCTGACACCAGAGACCAACAAAGGGACTTTCTGAAGGA

AAATGGAAAAACCAAAATGAACACTGAACTTGGCCACAGGCCCCAAGTTTCCTCTGG

CAGACATGCTGCACGTCTGTACCCTTCTCAGATCAACTCCCTGGTGATGTTTCTTCC

ACATACATCTGTGAAATGAACAAGGAAGTGAGGCTTCCCAAGAATTTAGCTTGCTGT

GCAGTGGCTGCAGGCGCAGAACAGAGCGTTACTTGATAACAGCGTTCCATCTTTGTG

TTGTAGCAGATGAAATGGACAGTAATGTGAGTTCAGACTTTGGGCATCTTGCTCTTG

GCTGGAACTGGATAATAAAAATCAGACTGAAAGCCAGGACATCTGAGTACCTATCTC

ACACACTGGACCACCAGTCACAAAGTCTGGAAAAGTTTACATTTTGGCTATCTTTAC

TTTGTTCTGGGAGCTGATCATGATAACCTGCAGACCTGATCAAGCCTCTGTGCCTCA

GTTTCTCTCTCAGGATAAAGAGTGAATAGAGGCTGAAGGGTGAATTTCTTATTATAC

ATAAAACACTCTGATATTATTGTATAAAGGAAGCTAAGAATATTATTTTATTTGCAA

AACCCAGAAGCTAAAAAGTCAATAAACAGAAAGAATGATTTTGAGATCTCTGAGTTT

TGAACAGTGGACTGGAAACCATGTAAGAGCCTTAAAAGTACAGTTCTGTGCAAATGG

CATTCAGTTTTAAAGAAAAACGTAGCAAATGTTTGATGGTGCTGTTACAAAGGAGCT

TGGAATACTCAGAGGAACTTGTCCCATGGTGATTTTTCACTTCTCAAAATGATGTTT

AAATCCCAGTTCTCTGTTGATTCCCTTGAACAACAAACCTGGAACCTCAGCTAAGAC

TCTCTGTGACCAGATTCTGAACCTCTTATATCCAGGGCTTCAAGGGGTATTGCAGGT

CAAGGTCTTTCCTAGGCACTTTCTACTCCCTGCATACCTCTCCTCACACTAAATTTA

TCCTCTAGTAGAAAATTAAGTTATTTTGGTCTAACAGCTTCAAATCTTTGAATGCTC

AATAACTTATTTTGCAAGCTGCAGGCAGAAAGAGACTTTTTAAGTAAAGTCCTTTGT

TTTTTCCTATTCTCTGCTTTTAGACAGGCTGTCCTCAATTTAAGCCCTGCTTTTTCT

TATTGTTTCTTATATAAACTTGGTAAGTACTGTAAGAAACAGCCACTATCATACCAT

TGCATAATAAGGAGCACCAACTTCCCAGCTCAAAACTCAGGTCCTTATTGCCTTGTA

TCTTACCTCCTCTATGAGGTCAATTCACATTGTAAGCCTGTTGCTTAGTGCATCTCG

TTTCCTGGTACCAGCTTCTTTAATAGAGTTCTTAGTTGCAATCAACAGAAGCTGGCT

TTGGCTTTTTTATGTAGAAAAGGAACCTATTGAAAAGATACTGATTGGTTCCAATAA

CTGCTAGAAGTTTCTGCAAAACCATGCTTTGAAAGTGAGCAGGAAAAGAAGAGACTA

GGCTGTGGCTGGGAGCACAGCCAAAATTACAAAACCAGCCCAGGGATGATGATCCTG

TTCATGCACAGCCACTGTCCCCAGCACTAGGCACAGACTCTACCACTGCCTCACTGT

CTCTGCTGGACTTGGAAACTTGATATTACTGTTACTGCTGCACTGTCTGCCATGAAA

ATGAATTCTCCAGGGTCCCTTCTTCATCCTTTCATCTCTAGCTTATAATTCAAAGTC

TGGGATTGAGTGGCCAATCCTAGGTCACATGTCCATGTCCTATCTCCAAGGGGGGCT

GGGAATTGAATATCTGGCATTTTCCACTTTCACTTCTTATGAATTAAGGAATTCTAC

AAATAATAGAAGTGGGATTCAGGTGGTAGGCAGACAAAAAAGCCTCACAATTATCCA

CTACGCCACCCTTGTATAACCTTACCCTCATTCACTGTCTACTCTCAAAACTGTGGA

GCTACTAATGAAGATTTGTAAACCCGGGCTTATGAGCACCCATTCCTTTACTACAAC

TCAGATTGCTCTAGAAGCTCAGTTCCCAGCACTTGGATTTTTCCAGTAGCTGAATTC

TACCTGAAGGAAGGGCAGAAACAAAGGGTGAAGAAGAGGCTATCACTTCCAAGTATC

CTGCACCCCTGGGCTCAAGACCTCACTGGGGAGGGAGTCTTTTGGGCCACCCACCAA

ACAGCACTGGCATTATGCCTCTCACCCTAGACCATGGTTACACGTGGTAAAACAACC

CCTTCTGGTGATACATTCACAACTCTCTAGTTTCCCCCAAATGGCACTATGGGGAGC

GGGAGCTTGCCTTTTCCTCAGACTTAAAACAATAAGTTTTCCCCGTGTTTCCCCTCT

AATGCTGTTTTCTTTTGACCAAGCATGTCTGAATTCTAGAGAAGTCAGGAGGAACAC

ACCCATTCTCGGTTTGAAGGGACTGATGTTCTGAAGTACAACTGGGCACAGTCCCAG

GCTCTTCAGGACGCTTCCTCCATTCACACAGCGGGGATGTGATTGTTACAGCGGGTG

GTGTGTGCTGGCTGAGAAGCCACTGTGAATTGATTCTTCTTCTGAAGTTTATGTTTC

TACTTTTTGGAAATGAATAAATTACAGCCAGTCCATCAAGGAAA (SEQ ID NO:

147)

>NP_003028.1 signaling lymphocytic activation molecule

isoform b precursor [Homo sapiens]

MDPKGLLSLTFVLFLSLAFGASYGTGGRMMNCPKILRQLGSKVLLPLTYERINKSMN

KSIHIVVTMAKSLENSVENKIVSLDPSEAGPPRYLGDRYKFYLENLTLGIRESRKED

EGWYLMTLEKNVSVQRFCLQLRLYEQVSTPEIKVLNKTQENGTCTLILGCTVEKGDH

VAYSWSEKAGTHPLNPANSSHLLSLTLGPQHADNIYICTVSNPISNNSQTFSPWPGC

RTDPSETKPWAVYAGLLGGVIMILIMVVILQLRRRGKTNHYQTTVEKKSLTIYAQVQ

KPGPLQKKLDSFPAQDPCTTIYVAATEPVPESVQETNSITVYASVTLPES (SEQ

ID NO: 148)

Mouse SLAM
>NM_013730.4 Mus musculus signaling lymphocytic

(CD150)
activation molecule family member 1 (Slamf1), transcript

variant 1, mRNA

GAGCTTCTTCCTTGGGGGTAACAGTAAGCAGCTGTCCTGCCGAGCTGAGCTGAGCTG

AGCTCACAGCTGGGGACCCTGTCTGCGATTGCTGGCTAATGGATCCCAAAGGATCCC

TTTCCTGGAGAATACTTCTGTTTCTCTCCCTGGCTTTTGAGTTGAGCTACGGAACAG

GTGGAGGTGTGATGGATTGCCCAGTGATTCTCCAGAAGCTGGGACAGGACACGTGGC

TGCCCCTGACGAATGAACATCAGATAAATAAGAGCGTGAACAAAAGTGTCCGCATCC

TCGTCACCATGGCGACGTCCCCAGGAAGCAAATCCAACAAGAAAATTGTGTCTTTTG

ATCTCTCTAAAGGGAGCTATCCAGATCACCTGGAGGATGGCTACCACTTTCAATCAA

AAAACCTGAGCCTGAAGATCCTCGGGAACAGGCGGGAGAGTGAAGGATGGTACTTGG

TGAGCGTGGAGGAGAACGTTTCTGTTCAGCAATTCTGCAAGCAGCTGAAGCTTTATG

AACAGGTCTCCCCTCCAGAGATTAAAGTGCTAAACAAAACCCAGGAGAACGAGAATG

GGACCTGCAGCTTGCTGTTGGCCTGCACAGTGAAGAAAGGGGACCATGTGACTTACA

GCTGGAGTGATGAGGCAGGCACCCACCTGCTGAGCCGAGCCAACCGCTCCCACCTCC

TGCACATCACTCTTAGCAACCAGCATCAAGACAGCATCTACAACTGCACCGCAAGCA

ACCCTGTCAGCAGTATCTCTAGGACCTTCAACCTATCATCGCAAGCATGCAAGCAGG

AATCCTCCTCAGAATCGAGTCCATGGATGCAATATACTCTTGTACCACTGGGGGTCG

TTATAATCTTCATCCTGGTTTTCACGGCAATAATAATGATGAAAAGACAAGGTAAAT

CAAATCACTGCCAGCCACCAGTGGAAGAAAAAAGCCTTACTATTTATGCCCAAGTAC

AGAAATCAGGGCCTCAAGAGAAGAAACTTCATGATGCCCTAACAGATCAGGACCCCT

GCACAACCATTTATGTGGCTGCCACAGAGCCTGCCCCAGAGTCTGTCCAGGAACCAA

ACCCCACCACAGTTTATGCCAGTGTGACACTGCCAGAGAGCTGACCCATATACCCAG

TGAAAGGACTTTTTGAAGGAGGATAGAAGAACCAAAATCCACACTGAACTGGACCCC

GGGTCCCAAGTTCTCTGTGACAGAAACTGCACATCTGTAACCTTCTCCAATCAGTTC

CCTGGTGACGGATCTGCACAGGCGTGCTTATGAAGTAGATGAGAAGTGAGGCTTCCT

GGGCATGCAACCTGCTCTGCTGCTGACACAGATATGAAGCAGAGATCCCGTGGTACA

GTGTACCATCTTTGCTGTAGCAGATAATGTGGGTTTAGGCATCTCACTCTTTGCTGG

ACTGGATAACAGAACTCAAAAAAAAACCAACAAGCCAAAGACATAGACTCCATCTCA

GATGGCTGAGCACAAAGTATAAAAGCCATTTTGGCTCTCTGGACTTTATTCTGGAAG

CTGATCCTGATCACCTCAAGGCCAAGGGCTCCATGCCTCAGTTTCTCTCTCACCCTC

TAGATGAAGAGGGAACAAAGCATAAAGAGTGAAATCCTTGTTGTCTGAGATCATTCT

ATAAACGAACTGACATTTTATTTGCAAAACTCAAGCTAGTAATTCAGTAGACTTGAA

GATGATTTTAGAGCCTCTTATGCTTCAAACAACAGAATGAAATCCATCCAATGTTCT

TCAAAGTGTGGTTCTCTGATTAAGTCAAAGCAACACTGTTTGGCAATGCTGCTGTAA

AGTTGCCTGGAATACTCAGAGGAACTTGTCCCAGGGAGGTTTTTTTCACTTCTTCAA

AGAACTTTTGAATTTAAGTTCTCTGTTTATTCCCTTGAGCAAAACTCTGGAACCTCA

AGAGTCTCTCTCCGTTGGTTCTGAGGCCATTTTATAGCCTAGGCCTCCTGTGGATCT

ACATGTGTATCACCCACTTCCTATCTCACTGCATACCTCTGTGTAGTAGTAAATTTA

ACCTCAAGTAGAAAATTAAATTATTTTGGATGATCAGTTCCAAATGATTAGATGTTT

AGTCTCTTATAATAGGATGTAGGTAGAGTCTATATAAAGTCCTATATTCTTCACGTT

GTCTGTCCTCAGAGAGACCATCTTTCAACCTATCTTCCTTCTTGCACAACTTTGGCA

AATACTTTAAAAATAACCATTGTGGAGATGGGGAGAGGTCTAAATGGATAATAGTAC

TTGCTTTGCAAACATGAAGATCTGGGTTCAAACTCCCAGTGTCCATGTAAAAAGATA

AGTGTGGTTGAGTGTGCCAGTAACATAGACACAGATAGGTCCTGAGACTTTGCTCCC

TAGCCTTCCCAGCCAGGCATAAATGTCAAGTCCCCTGAGAGTGACAGAGGAAGATAC

TCCCCCCACACACACACACATACACGCACAGTGATACACATATACATGCATACAAAA

AAAAAACTTATTGTAACAAAGAACACCAACTGCCTGGCTCAAAACTCTCATGTCCCA

TTACTCTGTACCTTTCTGTATTTAGATAATTTACAGTGTGAGTTCTGCTGTTCCATG

TATCCTATTTGTGTTACTAACTTATGTCAAAGTATTTCTAATTATAATCAACAAAAG

CTAACTTTG (SEQ ID NO: 149)

>NP_038758.2 signaling lymphocytic activation molecule

isoform 1 precursor [Mus musculus]

MDPKGSLSWRILLFLSLAFELSYGTGGGVMDCPVILQKLGQDTWLPLTNEHQINKSV

NKSVRILVTMATSPGSKSNKKIVSFDLSKGSYPDHLEDGYHFQSKNLSLKILGNRRE

SEGWYLVSVEENVSVQQFCKQLKLYEQVSPPEIKVLNKTQENENGTCSLLLACTVKK

GDHVTYSWSDEAGTHLLSRANRSHLLHITLSNQHQDSIYNCTASNPVSSISRTFNLS

SQACKQESSSESSPWMQYTLVPLGVVIIFILVFTAIIMMKRQGKSNHCQPPVEEKSL

TIYAQVQKSGPQEKKLHDALTDQDPCTTIYVAATEPAPESVQEPNPTTVYASVTLPE

S (SEQ ID NO: 150)

Human CD40
>NM_001250.6 Homo sapiens CD40 molecule (CD40),

transcript variant 1, mRNA

AGTGGTCCTGCCGCCTGGTCTCACCTCGCTATGGTTCGTCTGCCTCTGCAGTGCGTC

CTCTGGGGCTGCTTGCTGACCGCTGTCCATCCAGAACCACCCACTGCATGCAGAGAA

AAACAGTACCTAATAAACAGTCAGTGCTGTTCTTTGTGCCAGCCAGGACAGAAACTG

GTGAGTGACTGCACAGAGTTCACTGAAACGGAATGCCTTCCTTGCGGTGAAAGCGAA

TTCCTAGACACCTGGAACAGAGAGACACACTGCCACCAGCACAAATACTGCGACCCC

AACCTAGGGCTTCGGGTCCAGCAGAAGGGCACCTCAGAAACAGACACCATCTGCACC

TGTGAAGAAGGCTGGCACTGTACGAGTGAGGCCTGTGAGAGCTGTGTCCTGCACCGC

TCATGCTCGCCCGGCTTTGGGGTCAAGCAGATTGCTACAGGGGTTTCTGATACCATC

TGCGAGCCCTGCCCAGTCGGCTTCTTCTCCAATGTGTCATCTGCTTTCGAAAAATGT

CACCCTTGGACAAGCTGTGAGACCAAAGACCTGGTTGTGCAACAGGCAGGCACAAAC

AAGACTGATGTTGTCTGTGGTCCCCAGGATCGGCTGAGAGCCCTGGTGGTGATCCCC

ATCATCTTCGGGATCCTGTTTGCCATCCTCTTGGTGCTGGTCTTTATCAAAAAGGTG

GCCAAGAAGCCAACCAATAAGGCCCCCCACCCCAAGCAGGAACCCCAGGAGATCAAT

TTTCCCGACGATCTTCCTGGCTCCAACACTGCTGCTCCAGTGCAGGAGACTTTACAT

GGATGCCAACCGGTCACCCAGGAGGATGGCAAAGAGAGTCGCATCTCAGTGCAGGAG

AGACAGTGAGGCTGCACCCACCCAGGAGTGTGGCCACGTGGGCAAACAGGCAGTTGG

CCAGAGAGCCTGGTGCTGCTGCTGCTGTGGCGTGAGGGTGAGGGGCTGGCACTGACT

GGGCATAGCTCCCCGCTTCTGCCTGCACCCCTGCAGTTTGAGACAGGAGACCTGGCA

CTGGATGCAGAAACAGTTCACCTTGAAGAACCTCTCACTTCACCCTGGAGCCCATCC

AGTCTCCCAACTTGTATTAAAGACAGAGGCAGAAGTTTGGTGGTGGTGGTGTTGGGG

TATGGTTTAGTAATATCCACCAGACCTTCCGATCCAGCAGTTTGGTGCCCAGAGAGG

CATCATGGTGGCTTCCCTGCGCCCAGGAAGCCATATACACAGATGCCCATTGCAGCA

TTGTTTGTGATAGTGAACAACTGGAAGCTGCTTAACTGTCCATCAGCAGGAGACTGG

CTAAATAAAATTAGAATATATTTATACAACAGAATCTCAAAAACACTGTTGAGTAAG

GAAAAAAAGGCATGCTGCTGAATGATGGGTATGGAACTTTTTAAAAAAGTACATGCT

TTTATGTATGTATATTGCCTATGGATATATGTATAAATACAATATGCATCATATATT

GATATAACAAGGGTTCTGGAAGGGTACACAGAAAACCCACAGCTCGAAGAGTGGTGA

CGTCTGGGGTGGGGAAGAAGGGTCTGGGGGAGGGTTGGTTAAAGGGAGATTTGGCTT

TCCCATAATGCTTCATCATTTTTCCCAAAAGGAGAGTGAATTCACATAATGCTTATG

TAATTAAAAAATCATCAAACATGTAAAAA (SEQ ID NO: 151)

>NP_001241.1 tumor necrosis factor receptor superfamily

member 5 isoform 1 precursor [Homo sapiens]

MVRLPLQCVLWGCLLTAVHPEPPTACREKQYLINSQCCSLCQPGQKLVSDCTEFTET

ECLPCGESEFLDTWNRETHCHQHKYCDPNLGLRVQQKGTSETDTICTCEEGWHCTSE

ACESCVLHRSCSPGFGVKQIATGVSDTICEPCPVGFFSNVSSAFEKCHPWTSCETKD

LVVQQAGTNKTDVVCGPQDRLRALVVIPIIFGILFAILLVLVFIKKVAKKPTNKAPH

PKQEPQEINFPDDLPGSNTAAPVQETLHGCQPVTQEDGKESRISVQERQ (SEQ ID

NO: 152)

Mouse CD40
>NM_170703.2 Mus musculus CD40 antigen (Cd40), transcript

variant 2, mRNA

AGCAGGGACTTTGGAGTGACTTGTGGCTTCAGCAGGAGCCCTGTGATTTGGCTCTTC

TGATCTCGCCCTGCGATGGTGTCTTTGCCTCGGCTGTGCGCGCTATGGGGCTGCTTG

TTGACAGCGGTCCATCTAGGGCAGTGTGTTACGTGCAGTGACAAACAGTACCTCCAC

GATGGCCAGTGCTGTGATTTGTGCCAGCCAGGAAGCCGACTGACAAGCCACTGCACA

GCTCTTGAGAAGACCCAATGCCACCCATGTGACTCAGGCGAATTCTCAGCCCAGTGG

AACAGGGAGATTCGCTGTCACCAGCACAGACACTGTGAACCCAATCAAGGGCTTCGG

GTTAAGAAGGAGGGCACCGCAGAATCAGACACTGTCTGTACCTGTAAGGAAGGACAA

CACTGCACCAGCAAGGATTGCGAGGCATGTGCTCAGCACACGCCCTGTATCCCTGGC

TTTGGAGTTATGGAGATGGCCACTGAGACCACTGATACCGTCTGTCATCCCTGCCCA

GTCGGCTTCTTCTCCAATCAGTCATCACTTTTCGAAAAGTGTTATCCCTGGACAAGG

TTTAAAGTCCCGGATGCGAGCCCTGCTGGTCATTCCTGTCGTGATGGGCATCCTCAT

CACCATTTTCGGGGTGTTTCTCTATATCAAAAAGGTGGTCAAGAAACCAAAGGATAA

TGAGATCTTACCCCCTGCGGCTCGACGGCAAGATCCCCAGGAGATGGAAGATTATCC

CGGTCATAACACCGCTGCTCCAGTGCAGGAGACGCTGCACGGGTGTCAGCCTGTCAC

ACAGGAGGATGGTAAAGAGAGTCGCATCTCAGTGCAGGAGCGGCAGGTGACAGACAG

CATAGCCTTGAGGCCCCTGGTCTGAACCCTGGAACTGCTTTGGAGGCGATGGCTCGG

CTCGGGAGCAGGGGCCTGGCTCTGAGGACTGCTTGCTGACCTTTGAAGTTTGAGATG

AGCCAAGACAGAGCCCAGTGCAGCTAACTCTCATGCCTGCCCCCTATCATTTCTCAA

CTTGCTTTTTAAGGATGGAGGGAGAGCTCGGGCATCGGGGGTCCACAGTGATACCTA

CCAAGTGCAGCAGTGCAGGACCCAGAGTCGTCTTGCTGCGGCGTTCACTGTAAGGAG

TCATGGACACAGGAGTCCGTGGCCCACAGCTTGTGCTGCTAGAGGGCACCTGGTTGC

CCATCAGCAGGGTACTGGCTAAATAAATCTGTAATTATTTATACAATGACATCTCAG

AAACTCTAGCAGGTGGGGCAGAAAACAGGTAGTAGAATGATGGGTAGAGAAATAGCT

TTTAAAACACATTCCAAGGCAGGTAAGATGGCTTTTGTGAGTAAAGGAGCTTGCTGC

CCAAACCCGGTTACCTGATTTTGATCCCTGGGACTTCATGGTAAAAGGGAGAGAACC

AAATCCAGAGGGTTGTCATTTGACCTCCATGTGTGCTCTGTGGTAATGTACCCCGTG

TGTGCACATGTGCACATATCCTAAAATGGATGTGGTGGTGTATTGTAGAAATTATTT

AATCCCGCCCTGGGGTTTCTACCTGTGTGTTACCATTTAGTTCTTGAATAAAAGACA

CACTCAACCTTTATATTTACAATAA (SEQ ID NO: 153)

>NP_733804.1 tumor necrosis factor receptor superfamily

member 5 isoform 2 precursor [Mus musculus]

MVSLPRLCALWGCLLTAVHLGQCVTCSDKQYLHDGQCCDLCQPGSRLTSHCTALEKT

QCHPCDSGEFSAQWNREIRCHQHRHCEPNQGLRVKKEGTAESDTVCTCKEGQHCTSK

DCEACAQHTPCIPGFGVMEMATETTDTVCHPCPVGFFSNQSSLFEKCYPWTRFKVPD

ASPAGHSCRDGHPHHHFRGVSLYQKGGQETKG (SEQ ID NO: 154)

Human CD28
>NM_006139.4 Homo sapiens CD28 molecule (CD28),

transcript variant 1, mRNA

ACACTTCGGGTTCCTCGGGGAGGAGGGGCTGGAACCCTAGCCCATCGTCAGGACAAA

GATGCTCAGGCTGCTCTTGGCTCTCAACTTATTCCCTTCAATTCAAGTAACAGGAAA

CAAGATTTTGGTGAAGCAGTCGCCCATGCTTGTAGCGTACGACAATGCGGTCAACCT

TAGCTGCAAGTATTCCTACAATCTCTTCTCAAGGGAGTTCCGGGCATCCCTTCACAA

AGGACTGGATAGTGCTGTGGAAGTCTGTGTTGTATATGGGAATTACTCCCAGCAGCT

TCAGGTTTACTCAAAAACGGGGTTCAACTGTGATGGGAAATTGGGCAATGAATCAGT

GACATTCTACCTCCAGAATTTGTATGTTAACCAAACAGATATTTACTTCTGCAAAAT

TGAAGTTATGTATCCTCCTCCTTACCTAGACAATGAGAAGAGCAATGGAACCATTAT

CCATGTGAAAGGGAAACACCTTTGTCCAAGTCCCCTATTTCCCGGACCTTCTAAGCC

CTTTTGGGTGCTGGTGGTGGTTGGTGGAGTCCTGGCTTGCTATAGCTTGCTAGTAAC

AGTGGCCTTTATTATTTTCTGGGTGAGGAGTAAGAGGAGCAGGCTCCTGCACAGTGA

CTACATGAACATGACTCCCCGCCGCCCCGGGCCCACCCGCAAGCATTACCAGCCCTA

TGCCCCACCACGCGACTTCGCAGCCTATCGCTCCTGACACGGACGCCTATCCAGAAG

CCAGCCGGCTGGCAGCCCCCATCTGCTCAATATCACTGCTCTGGATAGGAAATGACC

GCCATCTCCAGCCGGCCACCTCAGGCCCCTGTTGGGCCACCAATGCCAATTTTTCTC

GAGTGACTAGACCAAATATCAAGATCATTTTGAGACTCTGAAATGAAGTAAAAGAGA

TTTCCTGTGACAGGCCAAGTCTTACAGTGCCATGGCCCACATTCCAACTTACCATGT

ACTTAGTGACTTGACTGAGAAGTTAGGGTAGAAAACAAAAAGGGAGTGGATTCTGGG

AGCCTCTTCCCTTTCTCACTCACCTGCACATCTCAGTCAAGCAAAGTGTGGTATCCA

CAGACATTTTAGTTGCAGAAGAAAGGCTAGGAAATCATTCCTTTTGGTTAAATGGGT

GTTTAATCTTTTGGTTAGTGGGTTAAACGGGGTAAGTTAGAGTAGGGGGAGGGATAG

GAAGACATATTTAAAAACCATTAAAACACTGTCTCCCACTCATGAAATGAGCCACGT

AGTTCCTATTTAATGCTGTTTTCCTTTAGTTTAGAAATACATAGACATTGTCTTTTA

TGAATTCTGATCATATTTAGTCATTTTGACCAAATGAGGGATTTGGTCAAATGAGGG

ATTCCCTCAAAGCAATATCAGGTAAACCAAGTTGCTTTCCTCACTCCCTGTCATGAG

ACTTCAGTGTTAATGTTCACAATATACTTTCGAAAGAATAAAATAGTTCTCCTACAT

GAAGAAAGAATATGTCAGGAAATAAGGTCACTTTATGTCAAAATTATTTGAGTACTA

TGGGACCTGGCGCAGTGGCTCATGCTTGTAATCCCAGCACTTTGGGAGGCCGAGGTG

GGCAGATCACTTGAGATCAGGACCAGCCTGGTCAAGATGGTGAAACTCCGTCTGTAC

TAAAAATACAAAATTTAGCTTGGCCTGGTGGCAGGCACCTGTAATCCCAGCTGCCCA

AGAGGCTGAGGCATGAGAATCGCTTGAACCTGGCAGGCGGAGGTTGCAGTGAGCCGA

GATAGTGCCACAGCTCTCCAGCCTGGGCGACAGAGTGAGACTCCATCTCAAACAACA

ACAACAACAACAACAACAACAACAAACCACAAAATTATTTGAGTACTGTGAAGGATT

ATTTGTCTAACAGTTCATTCCAATCAGACCAGGTAGGAGCTTTCCTGTTTCATATGT

TTCAGGGTTGCACAGTTGGTCTCTTTAATGTCGGTGTGGAGATCCAAAGTGGGTTGT

GGAAAGAGCGTCCATAGGAGAAGTGAGAATACTGTGAAAAAGGGATGTTAGCATTCA

TTAGAGTATGAGGATGAGTCCCAAGAAGGTTCTTTGGAAGGAGGACGAATAGAATGG

AGTAATGAAATTCTTGCCATGTGCTGAGGAGATAGCCAGCATTAGGTGACAATCTTC

CAGAAGTGGTCAGGCAGAAGGTGCCCTGGTGAGAGCTCCTTTACAGGGACTTTATGT

GGTTTAGGGCTCAGAGCTCCAAAACTCTGGGCTCAGCTGCTCCTGTACCTTGGAGGT

CCATTCACATGGGAAAGTATTTTGGAATGTGTCTTTTGAAGAGAGCATCAGAGTTCT

TAAGGGACTGGGTAAGGCCTGACCCTGAAATGACCATGGATATTTTTCTACCTACAG

TTTGAGTCAACTAGAATATGCCTGGGGACCTTGAAGAATGGCCCTTCAGTGGCCCTC

ACCATTTGTTCATGCTTCAGTTAATTCAGGTGTTGAAGGAGCTTAGGTTTTAGAGGC

ACGTAGACTTGGTTCAAGTCTCGTTAGTAGTTGAATAGCCTCAGGCAAGTCACTGCC

CACCTAAGATGATGGTTCTTCAACTATAAAATGGAGATAATGGTTACAAATGTCTCT

TCCTATAGTATAATCTCCATAAGGGCATGGCCCAAGTCTGTCTTTGACTCTGCCTAT

CCCTGACATTTAGTAGCATGCCCGACATACAATGTTAGCTATTGGTATTATTGCCAT

ATAGATAAATTATGTATAAAAATTAAACTGGGCAATAGCCTAAGAAGGGGGGAATAT

TGTAACACAAATTTAAACCCACTACGCAGGGATGAGGTGCTATAATATGAGGACCTT

TTAACTTCCATCATTTTCCTGTTTCTTGAAATAGTTTATCTTGTAATGAAATATAAG

GCACCTCCCACTTTTATGTATAGAAAGAGGTCTTTTAATTTTTTTTTAATGTGAGAA

GGAAGGGAGGAGTAGGAATCTTGAGATTCCAGATCGAAAATACTGTACTTTGGTTGA

TTTTTAAGTGGGCTTCCATTCCATGGATTTAATCAGTCCCAAGAAGATCAAACTCAG

CAGTACTTGGGTGCTGAAGAACTGTTGGATTTACCCTGGCACGTGTGCCACTTGCCA

GCTTCTTGGGCACACAGAGTTCTTCAATCCAAGTTATCAGATTGTATTTGAAAATGA

CAGAGCTGGAGAGTTTTTTGAAATGGCAGTGGCAAATAAATAAATACTTTTTTTTAA

ATGGAAAGACTTGATCTATGGTAATAAATGATTTTGTTTTCTGACTGGAAAAATAGG

CCTACTAAAGATGAATCACACTTGAGATGTTTCTTACTCACTCTGCACAGAAACAAA

GAAGAAATGTTATACAGGGAAGTCCGTTTTCACTATTAGTATGAACCAAGAAATGGT

TCAAAAACAGTGGTAGGAGCAATGCTTTCATAGTTTCAGATATGGTAGTTATGAAGA

AAACAATGTCATTTGCTGCTATTATTGTAAGAGTCTTATAATTAATGGTACTCCTAT

AATTTTTGATTGTGAGCTCACCTATTTGGGTTAAGCATGCCAATTTAAAGAGACCAA

GTGTATGTACATTATGTTCTACATATTCAGTGATAAAATTACTAAACTACTATATGT

CTGCTTTAAATTTGTACTTTAATATTGTCTTTTGGTATTAAGAAAGATATGCTTTCA

GAATAGATATGCTTCGCTTTGGCAAGGAATTTGGATAGAACTTGCTATTTAAAAGAG

GTGTGGGGTAAATCCTTGTATAAATCTCCAGTTTAGCCTTTTTTGAAAAAGCTAGAC

TTTCAAATACTAATTTCACTTCAAGCAGGGTACGTTTCTGGTTTGTTTGCTTGACTT

CAGTCACAATTTCTTATCAGACCAATGGCTGACCTCTTTGAGATGTCAGGCTAGGCT

TACCTATGTGTTCTGTGTCATGTGAATGCTGAGAAGTTTGACAGAGATCCAACTTCA

GCCTTGACCCCATCAGTCCCTCGGGTTAACTAACTGAGCCACCGGTCCTCATGGCTA

TTTTAATGAGGGTATTGATGGTTAAATGCATGTCTGATCCCTTATCCCAGCCATTTG

CACTGCCAGCTGGGAACTATACCAGACCTGGATACTGATCCCAAAGTGTTAAATTCA

ACTACATGCTGGAGATTAGAGATGGTGCCAATAAAGGACCCAGAACCAGGATCTTGA

TTGCTATAGACTTATTAATAATCCAGGTCAAAGAGAGTGACACACACTCTCTCAAGA

CCTGGGGTGAGGGAGTCTGTGTTATCTGCAAGGCCATTTGAGGCTCAGAAAGTCTCT

CTTTCCTATAGATATATGCATACTTTCTGACATATAGGAATGTATCAGGAATACTCA

ACCATCACAGGCATGTTCCTACCTCAGGGCCTTTACATGTCCTGTTTACTCTGTCTA

GAATGTCCTTCTGTAGATGACCTGGCTTGCCTCGTCACCCTTCAGGTCCTTGCTCAA

GTGTCATCTTCTCCCCTAGTTAAACTACCCCACACCCTGTCTGCTTTCCTTGCTTAT

TTTTCTCCATAGCATTTTACCATCTCTTACATTAGACATTTTTCTTATTTATTTGTA

GTTTATAAGCTTCATGAGGCAAGTAACTTTGCTTTGTTTCTTGCTGTATCTCCAGTG

CCCAGAGCAGTGCCTGGTATATAATAAATATTTATTGACTGAGTGAA (SEQ ID

NO: 155)

>NP_006130.1 T-cell-specific surface glycoprotein CD28

isoform 1 precursor [Homo sapiens]

MLRLLLALNLFPSIQVTGNKILVKQSPMLVAYDNAVNLSCKYSYNLFSREFRASLHK

GLDSAVEVCVVYGNYSQQLQVYSKTGFNCDGKLGNESVTFYLQNLYVNQTDIYFCKI

EVMYPPPYLDNEKSNGTIIHVKGKHLCPSPLFPGPSKPFWVLVVVGGVLACYSLLVT

VAFIIFWVRSKRSRLLHSDYMNMTPRRPGPTRKHYQPYAPPRDFAAYRS (SEQ ID

NO: 156)

Mouse CD28
>NM_007642.4 Mus musculus CD28 antigen (Cd28), mRNA

AGACCTTGGCAGATGTGACTTCAGTTCACACCACACTCTGCCTTGCTCACAGAGGAG

GGGCTGCAGCCCTGGCCCTCATCAGAACAATGACACTCAGGCTGCTGTTCTTGGCTC

TCAACTTCTTCTCAGTTCAAGTAACAGAAAACAAGATTTTGGTAAAGCAGTCGCCCC

TGCTTGTGGTAGATAGCAACGAGGTCAGCCTCAGCTGCAGGTATTCCTACAACCTTC

TCGCAAAGGAATTCCGGGCATCCCTGTACAAGGGCGTGAACAGCGACGTGGAAGTCT

GTGTCGGGAATGGGAATTTTACCTATCAGCCCCAGTTTCGCTCGAATGCCGAGTTCA

ACTGCGACGGGGATTTCGACAACGAAACAGTGACGTTCCGTCTCTGGAATCTGCACG

TCAATCACACAGATATTTACTTCTGCAAAATTGAGTTCATGTACCCTCCGCCTTACC

TAGACAACGAGAGGAGCAATGGAACTATTATTCACATAAAAGAGAAACATCTTTGTC

ATACTCAGTCATCTCCTAAGCTGTTTTGGGCACTGGTCGTGGTTGCTGGAGTCCTGT

TTTGTTATGGCTTGCTAGTGACAGTGGCTCTTTGTGTTATCTGGACAAATAGTAGAA

GGAACAGACTCCTTCAAAGTGACTACATGAACATGACTCCCCGGAGGCCTGGGCTCA

CTCGAAAGCCTTACCAGCCCTACGCCCCTGCCAGAGACTTTGCAGCGTACCGCCCCT

GACAGGGACCCCTATCCAGAAGCCCGCCGGCTGGTACCCGTCTACCTGCTCATCATC

ACTGCTCTGGATAGGAAAGGACAGCCTCATCTTCAGCCGGCCACTTTGGACCTCTAC

TGGGCCACCAATGCCAACTATTTTAGAGTGTCTAGATCTAACATCATGATCATCTTG

AGACTCTGGAATGAATGACAGAAGCTTCTATGGCAGGATAAAGTCTGTGTGGCTTGA

CCCAAACTCAAGCTTAATACATTTATTGACTTGATTGGGGAAGTTAGAGTAGAGCAA

TCAAAAAGATCATTCATTCAGCCTTGGGAAGTCAATTTGCAGGCTCCTGGATGAGCC

CTGCCCCGTTTTCACTTGCCAGCACATTTCAGTCATGTGGTGTGATAGCCAAAGATG

TTTTGGACAGAGAAGAAAGGATAGAAAAACCTTCTCTTTGGCTAAGTTGGTGTTTGG

GGTGGGGATAGGTTAGAGTATAGTACTTAACTATTTGAAAAATAATGAAAACACTTT

TTTCACTCATGAAATGAGCCACTTAGCTCCTAAATAGTGTTTTCCTGTTAGTTTAGA

AAGTTGTGGACATATTTTTTTAATGATTTCTGACCATTTTTAATCACATTGACTCAT

GGAATGGCCTCAAAGCACCCCCCAGTGCTTCTTTCCTCATTCCCGGTCATGGGAACT

CAGTATTATTAATAGTCACAACATGATTTCAGAACTAGATAGCCCTCCCACACCAAG

AAGAATGTGAGAGGAAGTAAGGTCACTTTATGTAAAAAAAAAAAAAAACAAACGCGT

ACACATATGTATGTATACATACATACCTATGTGCACACACACACACATATACATACA

CACAAAATGCTATGAAGAGTTATCTGTTTAGTAGCCTGTTATAGTCAAATCATTTTA

AGTTTCAACTTCTTACAGTTGGGCCACTTGTTGTCCTTTGTGGATGGATATCTGAAA

TTGTGTCTATATATTGCTAGTCATGATACTGTGAACAAAAAGGGTAGTGTTAGTATT

TGTCAGGGTGGTAAGGATGCATTCCAGGAAGCTTCCTCTGAGGAAGGGAATGAGGTC

ATTCTTGCCATGTATGAAAGACATAGATGTTTTCCAGAAGGCACCATTGGGAGCCCC

AGTATAAGTTCCTTTAGACTCTACAGTTTAGAGGGATTTTATATGTCCTAGGACTCA

GGACTCCAGAACTTTGTGGGCTCAGCTGCTTCATACCATGGGGATACATTGACATGA

ACAATTATTTTGGAATGTGTCTTTAGGGACGACATCAAAGTTCTCAAGTACCTACAA

GACCTGATACTGGAATGAAGGTGGACTTTCTTTTTTGCTTCCAGTTCGGATCAACTG

GAATGTATCTGGGGACCTTGAAGAACGGCTGTCCAGCTGTCTTCACCATTTGTATAG

TGCTTTGAATTATTCAGAGGTTTTAAAGTCAGGAAGACCTGGTTTAAAAAACATTTC

ATTATGAGTTAAATGGCCTCAGGCAAGTCACTGTTCATCCAAGTCTATGACTCCTCA

ACTGTAAGATGGCCACACTGAAACTTGCTAAGATCCTCTGGCCTCTGCCTCCCAAGA

GTTGGGATTTCAGGAGTGCACAATCATGACCCAAACTCGTGATAATCTCTCAGCTTC

AATAACTTTCCAGCTAATTGGAATATCCTGTAATCAAACATGAGGCATTTCCCCTCC

CCCCACTGTTTTTGTGTATAAAGAGATCTTTAAACTTTTTTTTTAATATGAGGGGTA

AGAAAAGATAGGAATCTTTTAATTCTAGACAGAAGATATTGTGCTTTGGTTTTTTTT

TTTTTTAATGGCTTCTATTCTGTGCTTTTAATTAAACCAGAGAAGGCCAAGATTAGC

CCTACTTGTGTGATAAAAGAATGCTGGCCCTTGTGATTGCAGTCAGCCTCTTGACAC

ATAGAGTTCTTGAATCTAAGTTATAAAATTATATTTGAAAATGACAGAGCTGGAGAA

TTTATAGAAAGGGTCATAGCAAATAACAAACCATTTTTTTTTAAACGGAAAGATTTG

GTCTTTGGCAATCAATAACTTTGTTTTCTAACTGGAAAAGGAGGTTTACTGGAGATG

AATCACACCTGAAAGTTTTCATACCTCCTCTGAACACAACCGAAACATAGGTGTCCA

AAGCCTTTCGCTCTCGGTATGAACCAACAGGCGGGTTAAAAACACTGGGTCAGAGTA

AAGCTTTTGCAGTTTCAGATGTAGTGTGTATGAAGAAAACTATGTCACTTGCTGCTA

TTATTGTAAGAGTCTAAGAACTAAAGGTGTGCCTGTAATTTCTAATTATGAGCTCAC

CTATTTGGTACCGAGCATGCCAATTTTAAAGAGACCCGGTGTACCTTATAGCTACAT

CCAATGATAAAATTACCACACTAGCACATGCCTGTGTTTAAACTCGTGCTTTAATGT

TTTTCTTAGGGCAGGTATGCACCCCCTTTGCAGTGAGTTGGGAGAGATTTTGAAAAA

GTGTATGACAAACATTTTTAACACCTTTGGTTTCCTCTCTCTGTGTCTCTTTGTCTC

TGTCTCTCTCTTTCTCTCCTGTGCATATGTCTCCCCTCCCTCACTTCTCTGTCTCTT

CCTCTCTCCCTCTCTCTGTCTTTCTCTGTGTGTCTCTCTGTCTCTGTGTATCTCTCT

GTCTGTCTCTTTCTCTGCAGATTTTCAAAACGTTGTTTTTCTATGGAAGAAATACAA

GCTGTGGTTGGTTTGCTACGAGTCAGTAGCAGTTTATCAGTAGGCCAATGTTTTATC

TCTTGGAGATTTCAGTCTGGGTTTACCCAATGTATTCTCTGTAATGTGACTGCTGGG

GACAGATATAACTTGATTGAGCCTTCAAATCATTTAGGTCTTCAATCATTTAGTCAA

CGGAGTGAGCCACTAATCTGCAATGGCTATTTTAATATGCATACTGATGGTCAAATG

GATGTCTGATCTCTCATCCCAGCTTTCTGTACTACCATATGGGAACTATATGTAACT

TGTATACTTACCTGAATATGTTAAATTCAACTACATGGTAAGATGGACCAGAAATTG

CAATGTTCATGTCCATATAGCCACCATTAACCCAAGTTAAGCACAGTAGTGTGGGTT

CTCTCAGGACTTGTGAATGAGTTTATGCTCTCTACAAAGACAGGTGAAGCTTAAATC

TCTCTTGCACTGCTATGTTTATGCAAATATCAAGATTGTTTCTGTACCAGGGACTTA

ACACATTCTATTCATACTATTTTCCCTGTCTACAATGTTATTTCATAGATATCTACT

TGGTTTGCTCTTACTTCCTTGACATATTTGCCCAAATGCCACCTTCAACTGTAGTTA

ATTACCTGTACAACCTGTCTCCATGCCTTGTTTTATTTTCTCTATAACTCTACTAAT

AGGTATTTTTCTTATTTATTGGTTTATTGCCTGTTTTTTTTCCTAAATCTACACCGG

ATCTCCAAAGGGAAAGAACTCCATTTGCTTTGATTTTATTGCTGTATCCCCAGTGCC

TAGAATAATGCTTAGCCTGCAATAAATATTTATTCATTGACT (SEQ ID NO:

157)

>NP 031668.3 T-cell-specific surface glycoprotein CD28

precursor [Mus musculus]

MTLRLLFLALNFFSVQVTENKILVKQSPLLVVDSNEVSLSCRYSYNLLAKEFRASLY

KGVNSDVEVCVGNGNFTYQPQFRSNAEFNCDGDFDNETVTFRLWNLHVNHTDIYFCK

IEFMYPPPYLDNERSNGTIIHIKEKHLCHTQSSPKLFWALVVVAGVLFCYGLLVTVA

LCVIWTNSRRNRLLQSDYMNMTPRRPGLTRKPYQPYAPARDFAAYRP (SEQ ID

NO: 158)

Human
>NM_144615.2 Homo sapiens transmembrane and

CD28H
immunoglobulin domain containing 2 (TMIGD2), transcript

variant 1, mRNA

GGAAGTCTGTCAACTGGGAGGGGGAGAGGGGGGTGATGGGCCAGGAATGGGGTCCCC

GGGCATGGTGCTGGGCCTCCTGGTGCAGATCTGGGCCCTGCAAGAAGCCTCAAGCCT

GAGCGTGCAGCAGGGGCCCAACTTGCTGCAGGTGAGGCAGGGCAGTCAGGCGACCCT

GGTCTGCCAGGTGGACCAGGCCACAGCCTGGGAACGGCTCCGTGTTAAGTGGACAAA

GGATGGGGCCATCCTGTGTCAACCGTACATCACCAACGGCAGCCTCAGCCTGGGGGT

CTGCGGGCCCCAGGGACGGCTCTCCTGGCAGGCACCCAGCCATCTCACCCTGCAGCT

GGACCCTGTGAGCCTCAACCACAGCGGGGCGTACGTGTGCTGGGCGGCCGTAGAGAT

TCCTGAGTTGGAGGAGGCTGAGGGCAACATAACAAGGCTCTTTGTGGACCCAGATGA

CCCCACACAGAACAGAAACCGGATCGCAAGCTTCCCAGGATTCCTCTTCGTGCTGCT

GGGGGTGGGAAGCATGGGTGTGGCTGCGATCGTGTGGGGTGCCTGGTTCTGGGGCCG

CCGCAGCTGCCAGCAAAGGGACTCAGGTAACAGCCCAGGAAATGCATTCTACAGCAA

CGTCCTATACCGGCCCCGGGGGGCCCCAAAGAAGAGTGAGGACTGCTCTGGAGAGGG

GAAGGACCAGAGGGGCCAGAGCATTTATTCAACCTCCTTCCCGCAACCGGCCCCCCG

CCAGCCGCACCTGGCGTCAAGACCCTGCCCCAGCCCGAGACCCTGCCCCAGCCCCAG

GCCCGGCCACCCCGTCTCTATGGTCAGGGTCTCTCCTAGACCAAGCCCCACCCAGCA

GCCGAGGCCAAAAGGGTTCCCCAAAGTGGGAGAGGAGTGAGAGATCCCAGGAGACCT

CAACAGGACCCCACCCATAGGTACACACAAAAAAGGGGGGATCGAGGCCAGACACGG

TGGCTCACGCCTGTAATCCCAGCAGTTTGGGAAGCCGAGGCGGGTGGAACACTTGAG

GTCAGGGGTTTGAGACCAGCCTGGCTTGAACCTGGGAGGCGGAGGTTGCAGTGAGCC

GAGATTGCGCCACTGCACTCCAGCCTGGGCGACAGAGTGAGACTCCGTCTCAAAAAA

AACAAAAAGCAGGAGGATTGGGAGCCTGTCAGCCCCATCCTGAGACCCCGTCCTCAT

TTCTGTAATGATGGATCTCGCTCCCACTTTCCCCCAAGAACCTAATAAAGGCTTGTG

AAGAAAAAGCAAAAAAAAAAAAAAAAAA (SEQ ID NO: 159)

>NP_653216.2 transmembrane and immunoglobulin domain-

containing protein 2 isoform 1 precursor [Homo sapiens]

MGSPGMVLGLLVQIWALQEASSLSVQQGPNLLQVRQGSQATLVCQVDQATAWERLRV

KWTKDGAILCQPYITNGSLSLGVCGPQGRLSWQAPSHLTLQLDPVSLNHSGAYVCWA

AVEIPELEEAEGNITRLFVDPDDPTQNRNRIASFPGFLFVLLGVGSMGVAAIVWGAW

FWGRRSCQQRDSGNSPGNAFYSNVLYRPRGAPKKSEDCSGEGKDQRGQSIYSTSFPQ

PAPRQPHLASRPCPSPRPCPSPRPGHPVSMVRVSPRPSPTQQPRPKGFPKVGEE

(SEQ ID NO: 160)

Human CD2
>NM_001328609.2 Homo sapiens CD2 molecule (CD2),

transcript variant 1, mRNA

AGTCTCACTTCAGTTCCTTTTGCATGAAGAGCTCAGAATCAAAAGAGGAAACCAACC

CCTAAGATGAGCTTTCCATGTAAATTTGTAGCCAGCTTCCTTCTGATTTTCAATGTT

TCTTCCAAAGGTGCAGTCTCCAAAGAGATTACGAATGCCTTGGAAACCTGGGGTGCC

TTGGGTCAGGACATCAACTTGGACATTCCTAGTTTTCAAATGAGTGATGATATTGAC

GATATAAAATGGGAAAAAACTTCAGACAAGAAAAAGATTGCACAATTCAGAAAAGAG

AAAGAGACTTTCAAGGAAAAAGATACATATAAGCTATTTAAAAATGGAACTCTGAAA

ATTAAGCATCTGAAGACCGATGATCAGGATATCTACAAGGTATCAATATATGATACA

AAAGGAAAAAATGTGTTGGAAAAAATATTTGATTTGAAGATTCAAGAGAGGGTCTCA

AAACCAAAGATCTCCTGGACTTGTATCAACACAACCCTGACCTGTGAGGTAATGAAT

GGAACTGACCCCGAATTAAACCTGTATCAAGATGGGAAACATCTAAAACTTTCTCAG

AGGGTCATCACACACAAGTGGACCACCAGCCTGAGTGCAAAATTCAAGTGCACAGCA

GGGAACAAAGTCAGCAAGGAATCCAGTGTCGAGCCTGTCAGCTGTCCAGGAGGCAGC

ATCCTTGGCCAGAGTAATGGGCTCTCTGCCTGGACCCCTCCCAGCCATCCCACTTCT

CTTCCTTTTGCAGAGAAAGGTCTGGACATCTATCTCATCATTGGCATATGTGGAGGA

GGCAGCCTCTTGATGGTCTTTGTGGCACTGCTCGTTTTCTATATCACCAAAAGGAAA

AAACAGAGGAGTCGGAGAAATGATGAGGAGCTGGAGACAAGAGCCCACAGAGTAGCT

ACTGAAGAAAGGGGCCGGAAGCCCCACCAAATTCCAGCTTCAACCCCTCAGAATCCA

GCAACTTCCCAACATCCTCCTCCACCACCTGGTCATCGTTCCCAGGCACCTAGTCAT

CGTCCCCCGCCTCCTGGACACCGTGTTCAGCACCAGCCTCAGAAGAGGCCTCCTGCT

CCGTCGGGCACACAAGTTCACCAGCAGAAAGGCCCGCCCCTCCCCAGACCTCGAGTT

CAGCCAAAACCTCCCCATGGGGCAGCAGAAAACTCATTGTCCCCTTCCTCTAATTAA

AAAAGATAGAAACTGTCTTTTTCAATAAAAAGCACTGTGGATTTCTGCCCTCCTGAT

GTGCATATCCGTACTTCCATGAGGTGTTTTCTGTGTGCAGAACATTGTCACCTCCTG

AGGCTGTGGGCCACAGCCACCTCTGCATCTTCGAACTCAGCCATGTGGTCAACATCT

GGAGTTTTTGGTCTCCTCAGAGAGCTCCATCACACCAGTAAGGAGAAGCAATATAAG

TGTGATTGCAAGAATGGTAGAGGACCGAGCACAGAAATCTTAGAGATTTCTTGTCCC

CTCTCAGGTCATGTGTAGATGCGATAAATCAAGTGATTGGTGTGCCTGGGTCTCACT

ACAAGCAGCCTATCTGCTTAAGAGACTCTGGAGTTTCTTATGTGCCCTGGTGGACAC

TTGCCCACCATCCTGTGAGTAAAAGTGAAATAAAAGCTTTGACTAGA (SEQ ID

NO: 161)

>NP_001315538.1 T-cell surface antigen CD2 isoform 1

precursor [Homo sapiens]

MSFPCKFVASFLLIFNVSSKGAVSKEITNALETWGALGQDINLDIPSFQMSDDIDDI

KWEKTSDKKKIAQFRKEKETFKEKDTYKLFKNGTLKIKHLKTDDQDIYKVSIYDTKG

KNVLEKIFDLKIQERVSKPKISWTCINTTLTCEVMNGTDPELNLYQDGKHLKLSQRV

ITHKWTTSLSAKFKCTAGNKVSKESSVEPVSCPGGSILGQSNGLSAWTPPSHPTSLP

FAEKGLDIYLIIGICGGGSLLMVFVALLVFYITKRKKQRSRRNDEELETRAHRVATE

ERGRKPHQIPASTPQNPATSQHPPPPPGHRSQAPSHRPPPPGHRVQHQPQKRPPAPS

GTQVHQQKGPPLPRPRVQPKPPHGAAENSLSPSSN (SEQ ID NO: 162)

Mouse CD2
>NM_013486.2 Mus musculus CD2 antigen (Cd2), mRNA

GCCTCACCACAGTCCTGACAGAAAGAACTCAGAGTCACCCCTGGGAAAAGAACTCTA

AAGATGAAATGTAAATTCCTGGGTAGCTTCTTTCTGCTCTTCAGCCTTTCCGGCAAA

GGGGCGGACTGCAGAGACAATGAGACCATCTGGGGTGTCTTGGGTCATGGCATCACC

CTGAACATCCCCAACTTTCAAATGACTGATGATATTGATGAGGTGCGATGGGTAAGG

AGGGGCACCCTGGTCGCAGAGTTTAAAAGGAAGAAGCCACCTTTTTTGATATCAGAA

ACGTATGAGGTCTTAGCAAACGGATCCCTGAAGATAAAGAAGCCGATGATGAGAAAC

GACAGTGGCACCTATAATGTAATGGTGTATGGCACAAATGGGATGACTAGGCTGGAG

AAGGACCTGGACGTGAGGATTCTGGAGAGGGTCTCAAAGCCCATGATCCACTGGGAA

TGCCCCAACACAACCCTGACCTGTGCGGTCTTGCAAGGGACAGATTTTGAACTGAAG

CTGTATCAAGGGGAAACACTACTCAATAGTCTCCCCCAGAAGAACATGAGTTACCAG

TGGACCAACCTGAACGCACCATTCAAGTGTGAGGCGATAAACCCGGTCAGCAAGGAG

TCTAAGATGGAAGTTGTTAACTGTCCAGAGAAAGGTCTGTCCTTCTATGTCACAGTG

GGGGTCGGTGCAGGAGGACTCCTCTTGGTGCTCTTGGTGGCGCTTTTTATTTTCTGT

ATCTGCAAGAGGAGAAAACGGAACAGGAGGAGAAAAGATGAAGAGCTGGAAATAAAA

GCTTCCAGAACAAGCACTGTGGAAAGGGGCCCCAAGCCGCACTCAACCCCAGCCGCA

GCAGCGCAGAATTCAGTGGCGCTCCAAGCTCCTCCTCCACCTGGCCATCACCTCCAG

ACACCTGGCCATCGTCCCTTGCCTCCAGGCCACCGTACCCGTGAGCACCAGCAGAAG

AAGAGACCTCCTCCATCAGGCACACAGATTCACCAGCAGAAAGGCCCTCCTTTACCC

AGACCCCGAGTTCAGCCAAAACCTCCCTGTGGGAGTGGAGATGGTGTTTCACTGCCG

CCCCCTAATTAAGAAGGCAGAGTTCGTCATTTCCAATAAAAAGCTGTGTGGATTTAT

CTTC (SEQ ID NO: 163)

>NP_038514.1 T-cell surface antigen CD2 precursor [Mus

musculus]

MKCKFLGSFFLLFSLSGKGADCRDNETIWGVLGHGITLNIPNFQMTDDIDEVRWVRR

GTLVAEFKRKKPPFLISETYEVLANGSLKIKKPMMRNDSGTYNVMVYGTNGMTRLEK

DLDVRILERVSKPMIHWECPNTTLTCAVLQGTDFELKLYQGETLLNSLPQKNMSYQW

TNLNAPFKCEAINPVSKESKMEVVNCPEKGLSFYVTVGVGAGGLLLVLLVALFIFCI

CKRRKRNRRRKDEELEIKASRTSTVERGPKPHSTPAAAAQNSVALQAPPPPGHHLQT

PGHRPLPPGHRTREHQQKKRPPPSGTQIHQQKGPPLPRPRVQPKPPCGSGDGVSLPP

PN (SEQ ID NO: 164)

Human LFA-3
>NM_001779.3 Homo sapiens CD58 molecule (CD58),

(CD58)
transcript variant 1, mRNA

GAACTTAGGGCTGCTTGTGGCTGGGCACTCGCGCAGAGGCCGGCCCGACGAGCCATG

GTTGCTGGGAGCGACGCGGGGCGGGCCCTGGGGGTCCTCAGCGTGGTCTGCCTGCTG

CACTGCTTTGGTTTCATCAGCTGTTTTTCCCAACAAATATATGGTGTTGTGTATGGG

AATGTAACTTTCCATGTACCAAGCAATGTGCCTTTAAAAGAGGTCCTATGGAAAAAA

CAAAAGGATAAAGTTGCAGAACTGGAAAATTCTGAATTCAGAGCTTTCTCATCTTTT

AAAAATAGGGTTTATTTAGACACTGTGTCAGGTAGCCTCACTATCTACAACTTAACA

TCATCAGATGAAGATGAGTATGAAATGGAATCGCCAAATATTACTGATACCATGAAG

TTCTTTCTTTATGTGCTTGAGTCTCTTCCATCTCCCACACTAACTTGTGCATTGACT

AATGGAAGCATTGAAGTCCAATGCATGATACCAGAGCATTACAACAGCCATCGAGGA

CTTATAATGTACTCATGGGATTGTCCTATGGAGCAATGTAAACGTAACTCAACCAGT

ATATATTTTAAGATGGAAAATGATCTTCCACAAAAAATACAGTGTACTCTTAGCAAT

CCATTATTTAATACAACATCATCAATCATTTTGACAACCTGTATCCCAAGCAGCGGT

CATTCAAGACACAGATATGCACTTATACCCATACCATTAGCAGTAATTACAACATGT

ATTGTGCTGTATATGAATGGTATTCTGAAATGTGACAGAAAACCAGACAGAACCAAC

TCCAATTGATTGGTAACAGAAGATGAAGACAACAGCATAACTAAATTATTTTAAAAA

CTAAAAAGCCATCTGATTTCTCATTTGAGTATTACAATTTTTGAACAACTGTTGGAA

ATGTAACTTGAAGCAGCTGCTTTAAGAAGAAATACCCACTAACAAAGAACAAGCATT

AGTTTTGGCTGTCATCAACTTATTATATGACTAGGTGCTTGCTTTTTTTGTCAGTAA

ATTGTTTTTACTGATGATGTAGATACTTTTGTAAATAAATGTAAATATGTACACAAG

TGA (SEQ ID NO: 165)

>NP_001770.1 lymphocyte function-associated antigen 3

isoform 1 [Homo sapiens]

MVAGSDAGRALGVLSVVCLLHCFGFISCFSQQIYGVVYGNVTFHVPSNVPLKEVLWK

KQKDKVAELENSEFRAFSSFKNRVYLDTVSGSLTIYNLTSSDEDEYEMESPNITDTM

KFFLYVLESLPSPTLTCALINGSIEVQCMIPEHYNSHRGLIMYSWDCPMEQCKRNST

SIYFKMENDLPQKIQCTLSNPLFNTTSSIILTTCIPSSGHSRHRYALIPIPLAVITT

CIVLYMNGILKCDRKPDRINSN (SEQ ID NO: 166)

Human CD48
>NM_001778.4 Homo sapiens CD48 molecule (CD48),

transcript variant 1, mRNA

CTTTTTCTAGCCAGGCTCTCAACTGTCTCCTGCGTTGCTGGGAAGTTCTGGAAGGAA

GCATGTGCTCCAGAGGTTGGGATTCGTGTCTGGCTCTGGAATTGCTACTGCTGCCTC

TGTCACTCCTGGTGACCAGCATTCAAGGTCACTTGGTACATATGACCGTGGTCTCCG

GCAGCAACGTGACTCTGAACATCTCTGAGAGCCTGCCTGAGAACTACAAACAACTAA

CCTGGTTTTATACTTTCGACCAGAAGATTGTAGAATGGGATTCCAGAAAATCTAAGT

ACTTTGAATCCAAATTTAAAGGCAGGGTCAGACTTGATCCTCAGAGTGGCGCACTGT

ACATCTCTAAGGTCCAGAAAGAGGACAACAGCACCTACATCATGAGGGTGTTGAAAA

AGACTGGGAATGAGCAAGAATGGAAGATCAAGCTGCAAGTGCTTGACCCTGTACCCA

AGCCTGTCATCAAAATTGAGAAGATAGAAGACATGGATGACAACTGTTATCTGAAAC

TGTCATGTGTGATACCTGGCGAGTCTGTAAACTACACCTGGTATGGGGACAAAAGGC

CCTTCCCAAAGGAGCTCCAGAACAGTGTGCTTGAAACCACCCTTATGCCACATAATT

ACTCCAGGTGTTATACTTGCCAAGTCAGCAATTCTGTGAGCAGCAAGAATGGCACGG

TCTGCCTCAGTCCACCCTGTACCCTGGCCCGGTCCTTTGGAGTAGAATGGATTGCAA

GTTGGCTAGTGGTCACGGTGCCCACCATTCTTGGCCTGTTACTTACCTGAGATGAGC

TCTTTTAACTCAAGCGAAACTTCAAGGCCAGAAGATCTTGCCTGTTGGTGATCATGC

TCCTCACCAGGACAGAGACTGTATAGGCTGACCAGAAGCATGCTGCTGAATTATCAA

CGAGGATTTTCAAGTTAACTTTTAAATACTGGTTATTATTTAATTTTATATCCCTTT

GTTGTTTTCTAGTACACAGAGATATAGAGATACACATGCTTTTTTCCCACCCAAAAT

TGTGACAACATTATGTGAATGTTTTATTATTTTTTAAAATAAACATTTGATATAATT

GTCAATTAACTGAA (SEQ ID NO: 167)

>NP_001769.2 CD48 antigen isoform 1 precursor [Homo

sapiens]

MCSRGWDSCLALELLLLPLSLLVTSIQGHLVHMTVVSGSNVTLNISESLPENYKQLT

WFYTFDQKIVEWDSRKSKYFESKFKGRVRLDPQSGALYISKVQKEDNSTYIMRVLKK

TGNEQEWKIKLQVLDPVPKPVIKIEKIEDMDDNCYLKLSCVIPGESVNYTWYGDKRP

FPKELQNSVLETTLMPHNYSRCYTCQVSNSVSSKNGTVCLSPPCTLARSEGVEWIAS

WLVVTVPTILGLLLT (SEQ ID NO: 168)

Mouse CD48
>NM_007649.5 Mus musculus CD48 antigen (Cd48), transcript

variant 1, mRNA

ATACGACTTCCGGTTTTGGGTTTTGCTTCCTGATTGAAGGGCAGGCGCCCTGACTTC

TCTTACAGTTGTCTCCAGTGTTCTGGGGAAGCTTCTCTAAGTATTATGTGCTTCATA

AAACAGGGATGGTGTCTGGTCCTGGAACTGCTACTGCTGCCCTTGGGAACTGGATTT

CAAGGTCATTCAATACCAGATATAAATGCCACCACCGGCAGCAATGTAACCCTGAAA

ATCCATAAGGACCCACTTGGACCATATAAACGTATCACCTGGCTTCATACTAAAAAT

CAGAAGATTTTAGAGTACAACTATAATAGTACAAAGACAATCTTCGAGTCTGAATTT

AAAGGCAGGGTTTATCTTGAAGAAAACAATGGTGCACTTCATATCTCTAATGTCCGG

AAAGAGGACAAAGGTACCTACTACATGAGAGTGCTGCGTGAAACTGAGAACGAGTTG

AAGATAACCCTGGAAGTATTTGATCCTGTGCCCAAGCCTTCCATAGAAATCAATAAG

ACTGAAGCGTCGACTGATTCCTGTCACCTGAGGCTATCGTGTGAGGTAAAGGACCAG

CATGTTGACTATACTTGGTATGAGAGCTCGGGACCTTTCCCCAAAAAGAGTCCAGGA

TATGTGCTCGATCTCATCGTCACACCACAGAACAAGTCTACATTTTACACCTGCCAA

GTCAGCAATCCTGTAAGCAGCAAGAACGACACAGTGTACTTCACTCTACCTTGTGAT

CTAGCCAGATCTTCTGGAGTATGTTGGACTGCAACTTGGCTAGTGGTCACAACACTC

ATCATTCACAGGATCCTGTTAACCTGACAAGAACTCTTCTCACCCAAGAAGGCAACT

TGGAAGCACAGAGTCTTGCCTTCATCCCTAGCAGTGTTCCTAGCCAGCGAAGCAACT

CTGGCTCTATTGGACAAAGGAAAATGTGTTACTGAACGTCTGCGAGAGTTTGCATGC

ATGCTCTATGAAACAAGCACAGGACCTTGTACAGTGCTCCACCACTGACCTGTGTGC

CCAGTCCTTTACAAAGATTTCAAATCAACCTTTTAAAAACTGTGCATAATATCTAAT

TTTATATACCCTAGTTGTTTCCCAACATATATTAAAGATAAATGCATTCTTTTTACC

AAAATGTGACTATATTATTTTCATGTTTTCATATCTCTTTTTAAAATAAATTCTTTT

AAAAAACT (SEQ ID NO: 169)

>NP_031675.1 CD48 antigen isoform 1 precursor [Mus

musculus]

MCFIKQGWCLVLELLLLPLGTGFQGHSIPDINATTGSNVTLKIHKDPLGPYKRITWL

HTKNQKILEYNYNSTKTIFESEFKGRVYLEENNGALHISNVRKEDKGTYYMRVLRET

ENELKITLEVEDPVPKPSIEINKTEASTDSCHLRLSCEVKDQHVDYTWYESSGPFPK

KSPGYVLDLIVTPQNKSTFYTCQVSNPVSSKNDTVYFTLPCDLARSSGVCWTATWLV

VTTLIIHRILLT (SEQ ID NO: 170)

Human CD226
>NM_006566.4 Homo sapiens CD226 molecule (CD226),

transcript variant 1, mRNA

GCAGATGGGAAGAAGCGTTAGAGCGAGCAGCACTCACATCTCAAGAACCAGCCTTTC

AAACAGTTTCCAGAGATGGATTATCCTACTTTACTTTTGGCTCTTCTTCATGTATAC

AGAGCTCTATGTGAAGAGGTGCTTTGGCATACATCAGTTCCCTTTGCCGAGAACATG

TCTCTAGAATGTGTGTATCCATCAATGGGCATCTTAACACAGGTGGAGTGGTTCAAG

ATCGGGACCCAGCAGGATTCCATAGCCATTTTCAGCCCTACTCATGGCATGGTCATA

AGGAAGCCCTATGCTGAGAGGGTTTACTTTTTGAATTCAACGATGGCTTCCAATAAC

ATGACTCTTTTCTTTCGGAATGCCTCTGAAGATGATGTTGGCTACTATTCCTGCTCT

CTTTACACTTACCCACAGGGAACTTGGCAGAAGGTGATACAGGTGGTTCAGTCAGAT

AGTTTTGAGGCAGCTGTGCCATCAAATAGCCACATTGTTTCGGAACCTGGAAAGAAT

GTCACACTCACTTGTCAGCCTCAGATGACGTGGCCTGTGCAGGCAGTGAGGTGGGAA

AAGATCCAGCCCCGTCAGATCGACCTCTTAACTTACTGCAACTTGGTCCATGGCAGA

AATTTCACCTCCAAGTTCCCAAGACAAATAGTGAGCAACTGCAGCCACGGAAGGTGG

AGCGTCATCGTCATCCCCGATGTCACAGTCTCAGACTCGGGGCTTTACCGCTGCTAC

TTGCAGGCCAGCGCAGGAGAAAACGAAACCTTCGTGATGAGATTGACTGTAGCCGAG

GGTAAAACCGATAACCAATATACCCTCTTTGTGGCTGGAGGGACAGTTTTATTGTTG

TTGTTTGTTATCTCAATTACCACCATCATTGTCATTTTCCTTAACAGAAGGAGAAGG

AGAGAGAGAAGAGATCTATTTACAGAGTCCTGGGATACACAGAAGGCACCCAATAAC

TATAGAAGTCCCATCTCTACCAGTCAACCTACCAATCAATCCATGGATGATACAAGA

GAGGATATTTATGTCAACTATCCAACCTTCTCTCGCAGACCAAAGACTAGAGTTTAA

GCTTATTCTTGACATGAGTGCATTAGTAATGACTCTTATGTACTCATGCATGGATCT

TTATGCAATTTTTTTCCACTACCCAAGGTCTACCTTAGATACTAGTTGTCTGAATTG

AGTTACTTTGATAGGAAAAATACTTCATTACCTAAAATCATTTTTCATAGAACTGTT

TCAGAAAACCTGACTCTAACTGGTTTATATACAAAAGAAAACTTACTGTATCATATA

ACAGAATGATCCAGGGGAGATTAAGCTTTGGGCAAGGGCTATTTACCAGGGCTTAAA

TGTTGTGTCTAGAATTAAGTATGGGCATAAACTGGCTTCTGAATCCCTTTCCAGAGT

GTTGGATCCATTTCCCTGGTCTTGGCCTCACTCTCATGCAGGCTTTCCTCTTGTGTT

GGCAAGATGGCTGCCAACTCTTGGCAATTCATACATCCTTGTTTCTGTCTGGTAGAG

AGTTTGCTTCTCAAATGGAGCAAACAAATTTGATTATTTTTTCATTGTTAAATAGGC

AACATGACCAGAAAGGATGGAATGGCTTAAGTAAACTAAGGGTTCACTTCTAGAGCT

GAGAAGCAGGGTCAAAGCACAATACTGGGCAATTCAGAGCATGGTTAGAAGAGGAAA

GGGGAGTCTCAAAGCTGGAGAGTTTACCAACAAATATTGACTGCAGTGATTAACCAA

GACATTTTTGTTAACTAAAAAGTGAAATATGGGATGGATTCTAGAAATGGGGTATCT

CTGTCCATACTTCTAGAATCCACTCTATCAGCATAGTCCAGAAGAATACCTGGCAGT

AGAAGAAATGAATATTCAAGAGGAAGATAAATGCGAGAGGGCAATCCTTTACTATTC

TCATATTTATTTATCTCTCATTCTGTATAGAATTCTTGCCGCCATCCCAGGTCTAGC

CTTAGGAGCAAATGTAGTAGATAGTCGAATAATAAATAACTTAATGTTTTGGACATA

TTTTGTCTACTTTTGAGAATTATTTTTAATATGTAAATTCTCTCAAAAGGGTCAGGC

ACCTAGTTATTATTTTTTAATGATTATGTGAAAGTTGAATATAATATACCACTAAAA

GTGACAGTTGAAAGTGGTGGCATAGGACGGTAGGGTAGAAATTTGGGAGGGAAAAAA

GAAATTGGGAGGGTACAGGCAACAGGAGAAAGGAATCAAACCACAGAAAAATACAAA

GGGAAACTTCTGCTTCACTATTCAGACAAAGACAGCCCTAATGACATCACCAACAGT

CAAAGCAATTAGAGACCATACCTAATATTGTTTAAATTCTAGATGTAGGCTAACAAT

GAAAAGTATTTGCCAAACTGAATAAAACTGTCATGGTTACCTTGAAAGGACAATGGT

TATTGTTAAATATAGTGATCATTCATGTCTAAAAGATTCATTATTTATCTCTAAAGA

TTTCTAAAGACCACCATCTAGAAAAGATTCATTATGAAGGCTGTATTTAAATATCAA

AGTTGTGGACTTCATGATAATCTTAAATAAAGCAAATCCAAATTCTCCTGTTGCCTA

GACAGATTCTAAGATGTAATTTACACTTTTAAGCTAATTAGTGAGTATTTTATGATT

TTAGCCTTAAACACCATGTATGCCAAATAATGCACTTGTTTTGTGAATTACAGAAAT

GGTAAGTGCCCACATTTCTGTGAATTATAAAATTTGTGAGTTTCTTTTAACCCTTTT

CAGGAGTGAAAAAATAAAAACGACCATTTCCTGGTTGTGCTTAAGTATATGCAAGAA

GGGTAAACTCTCATTTTTATTATGTTTGCTTAAAGATCTTTTTATACCTGGATTCAT

GAAATGTTTCCACAAATATATTAGTGTAACAAACTTGAAAGGCAGTTTACAAGAAAG

CACTCTACTATCAGATCAATCAAAGATTCTGTGAGTGAATTTATTGGTTTGCATGGT

GAAGCAAGCTTAGCATCAATTAAAAGGTAAATAATTTCTTTTCTGAATGGTAAAGAC

AATCAAAATATTACTTTCTGGAAAACTCCAATAACCAAATTCTCAATGATTAGTGTA

TGTGAGCAGGAAAACATTTTTACAGTTGTAGTATGGGGAAATATAAATCCAATTTTA

AGAGAGAAAATTATGACTGGGTGTGGAAGGGACAGTATAGTCAGATACCATTGTCAT

GGTGGTTTTTACTGGGAACTTCATGAAAGACTTTTGTAGCAAACCACTGCAGTATTG

CAAAGCCTCCAGAACATTTGGAACTTGTCTCTTTTTCCTTGTGTGTGTTTGTGTTTT

TGGTCTCTCATTCAAAATATTGATGAGAACTATTTACTCTGTCCTTTCTTCTCTATA

TATTCTTCCTCTACAGAGTGTAGGGTTTTTTCAGGAATTTGGAGCCATCTGAAGTCC

TCCCAAAAATTCTCTGACGTCTTCTGATGCTCCTGTTATACCCTCAGGGGTAATGCT

TGTGAAATTCCATTCATTCATTTTCTTTCTCTGGACATCTTTACTTACCAAAGCACT

TTCATTGTCATCTTTTTAACATCATTCTTAATTCGTGATAGTTTTGGGACTCTCCCT

AGTGTATGTTTCTCCCCCTCTACTCTTTTGCACCTATGATTCTGATTGTTACTAAGA

AAGCAGATGAAAAACAGATCCACAGAATAAACGATCAGAATTCCAGTAAATTCTATT

TTAAATACAGATACTTTTTACAAGTTGCTGCTTTGGAAGCAAAATGCTTCTTAAGTT

TTACATATATATATATATATATACATATATATATACACATATAATTTATATCGATGG

ATAATACATTAAGAATCTATGCTTCCTTTGAATGCCATTAATATTTATGTTAAAGTA

ACCAATGAAAGGAAATTACTTTGTTATAATAAGATAGGAAGACTTGTTAATGGAGTA

CACAGTTTTGTCAGGGAAAGAACACATCTTATTGAACTATGATGACTATGCATTGAC

TATATTATTATAAGAGATACCTTCAAACTTTATTTAAAGAACTTTAGGTATAATATG

TTGAGAAAATAAAATAGAAATTTCATTTACTTGTAATCATGCTTAAAATGGGAGGCA

GGTAGGTGAAGATATAATTTTTAGTAAAAACTCCAATTTATGTTTTAAGTAATTCAG

TGTATTACTAAAATACTATATATATAAACTTAAAATACATGGGTTATCAATTTAAAA

GACAAAGTAAGTAAAAATACTTTTAGTAGGCATTCGTGGATTGTGAACATCCAAGTT

ATATTGGTTTGTATAGAATGGCATTAAGTAAAAATTACAGCTGTATAACAGTAGTTT

TCTAAATTGAGAGAGTCCACATTGTAATTAGAGATCACTGTGACCAAAATGCTTCTC

CTTGATTTATAATGATGTACTGTATTTTGTACTGCTTATATGAAATTTCAGCAAGAT

TGACGATATTATAAAGATGCTTATAAAGTGTAAGTGGAGACGCTAAATTGTGAGTAC

AAAGTTTCTTTTTCACAACAGTGATAAGAAAATATCTTTAAAAAATATAAGACAATA

TAAACATGTCATCATTAGTTTAGCTACTATTAAAATGTAACATCTAGAAAGTACTGA

TCTCCACCTTCAGACTTCTGTATAAGTATATTTTTTCACTGATCTGTTCATTAGAGT

TCTTCCAGCCAAGACTCTGGGCTCTTAAAACATGTATCTGAAAACTAAAAACAAGTT

AATTTTTTTAAAAGCTTCTCTATTTCTAGTGATTCAATAGGTAGAAAAATAGCTTCT

AGAATTAACTGCAATGCTTTCTAAGGAAATTTTATAAATCCTCAAGGTCGGTTTACA

CATATTTTTCCAGATTCAGAGCACTAACTATCTTGTAAGATGTAAGAAAAGGTCCAT

TTGGAAGTATGAGTAATAAATGTCTGGGATAATTCTGGTTTATTTCGTATTATCCTT

GTTAGAATAAGTTATATGGTCAACCTGTTCAGAACACTTTTTCTAGTGTTAGTGTGT

ACTTTTGGATTTTTGGTTCTTGTAGGGTATAGAAATATTTTCCTTTGTCTTGTATTC

TGTTGTTTTGAATGAATAAAACACAATGTTTCACGATCACTACTTTCATTTGCCATG

GAGAAATAGCAGGGAAAAATTTCTACAGAATAAAATTAACTGATGAATTACATGCAG

AAAAAATTCAAATCAATGATACATTGTAATTTTTATCTCAATGCAATGTTCTTTGTA

TTTTATTTTATTATTATTTTTTTGAGACGGAGTTTCACTTTTGTTGCCCGGGCTGGA

GTGCAATGGCACAATCTCGGCTCACCACAACCTCTGCCTCCCGGATTCAAGTGATTC

TCCTGCCTCAGCCTCCTGAATAGCTGGGATTACAGGCATATGCCAACATGCCTGGCT

AATTTTGTATTTTTAGTGGAGACGGGGTTTCTCCACGTTGGTCAGACTTGTCTTGAA

CTCTGGACCTCAGGTGATCCACCTGCCTCAGCCTCCTAAATTGCTGGGATTACAGGC

ATGAGCGACCACTCCTGGCCTTGTTCTTTGTATTTTATAAGTGCATGTAGTGCAAAG

GGTCAAAGGGCTTTACAGGTTTTTTGTTTGTTTGTTTTTGTTTTTCCCGAAACATAG

TAGTCCCTTGCCCTTCCTCATTTTTGTTACCTTGAGACAACAAATTTTACTACTTCT

AACTCATTATTTTATTTATGTTCACTTTTCTGAATAGCATGCTTATGACACTAATAC

TTTTTTTTTCAATTTTAGACATTCATTATTCATTTAGATGTCTTTCTCTCCCCAAAC

TCACCACATAAAATACTCTTCTCATGTCTCTTTCAGAAATATTTGTATTAAAATATG

ATTATATCAATATTTGGCATTTATTTCTTATGACCTTGCCAGTACTCTTAGTTAAAC

TACATGGTAAAAATGATTTTGCTTTCCCTCCTACATAACTTTTTTTCCACCTAGAGC

TAATAATTGTCATTCTGGGGACTGACTTTTTCTGTATTTACCATAAATTGACCTGAA

ACTCCCCTGTGATGCAGCAGGAATTCTACCAACGTCAACTTCCTTAGAAAGACTCCA

TTAGAAGCTTGACTTGGGGCTAGAAGGAGAGGCACACAACTGCCATCCTGGTGTCTC

CCTTCATCCAGAAAAAGGGGGAGGAATACATGAAACCTAGAATCCACTCTAAAACAT

TTTCCAGAACAAAAGGACATGTGTTTCCGTGTTGTAAATGTTTAACGAGTGCCCATA

ACAAGGAATAATAAGTCTATTATGTTTGCTTTTGTGTCTGTAAAAGTTGGGGGTATT

GGTTGTAAGCACGAAAACAGATACTGACTGTTGAAGAAAAAAAAAAATACGAGGTCA

GGAGTTTGAGACCAACTTGGCCAATATGGTGAAACCCTGTCTTAGTAAAAATAGAAA

AATTAGCCAGGCCTGGTGGCACGCACCTGTAGTCCCAGCTACTTGGGAGGCTGAGGC

AGAAGAATCGCTTGAACCCGGGAGGCAGAGGTTGCAGTGAGCCAAGATCGCACCACT

GCACTCCACCCTGGGCAACAGAGCGAGACTCCGTCTCAAAAAAAAAAAAAAAAAAAA

AAAAAAAAAGTTAAGTATTTGAACATAGGGGTGGCTCATAGAATTCCCAGGACACCC

GATGGAGTAGGCTTGCAAAACACAACATGTGGCAACTCCAGTGGGAAACGAGGCAGG

AAACACTCGTTTCCTGCAGAAAGCAACAATTTGGGCTTCGATACCCTCCCTAGAACA

CAGGGCAGTGAATCTGAGCAGCATCAGTACCCCACGTTCGGATGAGTCCTGAGCCCC

TATTTTTATTCACTGACTTATTCCAAAATCAGTGTCTCTTAAATATATCTGGAAGGC

AGCAGCTTGTATCTCCCCCTTCAGCTTCCATAGTGGCAGTCAGGGTACAACTTACTT

TCCAAACAGAACACACTGCGACATTCCCTCCAGGCTCGTTGAAGAACTTCAACTGAC

AAATGTCCCTCCTCGACCAGATGATAGTTTTCTTAAAGGCAGGGTTTAATATACCCT

TTTATAAATGTTTCAAGGCCCTGTGTAATACCTGAGTTTATTCCAGATGTAACTAAA

TATATCCAAGATTGTTTTAAAATAAATTGCTGAAAAAACAAATAAATACAGTTAGTA

TCTATATCAATATTCTCAGTTGGCAGTTTTGCAATAATGGCCGATAGTTCATTTTTA

GTAACACTATTGACATTGCATTTGGATATTAGGGTTTACTAATCATCCGCATGTATA

CATTGCATATTTTTCTAGACTTTAACTTTATTCAAATCTATTGATTTTTAAACCTGC

AACTTATGTCTAGACACAGGTATACCTTTACAAGAACTACCATTTTTTTTGGTAACA

TACTACCTCCAAAATTTCAAGTAAGAAGTTGATTTTTGTCCATTTTTAAATGGAAAA

CTTGTAATCAAAATGCCACAAAATTATACTGTGTATCATTTGACCTATAGAAACCAA

TATTATTACAGGAAGAAAGCAGAGCCAATCTTCTACCTGTGGTCAAATAAGTGGAGG

CCCTTTCTAGACTAAGTTCTCATGAGTTTAAAATACCAAGCATAAGTTCTCCAAATT

CCTGAAAAGGAAGCCTTGTGTTGTATTGCCCAGCCATATTTGTAAGACATAAAAATA

AAACTTGAGAAGAAGCTATGATAACTTACTTTCTTCATTCTTCAAAATTTACATAAT

CTCAACTGATTTTATGTTTTTATGAAAATGCATTCTTAAGATATATCCTTATTCAAT

CATGTATTCATTACATCCTTTATGCCAGGTATCCAAAAGTACTTACAGTGACTAAGA

CCATTATTCTTTGATCAGCTGCCTGAGTAAGACTTTGAGCTCTCCAATATACTCTCA

GTGATACTAAGTTTTCTGAGTAACAGCTTTGGATGTGGCTTCAGTTGAGCTGATTTA

TCCCACACTTTATTTTTATCGTATAATGGTCCTCAGAAGCAAATTTTGATTTTAGCT

CACATAAAAAATGTACAAAGAAATGTAATGGCTCAGTAGCTTCTAGAGATAGAGATT

ACTCTTCTAACCTTTCTGTAATTTTGTATGTCTATTTTATAATTCTTTCAATGTCTA

ATGAATAGCTATCTTTTTTTGAGACGGAGTCTCGCTCTGTCGCCCAGGCTGGAGTGC

AGTGGTGCGACCTCGGCTCACCGCAAGCTGCGTCTTCCAGGTTCACGCCATTCTCCT

GCCTCAGCCTCCCGAGTAGCTGGGACTTCAGGCGCCCACCACCATGCCCAGCTAATT

TTTTTGTATTTTTAGTAGAGACGGGGTTTCACCGTGTTAGCCAGGGTGGTCTCGATC

TCCTGACCTCGTGATCCGCCCGCCTCGGCCTCCCAACGTGCTGGGATTACAGGAGTG

AGCCACCGCGCCCGGCCTCCTTAGTTTCTTAAGGTGGAAGCCTAGATTATTGATTTT

ATATGTTGTTTTCTTTTCCAATAGTGGCACTTAATGCTATAAATTTCACTTTGTTCC

ACAAGTTTTGGTAAGCTCTATTTTTATTTTCATTTAGTCCAAAATATTTTAAAATTT

CTTTTGATATTTCTTCTTTGAGCCATGAATTATTTACAATGTGTTGTTTAATCTCTA

TATATTTTGGGATTTTTCTACTTTATATCTCTTACAGATTTCTAACTTAATTTCATC

ATGTTTTAAAAACATTCTTTGTATAATTTCTATTCTTTTAAATTTTTCAGGTGTATT

TTATGGCCCAGAATATGGTCTATCTTGTAGAATGTTTCATGTGATCTTAAGAAGAAT

GTTCATTCTGCTGTTGAGTGTAATATTCTACAAATGTCCATTAGATTAAACTGATTG

ATACCACCGTTCAGATTATCTATATCCTTTCTGATTTTCCCTCTTCTTGATCTATCA

CATACTGACAGATCAAGTGATCAAGTCTCGTTAAAGACTGCAAGTAAAATAGTGGAT

TTTTCTATTTCTCCTTGCAGTTTTGTTAGTTTTTGTCTCATGTATCTTGATACTCTT

GTTAGTACATATACTTTCAGAATCGTTAGGTTTTCTTGGAGAATTGACCCCTTTACC

ACATGTAATGTCCCTTTTATTCTTGATAATCTTTCTTGTTCTGTCTGCTTTTTCTGA

TATTAACATAACTTTCAGTTTTTTAAAAAATTAACATTAGCATCTCACATCTTTATC

CTTTTAATTTTAAATTATCTAAATATTTATATTTAATGTGCCTTTCTTATAGACAAT

GTATAGTTGCGTCTATTTGTAATTTCCCCACTTTTCTTACTTAAAAATGTTGTAGAT

ATATAGGAGTTGTATATATTTGGGGGGTACATGTGATGTTTTGATACCTGTATACAA

TATGTAATGATCATATTGGGTAATCGTGATATCTGTCACCTCTAACATTCATCTTTT

TTGTGTGTTTAAACCCACCACTTCTAATTGGTACATTTAGATTATTCAAATTTAAGT

GATTATTGATATAGTTGGATTAATATCTACTATGTTTGTAACTTTTCTATCCTTGCA

CTCGTTCTTTCTTTTTTATCCTCCTTTTTCTGTGTTCTCTGATTTTAACTGGGGTTT

TTACATGATTTAATTTTCTCTCGTGGCATATCTTTCATTGATCAACCTAGGTTTTTC

TCCTTTTCCCCTCTTTTTTTTGGTATTTATTCTATTTAGTGTTATCTGAGCTACCTG

AGTTGGTGTCTATCACTAATTTTGGCAAGTTCCCAGACGTTATTACTTCTAACATTC

TTTTGCTCCATTCTTTCTTCTTCTTCAATTATTCCATAGTCTTGAATATTCTGGGTT

TTTCCCACTCTTTGAATTTTAGTTTGAAAAGTTTCTATTGGCCTAGCTTCAAAGTCA

TTCATTCTTCCTTCGGGGTTCCAAGTCAACTGATAATTGCATCAAAGATATCCTTCC

TTTCTATTACTATGTTTTTTATTGCTACCATTTCTTTTTTATTCCTTCTTAGTGTTT

CCATCTTTCTTCTTACATTATCCATCTGTTGTCTATTTTTTTCATGAGAGCTCTTAA

CATATTAATGATAAGTTCCATGTCTGATAATTCTGACACGTGTCATGTCTCTATCTG

GTTCCAATGATTGCTTTATCTCTTCAGACCATGACTTTTCTTGCCTTTTGACGTTCT

TTGACATTTTTTTTGAATTTTTTGTTGCAAGCCAGATCTGGTGTGTTATGTAATAGG

AACAGGTAAATAAGTCTTTAGCTTGCAGACTTATCTTAATCTGACTAACTATTAGAC

TGTGTTTAAAGTCTGTTATAACCATAGGTGCTAAATTTCTTCAAATTCCTCTAGTGT

CTTTGTTTTGTTTGTTCATGTGTTTTTCCCCTTCTTGAGTTCAGGCTTCCCTAAGTG

CTCCTCTTCAGAGAGACTTTCTGTCTTTCAGCTCTTTCCTCTGCAATTCACTGTTAC

TATACTGGAGCCCTGTTGGTGTAGTACTAAGCTGTGGGAAAGGAGAGTGCTCTGTAA

TCTTACAGTGAAATCTCAGTCTTTTAGTGGGTCTGTGTCTGGGACATTCACAGAGCT

TCTCCAGTGGTATTGCTTCCTCATCCTCAACTCTCTTTCCTGGCTGCAGCATTCCCA

ATGTATTTCTTTGAAGGCCTGCCCCCTGTTGACTGTTATTTTCCCTCTTTCCTTAAG

TGGGACAGGGAGACTTCAGGGGCTGGGATGAGGTTTGGGAATTGTGCTTGGCAGAGT

CCTTTCCATCTTTGTTACCAAGAAGGTTCATGGCTTATTTCTCAATGGATGTCCCTC

TCTATCTGTTGCCAGAGCCACGAGGAAATTTTTCTTGGATCCTCATAATGAGAACCT

TGGAGTTTCCTACTGGAAAAGCCCTTGAATGTGTGGAGTGCCTCAAGAGCACAGCCC

CCATGGGTTTCTTGCTCACACCAGTCCACAAACAGATGCCAGCAATTCACCCAACTT

ACCATATAAAGGCTCATACTAGTTTATGGCTCCAGTGCTTTGACTCCAGATAAATGG

CTATTGGTTGCGTATCTCTCTGGATGTATCTGTATCTCCAGATTTTGGGGTGGCAGT

TTGCTCAGGACCTTGGTTCTCTAATAGGTCTAATAAGAAAAGTCATTGATTTTCAGC

TTTCCAACTTTCCAGCTTTGTCTTGTTATAAGCATGGCAGCAACATCTTCCATGCCT

TAACATGATGACACTAAAGGCAGAAGTCGATCTCCATGTATAAACATTTTAACACAT

ATGTTTTTTGTTATCGTGGTTTCTGACCTGTCTCTTTGCCCTGACTTTCTGATACTG

CACTAGGGTTCCTGTTGCTGGACTCCATTCCATATGACTTGCTCTCGTCTAGGCTGC

TCTTTGGCTCATCTTTATAAATCATGATCCAAAATGAAGCACATATTTATTTTTTAA

ATAAATATGAAATGAAGTATAGACATCAAACTGAAGATGAGTAGATCATACTGAGTT

TCACTGTCTGTGCTTGGATCAACATCAGGCCTTATACAAATATTCAAGTCCAGAGGC

AAAAGGTAATAAGGAAAATTTGTAGCACAAGCCACAAGGAGATAACATGTCAAGTCT

ATGCGATTGGAAATAAACTAAAGATGAACTGCTGGGGATGCTCACTCATCACAGAGC

TCAGTCTAAAGCACCAGATTTCACAAGCATTTTTTGGGGGAAATTCTGTTAAAATGA

AATATGAGTCACATGGTGGTGTTTCACTCATCATATGTGTTCAATATTAATTCATTT

TAAGGTTTAGTTGCACAAAAGGTAAATGAGAATTAGAAGACTCCATGGGTAAGAGGA

GCCACAGAAGTAAAGCATTGTCAAGGGTTCTATGTCTATATATTTAGATATTAGGCT

TCTGAGAAAAAAACACAATAGGAAGGAAGATGAACACAACAGAGGGCAGAAGGTCTA

TACGTCCTGAGGCCTTTTATGCAACGTTTGTTTGTGGAATGTTTTTTAAGAATGTGT

GAGAGTCATTTTAATGTGAAATAAAGACCTACGTCTACA (SEQ ID NO: 171)

>NP_006557.2 CD226 antigen isoform a precursor [Homo

sapiens]

MDYPTLLLALLHVYRALCEEVLWHTSVPFAENMSLECVYPSMGILTQVEWFKIGTQQ

DSIAIFSPTHGMVIRKPYAERVYFLNSTMASNNMTLFFRNASEDDVGYYSCSLYTYP

QGTWQKVIQVVQSDSFEAAVPSNSHIVSEPGKNVTLTCQPQMTWPVQAVRWEKIQPR

QIDLLTYCNLVHGRNFTSKFPRQIVSNCSHGRWSVIVIPDVTVSDSGLYRCYLQASA

GENETFVMRLTVAEGKTDNQYTLFVAGGTVLLLLFVISITTIIVIFLNRRRRRERRD

LFTESWDTQKAPNNYRSPISTSQPTNQSMDDTREDIYVNYPTESRRPKTRV (SEQ

ID NO: 172)

Mouse CD226
>NM_178687.2 Mus musculus CD226 antigen (Cd226),

transcript variant 1, mRNA

ACACAGAAGACTTCTTGACTTCAGGAGACACTGCTGTATGAAACAGTGCTTGCTATC

AGTGGCTGCTGGAAGAGGCTGTGGTGGAAAGAAAACCTCAACTGCAGGCCAGAGTTG

GTTCCCCAAAAGAGGCAAACTCCCAGTGCTAGCCAGAGGCTAGGAAGCTCTAAGCAA

CCCACTTATCTGCAAGGAGAGTTACGCCCAAAGAGCATCAAGTCCAACCTCCTGAAC

TGTTTCCAGAGATGGCTTATGTTACTTGGCTTTTGGCTATTCTTCATGTGCACAAAG

CACTGTGTGAAGAGACATTGTGGGACACAACAGTTCGGCTTTCTGAGACTATGACTC

TGGAATGTGTATATCCATTGACGCATAACTTAACCCAGGTGGAGTGGACCAAGAACA

CTGGCACAAAGACAGTGAGCATAGCAGTTTACAACCCTAACCATAATATGCATATAG

AATCTAACTACCTCCATAGAGTACACTTCCTAAACTCAACAGTGGGGTTCCGCAACA

TGAGCCTTTCCTTTTACAATGCCTCAGAAGCAGACATTGGCATCTACTCCTGCTTGT

TTCATGCTTTCCCAAATGGACCTTGGGAAAAGAAGATAAAAGTAGTCTGGTCAGATA

GTTTTGAGATAGCAGCACCCTCGGATAGCTACCTGTCTGCAGAACCTGGACAAGATG

TCACACTCACTTGCCAGCTTCCAAGGACTTGGCCAGTGCAACAAGTCATATGGGAAA

AAGTCCAGCCCCATCAGGTAGACATCTTAGCTTCCTGTAACCTATCTCAAGAGACAA

GATACACTTCAAAGTACCTAAGACAAACAAGGAGCAACTGTAGCCAGGGGAGCATGA

AGAGCATCCTCATCATTCCAAATGCCATGGCCGCTGACTCAGGACTTTACAGATGTC

GCTCAGAGGCCATTACAGGAAAAAACAAGTCCTTTGTCATAAGGCTGATCATAACTG

ATGGTGGAACCAATAAACATTTTATCCTTCCCATCGTTGGAGGGTTAGTTTCACTGT

TACTTGTCATCCTAATTATCATCATTTTCATTTTATATAACAGGAAGAGACGGAGAC

AGGTGAGAATTCCACTTAAAGAGCCCAGGGATAAACAGAGTAAGGTAGCCACCAACT

GCAGAAGTCCTACTTCTCCCATCCAGTCTACAGATGATGAAAAAGAGGACATTTATG

TAAACTATCCAACTTTCTCTCGAAGACCAAAACCAAGACTCTAAGCTGCTCTTTTGG

CCTGAACACATTAGTGATGACTTCTATGGCATGGAATTTTACCCATGATTTCCTTAC

CACTAGGATCTACATTGATAAAAAAAATTGATTAAATTTATTTCATCTCATATATAG

AAGTACTTTATTACCTGGAAACATTCTTAATAGAGATTCATTAGAAAACCCAAATCT

AATGTTCATGTGTTCAAGGAACCTTCTTCCATTATGTAACAGAACAGTCTAGAGAAG

ATTAAGGACCACATGGCTTTCTTGCTCTACTTGAAATTAATTGTGAGCATAAGCTTG

TTTCTGGAGTCTTCTTACATTGTTGGTTCTACTTACATACTACTGGTCCAACTCTCA

TGCTGTTTCTCTCAGATGTTCCCATGATGGTTGCCAAGGACACTTGATAGAAAGACT

ACTGGTTAAACACAATAAACAAAGTTCATTATTCACTTATTAGCAAGAAGGTAGCAT

TATCATAAAGGATTAGATGACTTAAGTTAGCTATAGGTTCAAGACCTGGACTAAAGT

ATTACTTGGAAATTCTGAGTATTGCTAAAAAGGAGGATGAAAGGGACCTAGAAGTTG

AGTTATTACTAAAAACTTTGAGTGCGAAGATATTACTCATTAACCAGATAACAAGTG

AATATGCTGTAGCATCAACATAATTCAAAAGAGTAAAGAAATGGCTAGGAATGAGGT

AGTTGTGTAATTATTTCTTCTCTTACTAGTTTCAAATAAATTCATCTCTAATTCTAT

AGAGAATTCTTGCCTCCCATTCAGGACTGGCCTTCTATACAGTGAGATGGTCCAGTA

AGAAATAATTTTTATTAGTGTTTTTTCTATTTTGAGAATTATTTTAATATATATTTT

AATATATAAACTTGTGAGTTAAATTTTTTTTTTGCAAAATTAGCACATGAAAAGAGA

TTGATGGTTTTAAGTAGTAGAACACAGTAGTGTAGGAATCTGAGAGCAGAGAGTTTG

GGAGGGGGTGAAGAGAAAACAACATCACCAAATAGTGATATATAAGAGAAAATCTGT

GCTTCAGAGTTTGATCAGGGCCATCTCTCCCAACTCTGCTGGAACTGAGAGAATGCA

CCTGATGTTGTCTCCATTTTAGATAGAGAAAAAAAAAACCCGAATATTTATAAAACT

AAATAAAACTATAGTTACCTCAAAACTATGGGGATCACTATAACATAGAATAGAATA

GAATAGAATAGAATAGAATAGAATAGAATAGAATAG (SEQ ID NO: 173)

>NP_848802.2 CD226 antigen isoform a precursor [Mus

musculus]

MAYVTWLLAILHVHKALCEETLWDTTVRLSETMTLECVYPLTHNLTQVEWTKNTGTK

TVSIAVYNPNHNMHIESNYLHRVHFLNSTVGFRNMSLSFYNASEADIGIYSCLFHAF

PNGPWEKKIKVVWSDSFEIAAPSDSYLSAEPGQDVTLTCQLPRTWPVQQVIWEKVQP

HQVDILASCNLSQETRYTSKYLRQTRSNCSQGSMKSILIIPNAMAADSGLYRCRSEA

ITGKNKSFVIRLIITDGGTNKHFILPIVGGLVSLLLVILIIIIFILYNRKRRRQVRI

PLKEPRDKQSKVATNCRSPTSPIQSTDDEKEDIYVNYPTFSRRPKPRL (SEQ ID

NO: 174)

Human DR3
>NM_003790.3 Homo sapiens TNF receptor superfamily member

25 (TNFRSF25), transcript variant 2, mRNA

GAAGGCGGAACCACGACGGGCAGAGAGCACGGAGCCGGGAAGCCCCTGGGCGCCCGT

CGGAGGGCTATGGAGCAGCGGCCGCGGGGCTGCGCGGCGGTGGCGGCGGCGCTCCTC

CTGGTGCTGCTGGGGGCCCGGGCCCAGGGCGGCACTCGTAGCCCCAGGTGTGACTGT

GCCGGTGACTTCCACAAGAAGATTGGTCTGTTTTGTTGCAGAGGCTGCCCAGCGGGG

CACTACCTGAAGGCCCCTTGCACGGAGCCCTGCGGCAACTCCACCTGCCTTGTGTGT

CCCCAAGACACCTTCTTGGCCTGGGAGAACCACCATAATTCTGAATGTGCCCGCTGC

CAGGCCTGTGATGAGCAGGCCTCCCAGGTGGCGCTGGAGAACTGTTCAGCAGTGGCC

GACACCCGCTGTGGCTGTAAGCCAGGCTGGTTTGTGGAGTGCCAGGTCAGCCAATGT

GTCAGCAGTTCACCCTTCTACTGCCAACCATGCCTAGACTGCGGGGCCCTGCACCGC

CACACACGGCTACTCTGTTCCCGCAGAGATACTGACTGTGGGACCTGCCTGCCTGGC

TTCTATGAACATGGCGATGGCTGCGTGTCCTGCCCCACGAGCACCCTGGGGAGCTGT

CCAGAGCGCTGTGCCGCTGTCTGTGGCTGGAGGCAGATGTTCTGGGTCCAGGTGCTC

CTGGCTGGCCTTGTGGTCCCCCTCCTGCTTGGGGCCACCCTGACCTACACATACCGC

CACTGCTGGCCTCACAAGCCCCTGGTTACTGCAGATGAAGCTGGGATGGAGGCTCTG

ACCCCACCACCGGCCACCCATCTGTCACCCTTGGACAGCGCCCACACCCTTCTAGCA

CCTCCTGACAGCAGTGAGAAGATCTGCACCGTCCAGTTGGTGGGTAACAGCTGGACC

CCTGGCTACCCCGAGACCCAGGAGGCGCTCTGCCCGCAGGTGACATGGTCCTGGGAC

CAGTTGCCCAGCAGAGCTCTTGGCCCCGCTGCTGCGCCCACACTCTCGCCAGAGTCC

CCAGCCGGCTCGCCAGCCATGATGCTGCAGCCGGGCCCGCAGCTCTACGACGTGATG

GACGCGGTCCCAGCGCGGCGCTGGAAGGAGTTCGTGCGCACGCTGGGGCTGCGCGAG

GCAGAGATCGAAGCCGTGGAGGTGGAGATCGGCCGCTTCCGAGACCAGCAGTACGAG

ATGCTCAAGCGCTGGCGCCAGCAGCAGCCCGCGGGCCTCGGAGCCGTTTACGCGGCC

CTGGAGCGCATGGGGCTGGACGGCTGCGTGGAAGACTTGCGCAGCCGCCTGCAGCGC

GGCCCGTGACACGGCGCCCACTTGCCACCTAGGCGCTCTGGTGGCCCTTGCAGAAGC

CCTAAGTACGGTTACTTATGCGTGTAGACATTTTATGTCACTTATTAAGCCGCTGGC

ACGGCCCTGCGTAGCAGCACCAGCCGGCCCCACCCCTGCTCGCCCCTATCGCTCCAG

CCAAGGCGAAGAAGCACGAACGAATGTCGAGAGGGGGTGAAGACATTTCTCAACTTC

TCGGCCGGAGTTTGGCTGAGATCGCGGTATTAAATCTGTGAAAGAAAACAAAACAAA

ACAAAAACGGCTTCTTGGCGTTTCTGCGGGGCTGGGGTGTTAAGTGGACTGGACTTT

TCTCGAGGGATTCGAAGGGGACGGGAATCTTGTCACCCCGGGATCTGGCACCCATGG

TGGAGTCCAGTGTGGCCTTAGCTCCCAAGCCTGCCCCTCCCGAGTCCACTCTGGCTC

AATTACCCCGAGAAGGAGAGAGCAAGTCGCGGCCACAGCGAGTGAGTGAACCGGAGC

CCAGATGAGAGCGCTTTAATGGGGCTGCGAGGTGGCGGAGACAGGGTCGGGATGGGG

TGCAGCAGTTGGAGACACAGGGTCAGGGCCCCTCATCCTCTATTCACTCCACCGGGG

CAGTGAAAGGGTCCCGGCAGCGAGTGGGTC (SEQ ID NO: 175)

>NP_003781.1 tumor necrosis factor receptor superfamily

member 25 isoform 2 precursor [Homo sapiens]

MEQRPRGCAAVAAALLLVLLGARAQGGTRSPRCDCAGDFHKKIGLFCCRGCPAGHYL

KAPCTEPCGNSTCLVCPQDTFLAWENHHNSECARCQACDEQASQVALENCSAVADTR

CGCKPGWFVECQVSQCVSSSPFYCQPCLDCGALHRHTRLLCSRRDTDCGTCLPGFYE

HGDGCVSCPTSTLGSCPERCAAVCGWRQMFWVQVLLAGLVVPLLLGATLTYTYRHCW

PHKPLVTADEAGMEALTPPPATHLSPLDSAHTLLAPPDSSEKICTVQLVGNSWTPGY

PETQEALCPQVTWSWDQLPSRALGPAAAPTLSPESPAGSPAMMLQPGPQLYDVMDAV

PARRWKEFVRTLGLREAEIEAVEVEIGRFRDQQYEMLKRWRQQQPAGLGAVYAALER

MGLDGCVEDLRSRLQRGP (SEQ ID NO: 176)

Mouse DR3
>NM_033042.4 Mus musculus tumor necrosis factor receptor

superfamily, member 25 (Tnfrsf25), transcript variant 2,

mRNA

CTGCGTGGAGGGGAAATGGGCCAGAGGCTGCTGGCAGGGGGCCTCCTCTGCTGTACA

CAAGCTGGTTTTGTAGACAGTGAGAGGGAAGCTGATCCCAGTCCCCTAACCCTGTTC

TGCCCAGGAGCCTGAGAACTGAGCTTACTCGGGCAAATGCTAGGGCTTCAGAAATGG

AGGAGCTGCCTAGGAGGGAGAGGTCACCTCCTGGGGCAGCCACACCAGGGTCAACTG

CACGTGTTCTCCAGCCTCTGTTCCTACCACTGCTGCTGCTGCTGCTGCTGCTGCTTG

GTGGCCAGGGCCAGGGCGGCATGTCTGGCAGGTGTGACTGTGCCAGTGAGTCCCAGA

AGAGGTATGGCCCGTTTTGTTGCAGGGGCTGCCCAAAGGGACACTACATGAAGGCCC

CCTGCGCAGAACCCTGTGGCAACTCCACCTGCCTTCCCTGTCCCTCGGACACCTTCT

TGACCAGAGACAACCACTTTAAGACTGACTGTACCCGCTGCCAAGTCTGTGATGAAG

AGGCCCTTCAAGTGACCCTTGAGAACTGCTCGGCAAAGTCGGACACCCACTGTGGCT

GCCAGTCAGGCTGGTGTGTTGACTGCTCCACCGAGCCATGTGGGAAAAGCTCACCTT

TCTCTTGTGTCCCATGCGGGGCTACAACACCAGTCCATGAGGCTCCAACCCCCCTGT

TTTGGGTCCAGGTGCTTCTAGGAGTCGCGTTCCTTTTTGGGGCTATCCTGATCTGTG

CATATTGTCGATGGCAGCCTTGTAAGGCCGTGGTCACTGCAGACACAGCTGGGACGG

AGACCCTGGCCTCACCACAGACTGCCCATCTCTCAGCCTCAGACAGCGCCCACACCC

TCCTGGCACCTCCAAGCAGTACTGGGAAAATCTGTACCACTGTCCAGTTGGTAGGCA

ACAACTGGACCCCTGGCTTATCCCAGACTCAGGAGGTGGTCTGCGGACAGGCCTCAC

AACCCTGGGATCAGCTGCCAAACAGAACTCTTGGAACTCCTCTGGCATCTCCGCTCT

CGCCAGCGCCCCCTGCGGGCTCTCCGGCTGCTGTGCTCCAGCCTGGCCCGCAGCTCT

ACGATGTGATGGATGCGGTCCCAGCACGAAGGTGGAAGGAGTTCGTGCGCACGCTGG

GGCTGCGGGAAGCGGAAATTGAAGCCGTGGAGGTGGAAATCTGCCGCTTCCGAGACC

AGCAGTATGAGATGCTCAAGCGCTGGCGTCAGCAGCAGCCTGCAGGCCTCGGTGCCA

TCTATGCGGCTCTGGAGCGCATGGGTCTGGAAGGCTGTGCCGAGGACCTGCGCAGCC

GCCTGCAGCGTGGCCCGTGATGGAAGGTCCATCAGCCACTTTGACACCCTAGTGACC

CTTGAAGGAGCCTTAAGTATTGTTACTTATGCGTGTAGACATTTTATGTCAATTACT

AACCCCCTGCCGTGGTCCTGCGTAGCAGGGCTGGCTGCCTCACTTTTGCTTATCTGC

AGCACGGAGCTCCTGCTAAGGGAAGCGTCATGGAGAAATACCAGAAGGGGCCAAGTG

ATTGGTTGCTCAGCTGTTAATTAGCCCGAGTTTGGACTTGGTATTAAATTTCGTAAG

AAAAGCAGCTGCTTG (SEQ ID NO: 177)

>NP_149031.2 tumor necrosis factor receptor superfamily

member 25 isoform 2 precursor [Mus musculus]

MEELPRRERSPPGAATPGSTARVLQPLFLPLLLLLLLLLGGQGQGGMSGRCDCASES

QKRYGPFCCRGCPKGHYMKAPCAEPCGNSTCLPCPSDTFLTRDNHFKTDCTRCQVCD

EEALQVTLENCSAKSDTHCGCQSGWCVDCSTEPCGKSSPFSCVPCGATTPVHEAPTP

LFWVQVLLGVAFLFGAILICAYCRWQPCKAVVTADTAGTETLASPQTAHLSASDSAH

TLLAPPSSTGKICTTVQLVGNNWTPGLSQTQEVVCGQASQPWDQLPNRTLGTPLASP

LSPAPPAGSPAAVLQPGPQLYDVMDAVPARRWKEFVRTLGLREAEIEAVEVEICRFR

DQQYEMLKRWRQQQPAGLGAIYAALERMGLEGCAEDLRSRLQRGP (SEQ ID NO:

178)

Human DcR3
>NM_003823.4 Homo sapiens TNF receptor superfamily member

6b (TNFRSF6B), mRNA

GGACTTGGGCGGCCCCTCCGCAGGCGGACCGGGGGCAAAGGAGGTGGCATGTCGGTC

AGGCACAGCAGGGTCCTGTGTCCGCGCTGAGCCGCGCTCTCCCTGCTCCAGCAAGGA

CCATGAGGGCGCTGGAGGGGCCAGGCCTGTCGCTGCTGTGCCTGGTGTTGGCGCTGC

CTGCCCTGCTGCCGGTGCCGGCTGTACGCGGAGTGGCAGAAACACCCACCTACCCCT

GGCGGGACGCAGAGACAGGGGAGCGGCTGGTGTGCGCCCAGTGCCCCCCAGGCACCT

TTGTGCAGCGGCCGTGCCGCCGAGACAGCCCCACGACGTGTGGCCCGTGTCCACCGC

GCCACTACACGCAGTTCTGGAACTACCTAGAGCGCTGCCGCTACTGCAACGTCCTCT

GCGGGGAGCGTGAGGAGGAGGCACGGGCTTGCCACGCCACCCACAACCGTGCCTGCC

GCTGCCGCACCGGCTTCTTCGCGCACGCTGGTTTCTGCTTGGAGCACGCATCGTGTC

CACCTGGTGCCGGCGTGATTGCCCCGGGCACCCCCAGCCAGAACACGCAGTGCCAGC

CGTGCCCCCCAGGCACCTTCTCAGCCAGCAGCTCCAGCTCAGAGCAGTGCCAGCCCC

ACCGCAACTGCACGGCCCTGGGCCTGGCCCTCAATGTGCCAGGCTCTTCCTCCCATG

ACACCCTGTGCACCAGCTGCACTGGCTTCCCCCTCAGCACCAGGGTACCAGGAGCTG

AGGAGTGTGAGCGTGCCGTCATCGACTTTGTGGCTTTCCAGGACATCTCCATCAAGA

GGCTGCAGCGGCTGCTGCAGGCCCTCGAGGCCCCGGAGGGCTGGGGTCCGACACCAA

GGGCGGGCCGCGCGGCCTTGCAGCTGAAGCTGCGTCGGCGGCTCACGGAGCTCCTGG

GGGCGCAGGACGGGGCGCTGCTGGTGCGGCTGCTGCAGGCGCTGCGCGTGGCCAGGA

TGCCCGGGCTGGAGCGGAGCGTCCGTGAGCGCTTCCTCCCTGTGCACTGATCCTGGC

CCCCTCTTATTTATTCTACATCCTTGGCACCCCACTTGCACTGAAAGAGGCTTTTTT

TTAAATAGAAGAAATGAGGTTTCTTAAAGCTTATTTTTATAAAGCTTTTTCATAAAA

(SEQ ID NO: 179)

>NP_003814.1 tumor necrosis factor receptor superfamily

member 6B precursor [Homo sapiens]

MRALEGPGLSLLCLVLALPALLPVPAVRGVAETPTYPWRDAETGERLVCAQCPPGTF

VQRPCRRDSPTTCGPCPPRHYTQFWNYLERCRYCNVLCGEREEEARACHATHNRACR

CRTGFFAHAGFCLEHASCPPGAGVIAPGTPSQNTQCQPCPPGTFSASSSSSEQCQPH

RNCTALGLALNVPGSSSHDTLCTSCTGFPLSTRVPGAEECERAVIDFVAFQDISIKR

LQRLLQALEAPEGWGPTPRAGRAALQLKLRRRLTELLGAQDGALLVRLLQALRVARM

PGLERSVRERFLPVH (SEQ ID NO: 180)

Human FasL
>NM_000639.3 Homo sapiens Fas ligand (FASLG), transcript

variant 1, mRNA

AGCAGTCAGCAACAGGGTCCCGTCCTTGACACCTCAGCCTCTACAGGACTGAGAAGA

AGTAAAACCGTTTGCTGGGGCTGGCCTGACTCACCAGCTGCCATGCAGCAGCCCTTC

AATTACCCATATCCCCAGATCTACTGGGTGGACAGCAGTGCCAGCTCTCCCTGGGCC

CCTCCAGGCACAGTTCTTCCCTGTCCAACCTCTGTGCCCAGAAGGCCTGGTCAAAGG

AGGCCACCACCACCACCGCCACCGCCACCACTACCACCTCCGCCGCCGCCGCCACCA

CTGCCTCCACTACCGCTGCCACCCCTGAAGAAGAGAGGGAACCACAGCACAGGCCTG

TGTCTCCTTGTGATGTTTTTCATGGTTCTGGTTGCCTTGGTAGGATTGGGCCTGGGG

ATGTTTCAGCTCTTCCACCTACAGAAGGAGCTGGCAGAACTCCGAGAGTCTACCAGC

CAGATGCACACAGCATCATCTTTGGAGAAGCAAATAGGCCACCCCAGTCCACCCCCT

GAAAAAAAGGAGCTGAGGAAAGTGGCCCATTTAACAGGCAAGTCCAACTCAAGGTCC

ATGCCTCTGGAATGGGAAGACACCTATGGAATTGTCCTGCTTTCTGGAGTGAAGTAT

AAGAAGGGTGGCCTTGTGATCAATGAAACTGGGCTGTACTTTGTATATTCCAAAGTA

TACTTCCGGGGTCAATCTTGCAACAACCTGCCCCTGAGCCACAAGGTCTACATGAGG

AACTCTAAGTATCCCCAGGATCTGGTGATGATGGAGGGGAAGATGATGAGCTACTGC

ACTACTGGGCAGATGTGGGCCCGCAGCAGCTACCTGGGGGCAGTGTTCAATCTTACC

AGTGCTGATCATTTATATGTCAACGTATCTGAGCTCTCTCTGGTCAATTTTGAGGAA

TCTCAGACGTTTTTCGGCTTATATAAGCTCTAAGAGAAGCACTTTGGGATTCTTTCC

ATTATGATTCTTTGTTACAGGCACCGAGAATGTTGTATTCAGTGAGGGTCTTCTTAC

ATGCATTTGAGGTCAAGTAAGAAGACATGAACCAAGTGGACCTTGAGACCACAGGGT

TCAAAATGTCTGTAGCTCCTCAACTCACCTAATGTTTATGAGCCAGACAAATGGAGG

AATATGACGGAAGAACATAGAACTCTGGGCTGCCATGTGAAGAGGGAGAAGCATGAA

AAAGCAGCTACCAGGTGTTCTACACTCATCTTAGTGCCTGAGAGTATTTAGGCAGAT

TGAAAAGGACACCTTTTAACTCACCTCTCAAGGTGGGCCTTGCTACCTCAAGGGGGA

CTGTCTTTCAGATACATGGTTGTGACCTGAGGATTTAAGGGATGGAAAAGGAAGACT

AGAGGCTTGCATAATAAGCTAAAGAGGCTGAAAGAGGCCAATGCCCCACTGGCAGCA

TCTTCACTTCTAAATGCATATCCTGAGCCATCGGTGAAACTAACAGATAAGCAAGAG

AGATGTTTTGGGGACTCATTTCATTCCTAACACAGCATGTGTATTTCCAGTGCAATT

GTAGGGGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTATGACTAAAGAGAGAATGT

AGATATTGTGAAGTACATATTAGGAAAATATGGGTTGCATTTGGTCAAGATTTTGAA

TGCTTCCTGACAATCAACTCTAATAGTGCTTAAAAATCATTGATTGTCAGCTACTAA

TGATGTTTTCCTATAATATAATAAATATTTATGTAGATGTGCATTTTTGTGAAATGA

AAACATGTAATAAAAAGTATATGTTAGGATACAAATAA (SEQ ID NO: 181)

>NP_000630.1 tumor necrosis factor ligand superfamily

member 6 isoform 1 [Homo sapiens]

MQQPFNYPYPQIYWVDSSASSPWAPPGTVLPCPTSVPRRPGQRRPPPPPPPPPLPPP

PPPPPLPPLPLPPLKKRGNHSTGLCLLVMFFMVLVALVGLGLGMFQLFHLQKELAEL

RESTSQMHTASSLEKQIGHPSPPPEKKELRKVAHLTGKSNSRSMPLEWEDTYGIVLL

SGVKYKKGGLVINETGLYFVYSKVYFRGQSCNNLPLSHKVYMRNSKYPQDLVMMEGK

MMSYCTTGQMWARSSYLGAVENLTSADHLYVNVSELSLVNFEESQTFFGLYKL

(SEQ ID NO: 182)

Mouse FasL
>NM_010177.4 Mus musculus Fas ligand (TNF superfamily,

member 6) (Fasl), transcript variant 1, mRNA

TGAGGCTTCTCAGCTTCAGATGCAAGTGAGTGGGTGTCTCACAGAGAAGCAAAGAGA

AGAGAACAGGAGAAAGGTGTTTCCCTTGACTGCGGAAACTTTATAAAGAAAACTTAG

CTTCTCTGGAGCAGTCAGCGTCAGAGTTCTGTCCTTGACACCTGAGTCTCCTCCACA

AGGCTGTGAGAAGGAAACCCTTTCCTGGGGCTGGGTGCCATGCAGCAGCCCATGAAT

TACCCATGTCCCCAGATCTTCTGGGTAGACAGCAGTGCCACTTCATCTTGGGCTCCT

CCAGGGTCAGTTTTTCCCTGTCCATCTTGTGGGCCTAGAGGGCCGGACCAAAGGAGA

CCGCCACCTCCACCACCACCTGTGTCACCACTACCACCGCCATCACAACCACTCCCA

CTGCCGCCACTGACCCCTCTAAAGAAGAAGGACCACAACACAAATCTGTGGCTACCG

GTGGTATTTTTCATGGTTCTGGTGGCTCTGGTTGGAATGGGATTAGGAATGTATCAG

CTCTTCCACCTGCAGAAGGAACTGGCAGAACTCCGTGAGTTCACCAACCAAAGCCTT

AAAGTATCATCTTTTGAAAAGCAAATAGCCAACCCCAGTACACCCTCTGAAAAAAAA

GAGCCGAGGAGTGTGGCCCATTTAACAGGGAACCCCCACTCAAGGTCCATCCCTCTG

GAATGGGAAGACACATATGGAACCGCTCTGATCTCTGGAGTGAAGTATAAGAAAGGT

GGCCTTGTGATCAACGAAACTGGGTTGTACTTCGTGTATTCCAAAGTATACTTCCGG

GGTCAGTCTTGCAACAACCAGCCCCTAAACCACAAGGTCTATATGAGGAACTCTAAG

TATCCTGAGGATCTGGTGCTAATGGAGGAGAAGAGGTTGAACTACTGCACTACTGGA

CAGATATGGGCCCACAGCAGCTACCTGGGGGCAGTATTCAATCTTACCAGTGCTGAC

CATTTATATGTCAACATATCTCAACTCTCTCTGATCAATTTTGAGGAATCTAAGACC

TTTTTCGGCTTGTATAAGCTTTAAAAGAAAAAGCATTTTAAAATGATCTACTATTCT

TTATCATGGGCACCAGGAATATTGTCTTGAATGAGAGTCTTCTTAAGACCTATTGAG

ATTAATTAAGACTACATGAGCCACAAAGACCTCATGACCGCAAGGTCCAACAGGTCA

GCTATCCTTCATTTTCTCGAGGTCCATGGAGTGGTCCTTAATGCCTGCATCATGAGC

CAGATGGAAGGAGGTCTGTGACTGAGGGACATAAAGCTTTGGGCTGCTGTGTGACAA

TGCAGAGGCACAGAGAAAGAACTGTCTGATGTTAAATGGCCAAGAGAATTTTAACCA

TTGAAGAAGACACCTTTACACTCACTTCCAGGGTGGGTCTACTTACTACCTCACAGA

GGCCGTTTTTGAGACATAGTTGTGGTATGAATATACAAGGGTGAGAAAGGAGGCTCA

TTTGACTGATAAGCTAGAGACTGAAAAAAAGACAGTGTCTCATTGGCACCATCTTTA

CTGTTACCTAATGTTTTCTGAGCCGACCTTTGATCCTAACGGAGAAGTAAGAGGGAT

GTTTGAGGCACAAATCATTCTCTACATAGCATGCATACCTCCAGTGCAATGATGTCT

GTGTGTTTGTATGTATGAGAGCAAACAGATTCTAAGGAGTCATATAAATAAAATATG

TACATTATGGAGTACATATTAGAAACCTGTTACATTTGATGCTAGATATCTGAATGT

TTCTTGGCAATAAACTCTAATAGTCTTCAAAATCTTTTATTATCAGCTACTGATGCT

GTTTTTCTTTAATACAACTAGTATTTATGCTCTGAACATCCTAATGAGGAAAAGACA

AATAAAATTATGTTATAGAATACAGAAATGCCTTAAGGACATAGACTTTGGAAA

(SEQ ID NO: 183)

>NP_034307.1 tumor necrosis factor ligand superfamily

member 6 isoform 1 [Mus musculus]

MQQPMNYPCPQIFWVDSSATSSWAPPGSVFPCPSCGPRGPDQRRPPPPPPPVSPLPP

PSQPLPLPPLTPLKKKDHNTNLWLPVVFFMVLVALVGMGLGMYQLFHLQKELAELRE

FTNQSLKVSSFEKQIANPSTPSEKKEPRSVAHLTGNPHSRSIPLEWEDTYGTALISG

VKYKKGGLVINETGLYFVYSKVYFRGQSCNNQPLNHKVYMRNSKYPEDLVLMEEKRL

NYCTTGQIWAHSSYLGAVFNLTSADHLYVNISQLSLINFEESKTFFGLYKL (SEQ

ID NO: 184)

Human TIM-1
>NM_012206.3 Homo sapiens hepatitis A virus cellular

(CD365)
receptor 1 (HAVCR1), transcript variant 1, mRNA

GACCAGGAGTCAGTTTGGCGGTTATGTGTGGGGAAGAAGCTGGGAAGTCAGGGGCTG

TTTCTGTGGACAGCTTTCCCTGTCCTTTGGAAGGCACAGAGCTCTCAGCTGCAGGGA

ACTAACAGAGCTCTGAAGCCGTTATATGTGGTCTTCTCTCATTTCCAGCAGAGCAGG

CTCATATGAATCAACCAACTGGGTGAAAAGATAAGTTGCAATCTGAGATTTAAGACT

TGATCAGATACCATCTGGTGGAGGGTACCAACCAGCCTGTCTGCTCATTTTCCTTCA

GGCTGATCCCATAATGCATCCTCAAGTGGTCATCTTAAGCCTCATCCTACATCTGGC

AGATTCTGTAGCTGGTTCTGTAAAGGTTGGTGGAGAGGCAGGTCCATCTGTCACACT

ACCCTGCCACTACAGTGGAGCTGTCACATCCATGTGCTGGAATAGAGGCTCATGTTC

TCTATTCACATGCCAAAATGGCATTGTCTGGACCAATGGAACCCACGTCACCTATCG

GAAGGACACACGCTATAAGCTATTGGGGGACCTTTCAAGAAGGGATGTCTCTTTGAC

CATAGAAAATACAGCTGTGTCTGACAGTGGCGTATATTGTTGCCGTGTTGAGCACCG

TGGGTGGTTCAATGACATGAAAATCACCGTATCATTGGAGATTGTGCCACCCAAGGT

CACGACTACTCCAATTGTCACAACTGTTCCAACCGTCACGACTGTTCGAACGAGCAC

CACTGTTCCAACGACAACGACTGTTCCAATGACGACTGTTCCAACGACAACTGTTCC

AACAACAATGAGCATTCCAACGACAACGACTGTTCTGACGACAATGACTGTTTCAAC

GACAACGAGCGTTCCAACGACAACGAGCATTCCAACAACAACAAGTGTTCCAGTGAC

AACAACTGTCTCTACCTTTGTTCCTCCAATGCCTTTGCCCAGGCAGAACCATGAACC

AGTAGCCACTTCACCATCTTCACCTCAGCCAGCAGAAACCCACCCTACGACACTGCA

GGGAGCAATAAGGAGAGAACCCACCAGCTCACCATTGTACTCTTACACAACAGATGG

GAATGACACCGTGACAGAGTCTTCAGATGGCCTTTGGAATAACAATCAAACTCAACT

GTTCCTAGAACATAGTCTACTGACGGCCAATACCACTAAAGGAATCTATGCTGGAGT

CTGTATTTCTGTCTTGGTGCTTCTTGCTCTTTTGGGTGTCATCATTGCCAAAAAGTA

TTTCTTCAAAAAGGAGGTTCAACAACTAAGTGTTTCATTTAGCAGCCTTCAAATTAA

AGCTTTGCAAAATGCAGTTGAAAAGGAAGTCCAAGCAGAAGACAATATCTACATTGA

GAATAGTCTTTATGCCACGGACTAAGACCCAGTGGTGCTCTTTGAGAGTTTACGCCC

ATGAGTGCAGAAGACTGAACAGACATCAGCACATCAGACGTCTTTTAGACCCCAAGA

CAATTTTTCTGTTTCAGTTTCATCTGGCATTCCAACATGTCAGTGATACTGGGTAGA

GTAACTCTCTCACTCCAAACTGTGTATAGTCAACCTCATCATTAATGTAGTCCTAAT

TTTTTATGCTAAAACTGGCTCAATCCTTCTGATCATTGCAGTTTTCTCTCAAATATG

AACACTTTATAATTGTATGTTCTTTTTAGACCCCATAAATCCTGTATACATCAAAGA

GAA (SEQ ID NO: 185)

>NP_036338.2 hepatitis A virus cellular receptor 1

isoform a precursor [Homo sapiens]

MHPQVVILSLILHLADSVAGSVKVGGEAGPSVTLPCHYSGAVTSMCWNRGSCSLFTC

QNGIVWTNGTHVTYRKDTRYKLLGDLSRRDVSLTIENTAVSDSGVYCCRVEHRGWFN

DMKITVSLEIVPPKVTTTPIVTTVPTVTTVRTSTTVPTTTTVPMTTVPTTTVPTTMS

IPTTTTVLTTMTVSTTTSVPTTTSIPTTTSVPVTTTVSTFVPPMPLPRQNHEPVATS

PSSPQPAETHPTTLQGAIRREPTSSPLYSYTTDGNDTVTESSDGLWNNNQTQLFLEH

SLLTANTTKGIYAGVCISVLVLLALLGVIIAKKYFFKKEVQQLSVSFSSLQIKALQN

AVEKEVQAEDNIYIENSLYATD (SEQ ID NO: 186)

Mouse TIM-1
>NM_134248.2 Mus musculus hepatitis A virus cellular

receptor 1 (Havcr1), transcript variant 1, mRNA

GTCAGTACCATGAATCAGATTCAAGTCTTCATTTCAGGCCTCATACTGCTTCTCCCA

GGCGCTGTGGATTCTTATGTGGAAGTAAAGGGGGTGGTGGGTCACCCTGTCACACTT

CCATGTACTTACTCAACATATCGTGGAATCACAACGACATGTTGGGGCCGAGGGCAA

TGCCCATCTTCTGCTTGTCAAAATACACTTATTTGGACCAATGGACATCGTGTCACC

TATCAGAAGAGCAGTCGGTACAACTTAAAGGGGCATATTTCAGAAGGAGATGTGTCC

TTGACGATAGAGAACTCTGTTGAGAGTGACAGTGGTCTGTATTGTTGTCGAGTGGAG

ATTCCTGGATGGTTTAATGATCAGAAAGTGACCTTTTCATTGCAAGTTAAACCAGAG

ATTCCCACACGTCCTCCAAGAAGACCCACAACTACAAGGCCCACAGCTACAGGAAGA

CCCACGACTATTTCAACAAGATCCACACATGTACCAACATCAACCAGAGTCTCTACC

TCCACTCCTCCAACATCTACACACACATGGACTCACAAACCAGAACCCACTACATTT

TGTCCCCATGAGACAACAGCTGAGGTGACAGGAATCCCATCCCATACTCCTACAGAC

TGGAATGGCACTGTGACATCCTCAGGAGATACCTGGAGTAATCACACTGAAGCAATC

CCTCCAGGGAAGCCGCAGAAAAACCCTACTAAGGGCTTCTATGTTGGCATCTGCATC

GCAGCCCTGCTGCTACTGCTCCTTGTGAGCACCGTGGCTATCACCAGGTACATACTT

ATGAAAAGGAAGTCAGCATCTCTAAGCGTGGTTGCCTTCCGTGTCTCTAAGATTGAA

GCTTTGCAGAACGCAGCGGTTGTGCATTCCCGAGCTGAAGACAACATCTACATTGTT

GAAGATAGACCTTGAGGGGCAGAATGAGTACCAGTGGCCCTCTGAGGGACCTTCTGC

CTGAGATTTATAGAGACTGTCACTGATGTCATAGAGTCACACCCATTACAGCGCCAA

GGCGATTTTCTGTGTTGGTTCTTCCAGCTGCAGCAGAGAGGGTAACCCTCTACTGTG

TATACTCAAAACTCAGATTAACATCATCCTAATTTTGGTATCTGCACCACCTCCGTG

TCTCTGCTCACTACAGAGATTCTCTCAAACATGAACGTTTTAGAAGTTTGTGTTTCC

CTTAGTCAATGTAATCATTGGTAATACTATTCTATTCTTGGTTACTAAAACCATTAC

TAAGAGAGGGATAGGAATTAAAAGTTGGTGTGAGGGGCCTCCTGAATTTAGAAGCAC

TTGATTCTGTTTTATCTACTTTCTTGAAATGTTACTTCTACCCTTCCCAATGGGTAA

AATCATGGGAGCATGGTGCCCTCATAGATAAATAGAAGAGAGTCTATTGCTGCCAAT

ATAGATGGTTATGCTTTCTCATAGCTCTGAAAATATGACACATTTATTATGAGGTTG

ATCTTAGGATAAGGATAGGTGTTTTATGTCAGGAGAGGTTATCATGGTGAATATGGA

CCAGCAGACAGCAGTGGAGGAAAATAATGAACCAAGGGATTGAGTTCATTAGTGCTA

ATTCTACTCCACTCCTGTCTTTATGCTCCTAAACTTACTGACTGAGCTCTGAATTAG

GTGCTAGGAGGAGACAATGCAGACATGAAAGGGGAAGGAGCGCCTTCAGGACACAGG

CTCTCTGCTGAGAGAAGTCCTATTTGCAGGTGTGATAGAGGTTGGGACAATCTCTGA

GTTGTAAATTTCTAATTGTCTTCAGGCCATATTTATAGTTAAATTCATTTCCGAAAG

ACATAGCATCTTCCCCAATGGGTCAGTTTGTCAAAATCAATAAAATATTTTGTTTTG

CTAAGAATTAAAAAAAAAAAAAAAAAAA (SEQ ID NO: 187)

>NP_599009.2 hepatitis A virus cellular receptor 1

homolog isoform a precursor [Mus musculus]

MNQIQVFISGLILLLPGAVDSYVEVKGVVGHPVTLPCTYSTYRGITTTCWGRGQCPS

SACQNTLIWINGHRVTYQKSSRYNLKGHISEGDVSLTIENSVESDSGLYCCRVEIPG

WFNDQKVTFSLQVKPEIPTRPPRRPTTTRPTATGRPTTISTRSTHVPTSTRVSTSTP

PTSTHTWTHKPEPTTFCPHETTAEVTGIPSHTPTDWNGTVTSSGDTWSNHTEAIPPG

KPQKNPTKGFYVGICIAALLLLLLVSTVAITRYILMKRKSASLSVVAFRVSKIEALQ

NAAVVHSRAEDNIYIVEDRP (SEQ ID NO: 188)

Human PD-1
>NM_005018.3 Homo sapiens programmed cell death 1

(PDCD1), mRNA

GCTCACCTCCGCCTGAGCAGTGGAGAAGGCGGCACTCTGGTGGGGCTGCTCCAGGCA

TGCAGATCCCACAGGCGCCCTGGCCAGTCGTCTGGGCGGTGCTACAACTGGGCTGGC

GGCCAGGATGGTTCTTAGACTCCCCAGACAGGCCCTGGAACCCCCCCACCTTCTCCC

CAGCCCTGCTCGTGGTGACCGAAGGGGACAACGCCACCTTCACCTGCAGCTTCTCCA

ACACATCGGAGAGCTTCGTGCTAAACTGGTACCGCATGAGCCCCAGCAACCAGACGG

ACAAGCTGGCCGCCTTCCCCGAGGACCGCAGCCAGCCCGGCCAGGACTGCCGCTTCC

GTGTCACACAACTGCCCAACGGGCGTGACTTCCACATGAGCGTGGTCAGGGCCCGGC

GCAATGACAGCGGCACCTACCTCTGTGGGGCCATCTCCCTGGCCCCCAAGGCGCAGA

TCAAAGAGAGCCTGCGGGCAGAGCTCAGGGTGACAGAGAGAAGGGCAGAAGTGCCCA

CAGCCCACCCCAGCCCCTCACCCAGGCCAGCCGGCCAGTTCCAAACCCTGGTGGTTG

GTGTCGTGGGCGGCCTGCTGGGCAGCCTGGTGCTGCTAGTCTGGGTCCTGGCCGTCA

TCTGCTCCCGGGCCGCACGAGGGACAATAGGAGCCAGGCGCACCGGCCAGCCCCTGA

AGGAGGACCCCTCAGCCGTGCCTGTGTTCTCTGTGGACTATGGGGAGCTGGATTTCC

AGTGGCGAGAGAAGACCCCGGAGCCCCCCGTGCCCTGTGTCCCTGAGCAGACGGAGT

ATGCCACCATTGTCTTTCCTAGCGGAATGGGCACCTCATCCCCCGCCCGCAGGGGCT

CAGCTGACGGCCCTCGGAGTGCCCAGCCACTGAGGCCTGAGGATGGACACTGCTCTT

GGCCCCTCTGACCGGCTTCCTTGGCCACCAGTGTTCTGCAGACCCTCCACCATGAGC

CCGGGTCAGCGCATTTCCTCAGGAGAAGCAGGCAGGGTGCAGGCCATTGCAGGCCGT

CCAGGGGCTGAGCTGCCTGGGGGCGACCGGGGCTCCAGCCTGCACCTGCACCAGGCA

CAGCCCCACCACAGGACTCATGTCTCAATGCCCACAGTGAGCCCAGGCAGCAGGTGT

CACCGTCCCCTACAGGGAGGGCCAGATGCAGTCACTGCTTCAGGTCCTGCCAGCACA

GAGCTGCCTGCGTCCAGCTCCCTGAATCTCTGCTGCTGCTGCTGCTGCTGCTGCTGC

TGCCTGCGGCCCGGGGCTGAAGGCGCCGTGGCCCTGCCTGACGCCCCGGAGCCTCCT

GCCTGAACTTGGGGGCTGGTTGGAGATGGCCTTGGAGCAGCCAAGGTGCCCCTGGCA

GTGGCATCCCGAAACGCCCTGGACGCAGGGCCCAAGACTGGGCACAGGAGTGGGAGG

TACATGGGGCTGGGGACTCCCCAGGAGTTATCTGCTCCCTGCAGGCCTAGAGAAGTT

TCAGGGAAGGTCAGAAGAGCTCCTGGCTGTGGTGGGCAGGGCAGGAAACCCCTCCAC

CTTTACACATGCCCAGGCAGCACCTCAGGCCCTTTGTGGGGCAGGGAAGCTGAGGCA

GTAAGCGGGCAGGCAGAGCTGGAGGCCTTTCAGGCCCAGCCAGCACTCTGGCCTCCT

GCCGCCGCATTCCACCCCAGCCCCTCACACCACTCGGGAGAGGGACATCCTACGGTC

CCAAGGTCAGGAGGGCAGGGCTGGGGTTGACTCAGGCCCCTCCCAGCTGTGGCCACC

TGGGTGTTGGGAGGGCAGAAGTGCAGGCACCTAGGGCCCCCCATGTGCCCACCCTGG

GAGCTCTCCTTGGAACCCATTCCTGAAATTATTTAAAGGGGTTGGCCGGGCTCCCAC

CAGGGCCTGGGTGGGAAGGTACAGGCGTTCCCCCGGGGCCTAGTACCCCCGCCGTGG

CCTATCCACTCCTCACATCCACACACTGCACCCCCACTCCTGGGGCAGGGCCACCAG

CATCCAGGCGGCCAGCAGGCACCTGAGTGGCTGGGACAAGGGATCCCCCTTCCCTGT

GGTTCTATTATATTATAATTATAATTAAATATGAGAGCATGCTAA (SEQ ID NO:

189)

>NP_005009.2 programmed cell death protein 1 precursor

[Homo sapiens]

MQIPQAPWPVVWAVLQLGWRPGWFLDSPDRPWNPPTFSPALLVVTEGDNATFTCSFS

NTSESFVLNWYRMSPSNQTDKLAAFPEDRSQPGQDCRFRVTQLPNGRDFHMSVVRAR

RNDSGTYLCGAISLAPKAQIKESLRAELRVTERRAEVPTAHPSPSPRPAGQFQTLVV

GVVGGLLGSLVLLVWVLAVICSRAARGTIGARRTGQPLKEDPSAVPVFSVDYGELDF

QWREKTPEPPVPCVPEQTEYATIVFPSGMGTSSPARRGSADGPRSAQPLRPEDGHCS

WPL (SEQ ID NO: 190)

Mouse PD-1
>NM_008798.3 Mus musculus programmed cell death 1

(Pdcd1), mRNA

TGAGCAGCGGGGAGGAGGAAGAGGAGACTGCTACTGAAGGCGACACTGCCAGGGGCT

CTGGGCATGTGGGTCCGGCAGGTACCCTGGTCATTCACTTGGGCTGTGCTGCAGTTG

AGCTGGCAATCAGGGTGGCTTCTAGAGGTCCCCAATGGGCCCTGGAGGTCCCTCACC

TTCTACCCAGCCTGGCTCACAGTGTCAGAGGGAGCAAATGCCACCTTCACCTGCAGC

TTGTCCAACTGGTCGGAGGATCTTATGCTGAACTGGAACCGCCTGAGTCCCAGCAAC

CAGACTGAAAAACAGGCCGCCTTCTGTAATGGTTTGAGCCAACCCGTCCAGGATGCC

CGCTTCCAGATCATACAGCTGCCCAACAGGCATGACTTCCACATGAACATCCTTGAC

ACACGGCGCAATGACAGTGGCATCTACCTCTGTGGGGCCATCTCCCTGCACCCCAAG

GCAAAAATCGAGGAGAGCCCTGGAGCAGAGCTCGTGGTAACAGAGAGAATCCTGGAG

ACCTCAACAAGATATCCCAGCCCCTCGCCCAAACCAGAAGGCCGGTTTCAAGGCATG

GTCATTGGTATCATGAGTGCCCTAGTGGGTATCCCTGTATTGCTGCTGCTGGCCTGG

GCCCTAGCTGTCTTCTGCTCAACAAGTATGTCAGAGGCCAGAGGAGCTGGAAGCAAG

GACGACACTCTGAAGGAGGAGCCTTCAGCAGCACCTGTCCCTAGTGTGGCCTATGAG

GAGCTGGACTTCCAGGGACGAGAGAAGACACCAGAGCTCCCTACCGCCTGTGTGCAC

ACAGAATATGCCACCATTGTCTTCACTGAAGGGCTGGGTGCCTCGGCCATGGGACGT

AGGGGCTCAGCTGATGGCCTGCAGGGTCCTCGGCCTCCAAGACATGAGGATGGACAT

TGTTCTTGGCCTCTTTGACCAGATTCTTCAGCCATTAGCATGCTGCAGACCCTCCAC

AGAGAGCACCGGTCCGTCCCTCAGTCAAGAGGAGCATGCAGGCTACAGTTCAGCCAA

GGCTCCCAGGGTCTGAGCTAGCTGGAGTGACAGCCCAGCGCCTGCACCAATTCCAGC

ACATGCACTGTTGAGTGAGAGCTCACTTCAGGTTTACCACAAGCTGGGAGCAGCAGG

CTTCCCGGTTTCCTATTGTCACAAGGTGCAGAGCTGGGGCCTAAGCCTATGTCTCCT

GAATCCTACTGTTGGGCACTTCTAGGGACTTGAGACACTATAGCCAATGGCCTCTGT

GGGTTCTGTGCCTGGAAATGGAGAGATCTGAGTACAGCCTGCTTTGAATGGCCCTGT

GAGGCAACCCCAAAGCAAGGGGGTCCAGGTATACTATGGGCCCAGCACCTAAAGCCA

CCCTTGGGAGATGATACTCAGGTGGGAAATTCGTAGACTGGGGGACTGAACCAATCC

CAAGATCTGGAAAAGTTTTGATGAAGACTTGAAAAGCTCCTAGCTTCGGGGGTCTGG

GAAGCATGAGCACTTACCAGGCAAAAGCTCCGTGAGCGTATCTGCTGTCCTTCTGCA

TGCCCAGGTACCTCAGTTTTTTTCAACAGCAAGGAAACTAGGGCAATAAAGGGAACC

AGCAGAGCTAGAGCCACCCACACATCCAGGGGGGCACTTGACTCTCCCTACTCCTCC

TAGGAACCAAAAGGACAAAGTCCATGTTGACAGCAGGGAAGGAAAGGGGGATATAAC

CTTGACGCAAACCAACACTGGGGTGTTAGAATCTCCTCATTCACTCTGTCCTGGAGT

TGGGTTCTGGCTCTCCTTCACACCTAGGACTCTGAAATGAGCAAGCACTTCAGACAG

TCAGGGTAGCAAGAGTCTAGCTGTCTGGTGGGCACCCAAAATGACCAGGGCTTAAGT

CCCTTTCCTTTGGTTTAAGCCCGTTATAATTAAATGGTACCAAAAGCTTTAA (SEQ

ID NO: 191)

>NP_032824.1 programmed cell death protein 1 precursor

[Mus musculus]

MWVRQVPWSFTWAVLQLSWQSGWLLEVPNGPWRSLTFYPAWLTVSEGANATFTCSLS

NWSEDLMLNWNRLSPSNQTEKQAAFCNGLSQPVQDARFQIIQLPNRHDFHMNILDTR

RNDSGIYLCGAISLHPKAKIEESPGAELVVTERILETSTRYPSPSPKPEGRFQGMVI

GIMSALVGIPVLLLLAWALAVFCSTSMSEARGAGSKDDTLKEEPSAAPVPSVAYEEL

DFQGREKTPELPTACVHTEYATIVFTEGLGASAMGRRGSADGLQGPRPPRHEDGHCS

WPL (SEQ ID NO: 191)

mScarlet
>KY021423.1 Synthetic construct mScarlet gene, partial

cds, mRNA

ATGGTGAGCAAGGGCGAGGCAGTGATCAAGGAGTTCATGCGGTTCAAGGTGCACATG

GAGGGCTCCATGAACGGCCACGAGTTCGAGATCGAGGGCGAGGGCGAGGGCCGCCCC

TACGAGGGCACCCAGACCGCCAAGCTGAAGGTGACCAAGGGTGGCCCCCTGCCCTTC

TCCTGGGACATCCTGTCCCCTCAGTTCATGTACGGCTCCAGGGCCTTCACCAAGCAC

CCCGCCGACATCCCCGACTACTATAAGCAGTCCTTCCCCGAGGGCTTCAAGTGGGAG

CGCGTGATGAACTTCGAGGACGGCGGCGCCGTGACCGTGACCCAGGACACCTCCCTG

GAGGACGGCACCCTGATCTACAAGGTGAAGCTCCGCGGCACCAACTTCCCTCCTGAC

GGCCCCGTAATGCAGAAGAAGACAATGGGCTGGGAAGCGTCCACCGAGCGGTTGTAC

CCCGAGGACGGCGTGCTGAAGGGCGACATTAAGATGGCCCTGCGCCTGAAGGACGGC

GGCCGCTACCTGGCGGACTTCAAGACCACCTACAAGGCCAAGAAGCCCGTGCAGATG

CCCGGCGCCTACAACGTCGACCGCAAGTTGGACATCACCTCCCACAACGAGGACTAC

ACCGTGGTGGAACAGTACGAACGCTCCGAGGGCCGCCACTCCACCGGCGGCATGGAC

GAGCTGTACAAG (SEQ ID NO: 192)

>APD76535.1 mScarlet, partial [synthetic construct]

MVSKGEAVIKEFMRFKVHMEGSMNGHEFEIEGEGEGRPYEGTQTAKLKVTKGGPLPF

SWDILSPQFMYGSRAFTKHPADIPDYYKQSFPEGFKWERVMNFEDGGAVTVTQDTSL

EDGTLIYKVKLRGTNFPPDGPVMQKKTMGWEASTERLYPEDGVLKGDIKMALRLKDG

GRYLADFKTTYKAKKPVQMPGAYNVDRKLDITSHNEDYTVVEQYERSEGRHSTGGMD

ELYK (SEQ ID NO: 193)

Nanoluciferase
>JQ513379.1 NanoLuc reporter vector pNL1.1.CMV

[Nluc/CMV], complete sequence, mRNA

GGCCTAACTGGCCTCAATATTGGCCATTAGCCATATTATTCATTGGTTATATAGCAT

AAATCAATATTGGCTATTGGCCATTGCATACGTTGTATCTATATCATAATATGTACA

TTTATATTGGCTCATGTCCAATATGACCGCCATGTTGGCATTGATTATTGACTAGTT

ATTAATAGTAATCAATTACGGGGTCATTAGTTCATAGCCCATATATGGAGTTCCGCG

TTACATAACTTACGGTAAATGGCCCGCCTGGCTGACCGCCCAACGACCCCCGCCCAT

TGACGTCAATAATGACGTATGTTCCCATAGTAACGCCAATAGGGACTTTCCATTGAC

GTCAATGGGTGGAGTATTTACGGTAAACTGCCCACTTGGCAGTACATCAAGTGTATC

ATATGCCAAGTCCGCCCCCTATTGACGTCAATGACGGTAAATGGCCCGCCTGGCATT

ATGCCCAGTACATGACCTTACGGGACTTTCCTACTTGGCAGTACATCTACGTATTAG

TCATCGCTATTACCATGGTGATGCGGTTTTGGCAGTACACCAATGGGCGTGGATAGC

GGTTTGACTCACGGGGATTTCCAAGTCTCCACCCCATTGACGTCAATGGGAGTTTGT

TTTGGCACCAAAATCAACGGGACTTTCCAAAATGTCGTAATAACCCCGCCCCGTTGA

CGCAAATGGGCGGTAGGCGTGTACGGTGGGAGGTCTATATAAGCAGAGCTCGTTTAG

TGAACCGTCAGATCACTAGAAGCTTTATTGCGGTAGTTTATCACAGTTAAATTGCTA

ACGCAGTCAGTGGGCCTCGGCGGCCAAGCTTGGCAATCCGGTACTGTTGGTAAAGCC

ACCATGGTCTTCACACTCGAAGATTTCGTTGGGGACTGGCGACAGACAGCCGGCTAC

AACCTGGACCAAGTCCTTGAACAGGGAGGTGTGTCCAGTTTGTTTCAGAATCTCGGG

GTGTCCGTAACTCCGATCCAAAGGATTGTCCTGAGCGGTGAAAATGGGCTGAAGATC

GACATCCATGTCATCATCCCGTATGAAGGTCTGAGCGGCGACCAAATGGGCCAGATC

GAAAAAATTTTTAAGGTGGTGTACCCTGTGGATGATCATCACTTTAAGGTGATCCTG

CACTATGGCACACTGGTAATCGACGGGGTTACGCCGAACATGATCGACTATTTCGGA

CGGCCGTATGAAGGCATCGCCGTGTTCGACGGCAAAAAGATCACTGTAACAGGGACC

CTGTGGAACGGCAACAAAATTATCGACGAGCGCCTGATCAACCCCGACGGCTCCCTG

CTGTTCCGAGTAACCATCAACGGAGTGACCGGCTGGCGGCTGTGCGAACGCATTCTG

GCGTAATTCTAGAGTCGGGGCGGCCGGCCGCTTCGAGCAGACATGATAAGATACATT

GATGAGTTTGGACAAACCACAACTAGAATGCAGTGAAAAAAATGCTTTATTTGTGAA

ATTTGTGATGCTATTGCTTTATTTGTAACCATTATAAGCTGCAATAAACAAGTTAAC

AACAACAATTGCATTCATTTTATGTTTCAGGTTCAGGGGGAGGTGTGGGAGGTTTTT

TAAAGCAAGTAAAACCTCTACAAATGTGGTAAAATCGATAAGGATCCGTCGACCGAT

GCCCTTGAGAGCCTTCAACCCAGTCAGCTCCTTCCGGTGGGCGCGGGGCATGACTAT

CGTCGCCGCACTTATGACTGTCTTCTTTATCATGCAACTCGTAGGACAGGTGCCGGC

AGCGCTCTTCCGCTTCCTCGCTCACTGACTCGCTGCGCTCGGTCGTTCGGCTGCGGC

GAGCGGTATCAGCTCACTCAAAGGCGGTAATACGGTTATCCACAGAATCAGGGGATA

ACGCAGGAAAGAACATGTGAGCAAAAGGCCAGCAAAAGGCCAGGAACCGTAAAAAGG

CCGCGTTGCTGGCGTTTTTCCATAGGCTCCGCCCCCCTGACGAGCATCACAAAAATC

GACGCTCAAGTCAGAGGTGGCGAAACCCGACAGGACTATAAAGATACCAGGCGTTTC

CCCCTGGAAGCTCCCTCGTGCGCTCTCCTGTTCCGACCCTGCCGCTTACCGGATACC

TGTCCGCCTTTCTCCCTTCGGGAAGCGTGGCGCTTTCTCATAGCTCACGCTGTAGGT

ATCTCAGTTCGGTGTAGGTCGTTCGCTCCAAGCTGGGCTGTGTGCACGAACCCCCCG

TTCAGCCCGACCGCTGCGCCTTATCCGGTAACTATCGTCTTGAGTCCAACCCGGTAA

GACACGACTTATCGCCACTGGCAGCAGCCACTGGTAACAGGATTAGCAGAGCGAGGT

ATGTAGGCGGTGCTACAGAGTTCTTGAAGTGGTGGCCTAACTACGGCTACACTAGAA

GAACAGTATTTGGTATCTGCGCTCTGCTGAAGCCAGTTACCTTCGGAAAAAGAGTTG

GTAGCTCTTGATCCGGCAAACAAACCACCGCTGGTAGCGGTGGTTTTTTTGTTTGCA

AGCAGCAGATTACGCGCAGAAAAAAAGGATCTCAAGAAGATCCTTTGATCTTTTCTA

CGGGGTCTGACGCTCAGTGGAACGAAAACTCACGTTAAGGGATTTTGGTCATGAGAT

TATCAAAAAGGATCTTCACCTAGATCCTTTTAAATTAAAAATGAAGTTTTAAATCAA

TCTAAAGTATATATGAGTAAACTTGGTCTGACAGCGGCCGCAAATGCTAAACCACTG

CAGTGGTTACCAGTGCTTGATCAGTGAGGCACCGATCTCAGCGATCTGCCTATTTCG

TTCGTCCATAGTGGCCTGACTCCCCGTCGTGTAGATCACTACGATTCGTGAGGGCTT

ACCATCAGGCCCCAGCGCAGCAATGATGCCGCGAGAGCCGCGTTCACCGGCCCCCGA

TTTGTCAGCAATGAACCAGCCAGCAGGGAGGGCCGAGCGAAGAAGTGGTCCTGCTAC

TTTGTCCGCCTCCATCCAGTCTATGAGCTGCTGTCGTGATGCTAGAGTAAGAAGTTC

GCCAGTGAGTAGTTTCCGAAGAGTTGTGGCCATTGCTACTGGCATCGTGGTATCACG

CTCGTCGTTCGGTATGGCTTCGTTCAACTCTGGTTCCCAGCGGTCAAGCCGGGTCAC

ATGATCACCCATATTATGAAGAAATGCAGTCAGCTCCTTAGGGCCTCCGATCGTTGT

CAGAAGTAAGTTGGCCGCGGTGTTGTCGCTCATGGTAATGGCAGCACTACACAATTC

TCTTACCGTCATGCCATCCGTAAGATGCTTTTCCGTGACCGGCGAGTACTCAACCAA

GTCGTTTTGTGAGTAGTGTATACGGCGACCAAGCTGCTCTTGCCCGGCGTCTATACG

GGACAACACCGCGCCACATAGCAGTACTTTGAAAGTGCTCATCATCGGGAATCGTTC

TTCGGGGCGGAAAGACTCAAGGATCTTGCCGCTATTGAGATCCAGTTCGATATAGCC

CACTCTTGCACCCAGTTGATCTTCAGCATCTTTTACTTTCACCAGCGTTTCGGGGTG

TGCAAAAACAGGCAAGCAAAATGCCGCAAAGAAGGGAATGAGTGCGACACGAAAATG

TTGGATGCTCATACTCGTCCTTTTTCAATATTATTGAAGCATTTATCAGGGTTACTA

GTACGTCTCTCAAGGATAAGTAAGTAATATTAAGGTACGGGAGGTATTGGACAGGCC

GCAATAAAATATCTTTATTTTCATTACATCTGTGTGTTGGTTTTTTGTGTGAATCGA

TAGTACTAACATACGCTCTCCATCAAAACAAAACGAAACAAAACAAACTAGCAAAAT

AGGCTGTCCCCAGTGCAAGTGCAGGTGCCAGAACATTTCTCT (SEQ ID NO:

194)

>AFJ15599.1 NanoLuc luciferase [NanoLuc reporter vector

pNL1.1.CMV [Nluc/CMV]]

MVFTLEDFVGDWRQTAGYNLDQVLEQGGVSSLFQNLGVSVTPIQRIVLSGENGLKID

IHVIIPYEGLSGDQMGQIEKIFKVVYPVDDHHFKVILHYGTLVIDGVTPNMIDYFGR

PYEGIAVFDGKKITVTGTLWNGNKIIDERLINPDGSLLFRVTINGVTGWRLCERILA

(SEQ ID NO: 195)

The polypeptides provided in Table 1 above are involved in a range of biological processes, including but not limited to, suppressing the adaptive arm of the immune system (e.g., PD-L1); cellular adhesion (e.g., nectin), immune activation (e.g., HVEM), and the like. The POI domains can also be used to track, purify, or identify the engineered EVs from native EVs (e.g., mScarlet and nanoluciferase). The genes, transcripts, polypeptides, and variants thereof can be used in any combination from Table 1 to be expressed by an engineered EV provided herein. In some embodiments, the POI domain is the human polypeptide. In some embodiments, the POI domain is a homologue of the human polypeptide (e.g., mouse).

In some embodiments of any of the aspects, the engineered cell or EV provided herein comprises an exogenous nucleic acid encoding one or more exogenous polypeptide(s) selected from the group consisting of: the polypeptides listed in Table 1.

In some embodiments of any of the aspects, the POI domain is PD-L1 or a fragment thereof. In some embodiments of any of the aspects, the POI domain is PD-L2 or a fragment thereof. In some embodiments of any of the aspects, the POI domain is FGL1 or a fragment thereof. In some embodiments of any of the aspects, the POI domain is 4-1BBL or a fragment thereof. In some embodiments of any of the aspects, the POI domain is CTLA or a fragment thereof.

In some embodiments of any of the aspects, the POI domain substantially binds to one or more of a target polypeptide. In some embodiments of any of the aspects, the target polypeptide is a cellular receptor. In some embodiments of any of the aspects, the target polypeptide is an immunosuppressive polypeptide. In some embodiments of any of the aspects, the target polypeptide is an immunostimulatory polypeptide. The engineered exosomes provided herein can be designed to activate, block, or modulate a given target polypeptide with the appropriate POI domain that binds to or modulates the function or expression of the target polypeptide. Non-limiting examples of target polypeptides include those listed in Table 2 (below).

TABLE 2

Exemplary Target Polypeptides

PD-1
VISTA
LAG-3
CD44

CD80
BTLA
CD112
IL10RA

CD86
CD160
CD200R
IL10RB

CD28
HVEM
CD200
Tim-3

ICOS
CD2
Galectin 9
TNFRSF25

CD28H
SLAM
TIM-3
TNFRSF6B

CD150

PD-L1
CD58
CD226
CD113

CTLA-4
TIM-1
CD155
CD27

4-1BB (CD137)
TIM-4
CD112
CD30

GITR
CD40
DR3
LFA-3 (CD58)

CD27L
CD30L
GITRL
CD40L

CD48
CD244
DcR3
CD28H

LFA-3 (CD58)
CD98
TNF Receptor
TNF receptor

Superfamily
associated

members
factor (TRAF)

family members

Butyrophilin
PD-L2
Nectin
TIM family

family members

members

B7/CD28 family
SLAM family
Nectin-like
Collagen family

members
members
binding receptors
proteins

LAIR-1 (CD305)

The EVs provided herein further comprise at least one fusion protein comprising a vesicle targeting domain. In various embodiments, the vesicle targeting domain provided herein is capable of binding or anchoring the fusion polypeptide provided herein to an extracellular vesicle, e.g., via targeting of the phospholipid bilayer membrane. In various embodiments, the vesicle targeting domain is a GPI domain (i.e., GPI linker, GPI anchor), fatty acetylation site, or prenylation site. One of skill in the art can appreciate that the aforementioned refer to peptide or protein sites, wherein covalent lipid attachment supports embedding of the lipid in a cell membrane (i.e., phospholipid bilayer). Biochemical forces that anchor EV targeting domains to the EV phospholipid bilayer may include, but are not limited to, electrostatic forces, affinity for EVs through protein-protein interactions with natively resident proteins (e.g., CD81, CD63, CD9, ALIX, TSG101. CD98, CD298, MARCKS, PTGFRN, Lactadherin (MFGe8)), association or affinity for negatively or positively curved phospholipids, association or affinity for negatively or positively charged domains of resident membrane associated proteins, etc., or the like.

Additional non-limiting examples of membrane targeting domains that can be used and their properties are further described in detail, e.g., Alberts B, Johnson A, Lewis J, et al., Molecular Biology of the Cell, 4th edition, New York: Garland Science, 2002. Membrane Proteins, https://www.ncbi.nlm.nih.gov/books/NBK26878/; Marilyn D. Resh, Fatty acylation of proteins: new insights into membrane targeting of myristoylated and palmitoylated proteins. Biochimica et Biophysica Acta (BBA)—Molecular Cell Research. Volume 1451, Issue 1, 12 Aug. 1999, Pages 1-16, doi.org/10.1016/S0167-4889(99)00075-0; Ann Apolloni, et. al., H-ras but Not K-ras Traffics to the Plasma Membrane through the Exocytic Pathway, Molecular and Cellular Biology April 2000, 20 (7) 2475-2487, DOI: 10.1128/MCB.20.7.2475-2487.2000; Rosie Dawaliby et. al., Phosphatidylethanolamine Is a Key Regulator of Membrane Fluidity in Eukaryotic Cells, Membrane Biology, VOLUME 291, ISSUE 7, doi.org/10.1074/jbc.M115.706523; R. J. Deschenes, Protein Palmitoylation, Encyclopedia of Biological Chemistry (Second Edition), Academic Press, 2013, Pages 645-647, ISBN 9780123786319, https://doi.org/10.1016/B978-0-12-378630-2.00022-0.; Charuta C. Palsuledesai and Mark D. Distefano, Protein Prenylation: Enzymes, Therapeutics, and Biotechnology Applications, ACS Chemical Biology 2015 10 (1), 51-62, DOI: 10.1021/cb500791f; Hung M E, Leonard J N. Stabilization of exosome-targeting peptides via engineered glycosylation, J Biol Chem, 2015 Mar. 27; 290(13):8166-72, doi: 10.1074/jbc.M114.621383; Udenwobele Daniel Ikenna, et. al., Myristoylation: An Important Protein Modification in the Immune Response, Frontiers in Immunology, Vol:8, 2017, DOI=10.3389/fimmu.2017.00751; Kinoshita Taroh 2020 Biosynthesis and biology of mammalian GPI-anchored proteins Open Biol. 10190290, http://doi.org/10.1098/rsob.190290, the contents of which are incorporated herein by reference in their entireties.

In some embodiments, the fusion polypeptide comprises one or more, two or more, three or more, four or more, five or more, or six or more vesicle targeting domains on the same polypeptide or nucleic acid construct encoding said polypeptide. For example, the fusion polypeptides provided herein can comprise PD-L1 and Glycosylphosphatidylinositol (GPI).

In some embodiments, the vesicle targeting domain is a prenylated protein. Prenylated proteins are proteins that have at least one prenylation site. Prenylation occurs when a 15-carbon or 20-carbon, farnesyl or geranylgeranyl isoprenoid, respectively, is covalently bound via a thioether bond to a cysteine at or near the carboxy terminus of a protein. In general, a prenylation site comprises an amino acid sequence CAAX, wherein C represents cysteine, A represents an aliphatic amino acid (glycine, alanine, valine, leucine, or isoleucine), and X represents alanine, methionine, serine, leucine, or glutamine.

In some embodiments, the vesicle targeting domain is a fatty acylated protein. Fatty acylated proteins are proteins that have been modified post-translationally by covalent attachment of one or more fatty acids, generally with a saturated fatty acid that comprises 14-carbon (e.g., myristic acid) via myristoylation or 16-carbons (e.g., palmitic acid) via palmitoylation. For example, proteins destined to become myristoylated begin with the amino acids Met-Gly-X-X-X followed by a serine or threonine at position 6 and lysine or arginine at position 7 and/or 8 wherein X can be any amino acid. The methionine is removed and a myristate is linked to the glycine via an amide bond. Palmitoylation herein means a posttranslational covalent attachment of fatty acids (e.g., palmitic acid) to cysteine (S-palmitoylation), serine and/or threonine (O-palmitoylation), and to the amino group of lysine (N-palmitoylation) of proteins.

Palmitoylated proteins may be acylated by attachment of a thioester linkage to a sulfhydryl group of cysteine, or via a palmitate linked to the amino group of an N-terminal cysteine. Palmitoylation sites may be present near the N- or C-terminus of a protein.

In some embodiments, the vesicle targeting domain is a glycosylphosphatidylinositol (GPI) anchor. A glycosylphosphatidylinositol (GPI) anchor (“GPI anchor”) or “GPI sticky binder” are used interchangeably and refer to a means of stably anchoring a protein to an outer leaflet (e.g., exterior layer of a phospholipid bilayer) of a cell membrane. A GPI anchor comprises a glycan, a phosphoethanolamine linker, a phospholipid tail, and may be modified by various glycan sidechains. The glycan core comprises phosphoinositol, glucosamine, and mannose residues wherein said mannose residues may be modified for example with phosphoethanolamine or carbohydrates. The phosphoethanolamine is amide-bonded to the carboxyl terminus of a protein during the process of GPI attachment. In some embodiments, the vesicle targeting domain may have affinity to EV resident proteins, e.g., CD81, CD63, CD9, ALIX, TSG101, CD98, CD298, MARCKS, PTGFRN, Lactadherin (MFGe8)

Sticky binders can include a sequence for one or more myristoylation and/or palmitoylation (Myr/Palm) sites fused to a transmembrane domain from 4F2 (CD98). For example, the myristoylation sequence from the MARCKS protein may be modified to encode for one or more myristoylation and palmitoylation sites, wherein the modified MARCKS protein sequence is fused to a protein sequence of the transmembrane domain from 4F2 via a covalent peptide bond. A Myr/Palm followed by the 4F2 transmembrane domain can improve loading of the fusion proteins provided herein when compared with 4F2 transmembrane domain alone or Myr/Palm alone.

Non-limiting examples of vesicle targeting domains that enhance fusion polypeptide structure and function on the extracellular vesicles are provided in Table 3 (below).

TABLE 3

Exosome Targeting Domain

Exosome Targeting

Domain/Sticky
Nucleic Acid Sequence (SEQ ID NO:)

Binder
Amino Acid Sequence (SEQ ID NO:)

Human CD55 (DAF)
>NM_000574.5 Homo sapiens CD55 molecule (Cromer blood

Glycosylphos
group) (CD55), transcript variant 1, mRNA

phatidylinositol
CTGCTTACTGCAACTCGCTCCGGCCGCTGGGCGTAGCTGCGACTCGGCGGAGTCCCG

(GPI)
GCGGCGCGTCCTTGTTCTAACCCGGCGCGCCATGACCGTCGCGCGGCCGAGCGTGCC

CGCGGCGCTGCCCCTCCTCGGGGAGCTGCCCCGGCTGCTGCTGCTGGTGCTGTTGTG

CCTGCCGGCCGTGTGGGGTGACTGTGGCCTTCCCCCAGATGTACCTAATGCCCAGCC

AGCTTTGGAAGGCCGTACAAGTTTTCCCGAGGATACTGTAATAACGTACAAATGTGA

AGAAAGCTTTGTGAAAATTCCTGGCGAGAAGGACTCAGTGATCTGCCTTAAGGGCAG

TCAATGGTCAGATATTGAAGAGTTCTGCAATCGTAGCTGCGAGGTGCCAACAAGGCT

AAATTCTGCATCCCTCAAACAGCCTTATATCACTCAGAATTATTTTCCAGTCGGTAC

TGTTGTGGAATATGAGTGCCGTCCAGGTTACAGAAGAGAACCTTCTCTATCACCAAA

ACTAACTTGCCTTCAGAATTTAAAATGGTCCACAGCAGTCGAATTTTGTAAAAAGAA

ATCATGCCCTAATCCGGGAGAAATACGAAATGGTCAGATTGATGTACCAGGTGGCAT

ATTATTTGGTGCAACCATCTCCTTCTCATGTAACACAGGGTACAAATTATTTGGCTC

GACTTCTAGTTTTTGTCTTATTTCAGGCAGCTCTGTCCAGTGGAGTGACCCGTTGCC

AGAGTGCAGAGAAATTTATTGTCCAGCACCACCACAAATTGACAATGGAATAATTCA

AGGGGAACGTGACCATTATGGATATAGACAGTCTGTAACGTATGCATGTAATAAAGG

ATTCACCATGATTGGAGAGCACTCTATTTATTGTACTGTGAATAATGATGAAGGAGA

GTGGAGTGGCCCACCACCTGAATGCAGAGGAAAATCTCTAACTTCCAAGGTCCCACC

AACAGTTCAGAAACCTACCACAGTAAATGTTCCAACTACAGAAGTCTCACCAACTTC

TCAGAAAACCACCACAAAAACCACCACACCAAATGCTCAAGCAACACGGAGTACACC

TGTTTCCAGGACAACCAAGCATTTTCATGAAACAACCCCAAATAAAGGAAGTGGAAC

CACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTT

GCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAGCCAAAGAAGAGTTAAGAAGA

AAATACACACAAGTATACAGACTGTTCCTAGTTTCTTAGACTTATCTGCATATTGGA

TAAAATAAATGCAATTGTGCTCTTCATTTAGGATGCTTTCATTGTCTTTAAGATGTG

TTAGGAATGTCAACAGAGCAAGGAGAAAAAAGGCAGTCCTGGAATCACATTCTTAGC

ACACCTACACCTCTTGAAAATAGAACAACTTGCAGAATTGAGAGTGATTCCTTTCCT

AAAAGTGTAAGAAAGCATAGAGATTTGTTCGTATTTAGAATGGGATCACGAGGAAAA

GAGAAGGAAAGTGATTTTTTTCCACAAGATCTGTAATGTTATTTCCACTTATAAAGG

AAATAAAAAATGAAAAACATTATTTGGATATCAAAAGCAAATAAAAACCCAATTCAG

TCTCTTCTAAGCAAAATTGCTAAAGAGAGATGAACCACATTATAAAGTAATCTTTGG

CTGTAAGGCATTTTCATCTTTCCTTCGGGTTGGCAAAATATTTTAAAGGTAAAACAT

GCTGGTGAACCAGGGGTGTTGATGGTGATAAGGGAGGAATATAGAATGAAAGACTGA

ATCTTCCTTTGTTGCACAAATAGAGTTTGGAAAAAGCCTGTGAAAGGTGTCTTCTTT

GACTTAATGTCTTTAAAAGTATCCAGAGATACTACAATATTAACATAAGAAAAGATT

ATATATTATTTCTGAATCGAGATGTCCATAGTCAAATTTGTAAATCTTATTCTTTTG

TAATATTTATTTATATTTATTTATGACAGTGAACATTCTGATTTTACATGTAAAACA

AGAAAAGTTGAAGAAGATATGTGAAGAAAAATGTATTTTTCCTAAATAGAAATAAAT

GATCCCATTTTTTGGTATCATGTAGTATGTGAAATTTATTCTTAAACGTGACTACTT

TATTTCTAAATAAGAAATTCCCTACCTGCTTCCTACAAGCAGTTCAGAATGCCATGC

CTTGGTTGTCCTAGTGTGAATAATTTTCAGCTACTTTAAAATTATATTGTACTTTCT

CAAGCATGTCATATCCTTTCCTATTAGAGTATCTATATTACTTGTTACTGATTTACC

TGAAGGCAATCTGATTAATTTCTAGGTTTTTACCATATTCTTGTCATCTTGCCAATT

ACATTTTAAGTGTTAGACTAGACTAAGATGTACTAGTTGTATAGAATATAACTAGA

TTTATTATGGCAATGTTTATTTTGTCATTTTGCTTCATCTGTTTTGTTGTTGAAGTA

CTTTAAATTTCATACGTTCATGGCATTTCACTGTAAAGACTTTAATGTGTATTTCTT

AAAATAAAACTTTTTTTCCTCCTTAA (SEQ ID NO: 196)

>NP_000565.1 complement decay-accelerating factor isoform

1 preproprotein [Homo sapiens]

MTVARPSVPAALPLLGELPRLLLLVLLCLPAVWGDCGLPPDVPNAQPALEGRTSFPE

DTVITYKCEESFVKIPGEKDSVICLKGSQWSDIEEFCNRSCEVPTRLNSASLKQPYI

TNYFPVGTVVEYECRPGYRREPSLSPKLTCLQNLKWSTAVEFCKKKSCPNPGEIRN

GQIDVPGGILFGATISFSCNTGYKLFGSTSSFCLISGSSVQWSDPLPECREIYCPAP

PQIDNGIIQGERDHYGYRQSVTYACNKGFTMIGEHSIYCTVNNDEGEWSGPPPECRG

KSLTSKVPPTVQKPTTVNVPTTEVSPTSQKTTTKTTTPNAQATRSTPVSRTTKHEHE

TTPNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT (SEQ ID NO: 197)

Human CD59
>NM_203330.2 Homo sapiens CD59 molecule (CD59 blood

Glycosylphos-
group) (CD59), transcript variant 1, mRNA

phatidylinositol
GGGGCCGGGGGGCGGAGCCTTGCGGGCTGGAGCGAAAGAATGCGGGGGCTGAGCGCA

(GPI)
GAAGCGGCTCGAGGCTGGAAGAGGATCTTGGGCGCCGCCAGTCTCTCTCTGTTGCCC

AAGCTGGAGTGCAGTGGCACAGTCTTGGCTCACTGCAACCTCCACCTCCTGGGTGCA

AGCGATTCTCGTGTCTCAGCCTCTCAAGTAGCTGGGATTACAGTCTTTAGCACCAGT

TGGTGTAGGAGTTGAGACCTACTTCACAGTAGTTCTGTGGACAATCACAATGGGAAT

CCAAGGAGGGTCTGTCCTGTTCGGGCTGCTGCTCGTCCTGGCTGTCTTCTGCCATTC

AGGTCATAGCCTGCAGTGCTACAACTGTCCTAACCCAACTGCTGACTGCAAAACAGC

CGTCAATTGTTCATCTGATTTTGATGCGTGTCTCATTACCAAAGCTGGGTTACAAGT

GTATAACAAGTGTTGGAAGTTTGAGCATTGCAATTTCAACGACGTCACAACCCGCTT

GAGGGAAAATGAGCTAACGTACTACTGCTGCAAGAAGGACCTGTGTAACTTTAACGA

ACAGCTTGAAAATGGTGGGACATCCTTATCAGAGAAAACAGTTCTTCTGCTGGTGAC

TCCATTTCTGGCAGCAGCCTGGAGCCTTCATCCCTAAGTCAACACCAGGAGAGCTTC

TCCCAAACTCCCCGTTCCTGCGTAGTCCGCTTTCTCTTGCTGCCACATTCTAAAGGC

TTGATATTTTCCAAATGGATCCTGTTGGGAAAGAATAAAATTAGCTTGAGCAACCTG

GCTAAGATAGAGGGGCTCTGGGAGACTTTGAAGACCAGTCCTGTTTGCAGGGAAGCC

CCACTTGAAGGAAGAAGTCTAAGAGTGAAGTAGGTGTGACTTGAACTAGATTGCATG

CTTCCTCCTTTGCTCTTGGGAAGACCAGCTTTGCAGTGACAGCTTGAGTGGGTTCTC

TGCAGCCCTCAGATTATTTTTCCTCTGGCTCCTTGGATGTAGTCAGTTAGCATCATT

AGTACATCTTTGGAGGGTGGGGCAGGAGTATATGAGCATCCTCTCTCACATGGAACG

CTTTCATAAACTTCAGGGATCCCGTGTTGCCATGGAGGCATGCCAAATGTTCCATAT

GTGGGTGTCAGTCAGGGACAACAAGATCCTTAATGCAGAGCTAGAGGACTTCTGGCA

GGGAAGTGGGGAAGTGTTCCAGATAGCAGGGCATGAAAACTTAGAGAGGTACAAGTG

GCTGAAAATCGAGTTTTTCCTCTGTCTTTAAATTTTATATGGGCTTTGTTATCTTCC

ACTGGAAAAGTGTAATAGCATACATCAATGGTGTGTTAAAGCTATTTCCTTGCCTTT

TTTTTATTGGAATGGTAGGATATCTTGGCTTTGCCACACACAGTTACAGAGTGAACA

CTCTACTACATGTGACTGGCAGTATTAAGTGTGCTTATTTTAAATGTTACTGGTAGA

AAGGCAGTTCAGGTATGTGTGTATATAGTATGAATGCAGTGGGGACACCCTTTGTGG

TTACAGTTTGAGACTTCCAAAGGTCATCCTTAATAACAACAGATCTGCAGGGGTATG

TTTTACCATCTGCATCCAGCCTCCTGCTAACTCCTAGCTGACTCAGCATAGATTGTA

TAAAATACCTTTGTAACGGCTCTTAGCACACTCACAGATGTTTGAGGCTTTCAGAAG

CTCTTCTAAAAAATGATACACACCTTTCACAAGGGCAAACTTTTTCCTTTTCCCTGT

GTATTCTAGTGAATGAATCTCAAGATTCAGTAGACCTAATGACATTTGTATTTTATG

ATCTTGGCTGTATTTAATGGCATAGGCTGACTTTTGCAGATGGAGGAATTTCTTGAT

TAATGTTGAAAAAAAACCCTTGATTATACTCTGTTGGACAAACCGAGTGCAATGAAT

GATGCTTTTCTGAAAATGAAATATAACAAGTGGGTGAATGTGGTTATGGCCGAAAAG

GATATGCAGTATGCTTAATGGTAGCAACTGAAAGAAGACATCCTGAGCAGTGCCAGC

TTTCTTCTGTTGATGCCGTTCCCTGAACATAGGAAAATAGAAACTTGCTTATCAAAA

CTTAGCATTACCTTGGTGCTCTGTGTTCTCTGTTAGCTCAGTGTCTTTCCTTACATC

AATAGGTTTTTTTTTTTTTTTTTGGCCTGAGGAAGTACTGACCATGCCCACAGCCAC

CGGCTGAGCAAAGAAGCTCATTTCATGTGAGTTCTAAGGAATGAGAAACAATTTTGA

TGAATTTAAGCAGAAAATGAATTTCTGGGAACTTTTTTGGGGGCGGGGGGGTGGGGA

ATTCAGCCACACTCCAGAAAGCCAGGAGTCGACAGTTTTGGAAGCCTCTCTCAGGAT

TGAGATTCTAGGATGAGATTGGCTTACTGCTATCTTGTGTCATGTACCCACTTTTTG

GCCAGACTACACTGGGAAGAAGGTAGTCCTCTAAAGCAAAATCTGAGTGCCACTAAA

TGGGGAGATGGGGCTGTTAAGCTGTCCAAATCAACAAGGGTCATATAAATGGCCTTA

AACTTTGGGGTTGCTTTCTGCAAAAAGTTGCTGTGACTCATGCCATAGACAAGGTTG

AGTGCCTGGACCCAAAGGCAATACTGTAATGTAAAGACATTTATAGTACTAGGCAAA

CAGCACCCCAGGTACTCCAGGCCCTCCTGGCTGGAGAGGGCTGTGGCAATAGAAAAT

TAGTGCCAACTGCAGTGAGTCAGCCTAGGTTAAATAGAGAGTGTAAGAGTGCTGGAC

AGGAACCTCCACCCTCATGTCACATTTCTTCAATGTGACCCTTCTGGCCCCTCTCCT

CCTGACAGCGGAACAATGACTGCCCCGATAGGTGAGGCTGGAGGAAGAATCAGTCCT

GTCCTTGGCAAGCTCTTCACTATGACAGTAAAGGCTCTCTGCCTGCTGCCAAGGCCT

GTGACTTTCTAACCTGGCCTCACGCTGGGTAAGCTTAAGGTAGAGGTGCAGGATTAG

CAAGCCCACCTGGCTACCAGGCCGACAGCTACATCCTCCAACTGACCCTGATCAACG

AAGAGGGATTCATGTGTCTGTCTCAGTTGGTTCCAAATGAAACCAGGGAGCAGGGGA

GTTAGGAATCGAACACCAGTCATGCCTACTGGCTCTCTGCTCGAGAGCCAATACCCT

GTGCCCTCCACTCATCTGGATTTACAGGAACTGTCATAGTGTTCAGTATTGGGTGGT

GATAAGCCCATTGGATTGTCCCCTTGGGGGGATGAGCTAGGGGTGCAAGGAACACCT

GATGAGTAGATAAGTGGAGCTCATGGTATTTCCTGAAAGATGCTAATCTATTTGCCA

AACTTGGTCTTGAATGTACTGGGGGCTTCAAGGTATGGGTATATTTTTCTTGTGTCC

TTGCAGTTAGCCCCCATGTCTTATGTGTGTCCTGAAAAAATAAGAGCCTGCCCAAGA

CTTTGGGCCTCTTGACAGAATTAACCACTTTTATACATCTGAGTTCTCTTGGTAAGT

TCTTTAGCAGTGTTCAAAGTCTACTAGCTCGCATTAGTTTCTGTTGCTGCCAACAGA

TCTGAACTAATGCTAACAGATCCCCCTGAGGGATTCTTGATGGGCTGAGCAGCTGGC

TGGAGCTAGTACTGACTGACATTCATTGTGATGAGGGCAGCTTTCTGGTACAGGATT

CTAAGCTCTATGTTTTATATACATTTTCATCTGTACTTGCACCTCACTTTACACAAG

AGGAAACTATGCAAAGTTAGCTGGATCGCTCAAGGTCACTTAGGTAAGTTGGCAAGT

CCATGCTTCCCACTCAGCTCCTCAGGTCAGCAAGTCTACTTCTCTGCCTATTTTGTA

TACTCTCTTTAATATGTGCCTAGCTTTGGAAAGTCTAGAATGGGTCCCTGGTGCCTT

TTTACTTTGAAGAAATCAGTTTCTGCCTCTTTTTGGAAAAGAAAACAAAGTGCAATT

GTTTTTTACTGGAAAGTTACCCAATAGCATGAGGTGAACAGGACGTAGTTAGGCCTT

CCTGTAAACAGAAAATCATATCAAAACACTATCTTCCCATCTGTTTCTCAATGCCTG

CTACTTCTTGTAGATATTTCATTTCAGGAGAGCAGCAGTTAAACCCGTGGATTTTGT

AGTTAGGAACCTGGGTTCAAACCCTCTTCCACTAATTGGCTATGTCTCTGGACAAGT

TTTTTTTTTTTTTTTTTTTTAAACCCTTTCTGAACTTTCACTTTCTATGTCTACCTC

AAAGAATTGTTGTGAGGCTTGAGATAATGCATTTGTAAAGGGTCTGCCAGATAGGAA

GATGCTAGTTATGGATTTACAAGGTTGTTAAGGCTGTAAGAGTCTAAAACCTACAGT

GAATCACAATGCATTTACCCCCACTGACTTGGACATAAGTGAAAACTAGCCAGAAGT

CTCTTTTTCAAATTACTTACAGGTTATTCAATATAAAATTTTTGTAATGGATAATCT

TATTTATCTAAACTAAAGCTTCCTGTTTATACACACTCCTGTTATTCTGGGATAAGA

TAAATGACCACAGTACCTTAATTTCTAGGTGGGTGCCTGTGATGGTTCATTGTAGGT

AAGGACATTTTCTCTTTTTCAGCAGCTGTGTAGGTCCAGAGCCTCTGGGAGAGGAGG

GGGGTAGCATGCACCCAGCAGGGGACTGAACTGGGAAACTCAAGGTTCTTTTTACTG

TGGGGTAGTGAGCTGCCTTTCTGTGATCGGTTTCCCTAGGGATGTTGCTGTTCCCCT

CCTTGCTATTCGCAGCTACATACAACGTGGCCAACCCCAGTAGGCTGATCCTATATA

TGATCAGTGCTGGTGCTGACTCTCAATAGCCCCACCCAAGCTGGCTATAGGTTTACA

GATACATTAATTAGGCAACCTAAAATATTGATGCTGGTGTTGGTGTGACATAATGCT

ATGGCCAGAACTGAAACTTAGAGTTATAATTCATGTATTAGGGTTCTCCAGAGGGAC

AGAATTAGTAGGATATATGTATATATGAAAGGGAGGTTATTAGGGAGAACTGGCTCC

CACAGTTAGAAGGCGAAGTCGCACAATAGGCCGTCTGCAAGCTGGGTTAGAGAGAAG

CCAGTAGTGGCTCAGCCTGAGTTCAAAAACCTCAAAACTGGGGAAGCTGACAGTGCA

GCCAGCCTTCAGTCTGTGGCCAAAGGCCCAAGAGCCCCTGGCAACCAACCCACTGGT

GCAAGTCCTAGATTCCAAAGGCTGAAGAACCTGGAGTCTGATGTCCAAGAGCAGGAA

GAGTGGAAGAAAGCCAGAAGACTCAGCAAACAAGGTAGACAGTGTCTACCACCATAG

TGGCCATACCAAAGAGGCTACCGATTCCTTCCTGCTACCTGGATCCCTGAAGTTGCC

CTGGTCTCTGCACCTTCTAAACCTAGTTCTTAAGAGCTTTCCATTACATGAGCTGTC

TCAAAGCCCTCCAATAAATTCTCAGTGTAAGCTTCTGTTGCTTGTGGACAGAAAATT

CTGACAGACCTACCCTATAAGTGTTACTGTCAGGATAACATGAGAACGCACAACAGT

AAGTGGTCACTAAGTGTTAGCTACGGTTATTTTGCCCAAGGTAGCATGGCTAGTTGA

TGCCGGTTGATGGGGCTTAAACCCAGCTCCCTCATCTTCCAGGCCTCTGTACTCCCT

ATTCCACTAAACTACCTCTCAGGTTTATTTTTTTAAATTCTTACTCTGCAAGTACAT

AGGACCACATTTACCTGGGAAAACAAGAATAAAGGCTGCTCTGCATTTTTTAGAAAC

TTTTTTGAAAGGGAGATGGGAATGCCTGCACCCCCAAGTCCAGACCAACACAATGGT

TAATTGAGATGAATAATAAAGGAAAGACTGTTCTGGGCTTCCCAGAATAGCTTGGTC

CTTAAATTGTGGCACAAACAACCTCCTGTCAGAGCCAGCCTCCTGCCAGGAAGAGGG

GTAGGAGACTAGAGGCCGTGTGTGCAGCCTTGCCCTGAAGGCTAGGGTGACAATTTG

GAGGCTGTCCAAACACCCTGGCCTCTAGAGCTGGCCTGTCTATTTGAAATGCCGGCT

CTGATGCTAATCGGCGACCCTCAGGCAAGTTACTTAACCTTACATGCCTCAGTTTTC

TCATCTGGAAAATGAGAACCCTAGGTTTAGGGTTGTTAGAAAAGTTAAATGAGTTAA

GACAAGTGCCTGGGACACAGTAGCCTCTTGTGTGTGTTTATCATTATGTCCTCAGCA

GGTCGTAGAAGCAGCTTCTCAGGTGTGAGGCTGGCGCGATTATCTGGAGTGGGTTGG

GTTTTCTAGGATGGACCCCCTGCTGCATTTTCCTCATTCATCCACCAGGGCTTAATG

GGGAATCAAGGAATCCATGTGTAACTGTATAATAACTGTAGCCACACTCCAATGACC

ACCTACTAGTTGTCCCTGGCACTGCTTATACATATGTCCATCAAATCAATCCTATGA

AGTAGATACTGTCTTCATTTTATAGATCAGAGACAATTGGGGTTCAGAGAGCTGATG

TGATTTTCCCAGGGTCACAGAGAGTCCCAGATTCAGGCACAACTCTTGTATTCCAAG

ACACAACCACTACATGTCCAAAGGCTGCCCAGAGCCACCGGGCACGGCAAATTGTGA

CATATCCCTAAAGAGGCTGAGCACCTGGTCAGGATCTGATGGCTGACAGTGTGTCCA

GATGCAGAGCTGGAGTGGGGGAGGGGAAGGGGGGCTCCTTGGGACAGAGAAGGCTTT

CTGTGCTTTCTCTGAAGGGAGCAGTCTGAGGACCAAGGGAACCCGGCAAACAGCACC

TCAGGTACTCCAGGCCCTCCTGGCTGGAGAGGGCTGTGGCAATGGAAAATTAGTGCC

AACTGCAATGAGTCAGCCTCGGTTAAATAGAGAGTGAAGAATGCTGGACAGGAACCT

CCACCCTCATGTCACATTTCTTCAGTGTGACCCTTCTGGCCCCTCTCCTCCTGACAG

CGGAACAATGACTGCCCCGATAGGTGAGGCTGGAGGAAGAATCAGTCCTGTCCTTGG

CAAGCTCTTCACTATGACAGTAAAGGCTCTCTGCCTGCTGCCAAGGCCTGTGACTTT

CTAACCTGGCCTCACGCTGGGTAAGCTTAAGGTAGAGGTGCAGGATTAGCAAGCCCA

CCTGGCTACCAGGCCGACAGCTACATCTTTCAACTGACCCTGATCAACGAAGAGGGA

CTTGTGTCTCTCAGTTGGTTCCAAATGAAACCAGGGAGCAGGGGCGTTAGGAAGCTC

CAACAGGATGGTACTTAATGGGGCATTTGAGTGGAGAGGTAGGTGACATAGTGCTTT

GGAGCCCAGGGAGGGAAAGGTTCTGCTGAAGTTGAATTCAAGACTGTTCTTTCATCA

CAAACTTGAGTTTCCTGGACATTTGTTTGCAGAAACAACCGTAGGGTTTTGCCTTAA

CCTCGTGGGTTTATTATTACCTCATAGGGACTTTGCCTCCTGACAGCAGTTTATGGG

TGTTCATTGTGGCACTTGAGTTTTCTTGCATACTTGTTAGAGAAACCAAGTTTGTCA

TCAACTTCTTATTTAACCCCCTGGCTATAACTTCATGGATTATGTTATAATTAAGCC

ATCCAGAGTAAAATCTGTTTAGATTATCTTGGAGTAAGGGGGAAAAAATCTGTAATT

TTTTCTCCTCAACTAGATATATACATAAAAAATGATTGTATTGCTTCATTTAAAAAA

TATAACGCAAAATCTCTTTTCCTTCTAAAAAAAAAAAAAAAAAA (SEQ ID NO:

197)

>NP_976075.1 CD59 glycoprotein preproprotein [Homo sapiens]

MGIQGGSVLFGLLLVLAVFCHSGHSLQCYNCPNPTADCKTAVNCSSDFDACLITKAG

LQVYNKCWKFEHCNENDVTTRLRENELTYYCCKKDLCNFNEQLENGGTSLSEKTVLL

LVTPFLAAAWSLHP (SEQ ID NO: 198)

Human C1C2 from
NM_005928.4 Homo sapiens milk fat globule-EGF factor 8

MFGE8
protein (MFGE8), transcript variant 1, mRNA

AGAACCCCGCGGGGTCTGAGCAGCCCAGCGTGCCCATTCCAGCGCCCGCGTCCCCGC

AGCATGCCGCGCCCCCGCCTGCTGGCCGCGCTGTGCGGCGCGCTGCTCTGCGCCCCC

AGCCTCCTCGTCGCCCTGGATATCTGTTCCAAAAACCCCTGCCACAACGGTGGTTTA

TGCGAGGAGATTTCCCAAGAAGTGCGAGGAGATGTCTTCCCCTCGTACACCTGCACG

TGCCTTAAGGGCTACGCGGGCAACCACTGTGAGACGAAATGTGTCGAGCCACTGGGC

CTGGAGAATGGGAACATTGCCAACTCACAGATCGCCGCCTCGTCTGTGCGTGTGACC

TTCTTGGGTTTGCAGCATTGGGTCCCGGAGCTGGCCCGCCTGAACCGCGCAGGCATG

GTCAATGCCTGGACACCCAGCAGCAATGACGATAACCCCTGGATCCAGGTGAACCTG

CTGCGGAGGATGTGGGTAACAGGTGTGGTGACGCAGGGTGCCAGCCGCTTGGCCAGT

CATGAGTACCTGAAGGCCTTCAAGGTGGCCTACAGCCTTAATGGACACGAATTCGAT

TTCATCCATGATGTTAATAAAAAACACAAGGAGTTTGTGGGTAACTGGAACAAAAAC

GCGGTGCATGTCAACCTGTTTGAGACCCCTGTGGAGGCTCAGTACGTGAGATTGTAC

CCCACGAGCTGCCACACGGCCTGCACTCTGCGCTTTGAGCTACTGGGCTGTGAGCTG

AACGGATGCGCCAATCCCCTGGGCCTGAAGAATAACAGCATCCCTGACAAGCAGATC

ACGGCCTCCAGCAGCTACAAGACCTGGGGCTTGCATCTCTTCAGCTGGAACCCCTCC

TATGCACGGCTGGACAAGCAGGGCAACTTCAACGCCTGGGTTGCGGGGAGCTACGGT

AACGATCAGTGGCTGCAGGTGGACCTGGGCTCCTCGAAGGAGGTGACAGGCATCATC

ACCCAGGGGGCCCGTAACTTTGGCTCTGTCCAGTTTGTGGCATCCTACAAGGTTGCC

TACAGTAATGACAGTGCGAACTGGACTGAGTACCAGGACCCCAGGACTGGCAGCAGT

AAGATCTTCCCTGGCAACTGGGACAACCACTCCCACAAGAAGAACTTGTTTGAGACG

CCCATCCTGGCTCGCTATGTGCGCATCCTGCCTGTAGCCTGGCACAACCGCATCGCC

CTGCGCCTGGAGCTGCTGGGCTGTTAGTGGCCACCTGCCACCCCCAGGTCTTCCTGC

TTTCCATGGGCCCGCTGCCTCTTGGCTTCTCAGCCCCTTTAAATCACCATAGGGCTG

GGGACTGGGGAAGGGGAGGGTGTTCAGAGGCAGCACCACCACACAGTCACCCCTCCC

TCCCTCTTTCCCACCCTCCACCTCTCACGGGCCCTGCCCCAGCCCCTAAGCCCCGTC

CCCTAACCCCCAGTCCTCACTGTCCTGTTTTCTTAGGCACTGAGGGATCTGAGTAGG

TCTGGGATGGACAGGAAAGGGCAAAGTAGGGCGTGTGGTTTCCCTGCCCCTGTCCGG

ACCGCCGATCCCAGGTGCGTGTGTCTCTGTCTCTCCTAGCCCCTCTCTCACACATCA

CATTCCCATGGTGGCCTCAAGAAAGGCCCGGAAGCGCCAGGCTGGAGATAACAGCCT

CTTGCCCGTCGGCCCTGCGTCGGCCCTGGGGTACCATGTGGCCACAACTGCTGTGGC

CCCCTGTCCCCAAGACACTTCCCCTTGTCTCCCTGGTTGCCTCTCTTGCCCCTTGTC

CTGAAGCCCAGCGACACAGAAGGGGGTGGGGGGGGTCTATGGGGAGAAAGGGAGCGA

GGTCAGAGGAGGGCATGGGTTGGCAGGGTGGGCGTTTGGGGCCCTCTATGCTGGCTT

TTCACCCCAGAGGACACAGGCAGCTTCCAAAATATATTTATCTTCTTCACGGGAA

(SEQ ID NO: 199)

>NP_005919.2 lactadherin isoform a preproprotein [Homo

sapiens]

MPRPRLLAALCGALLCAPSLLVALDICSKNPCHNGGLCEEISQEVRGDVFPSYTCTC

LKGYAGNHCETKCVEPLGLENGNIANSQIAASSVRVTFLGLQHWVPELARLNRAGMV

NAWTPSSNDDNPWIQVNLLRRMWVTGVVTQGASRLASHEYLKAFKVAYSLNGHEFDF

IHDVNKKHKEFVGNWNKNAVHVNLFETPVEAQYVRLYPTSCHTACTLRFELLGCELN

GCANPLGLKNNSIPDKQITASSSYKTWGLHLFSWNPSYARLDKQGNFNAWVAGSYGN

DQWLQVDLGSSKEVTGIITQGARNFGSVQFVASYKVAYSNDSANWTEYQDPRTGSSK

IFPGNWDNHSHKKNLFETPILARYVRILPVAWHNRIALRLELLGC (SEQ ID NO:

200)

Human 4F2 (CD98)
>NM_002394.6 Homo sapiens solute carrier family 3 member

2 (SLC3A2), transcript variant 3, mRNA

GCATTGCGGCTTGGTTTTCTCACCCAGTGCATGTGGCAGGAGCGGTGAGATCACTGC

CTCACGGCGATCCTGGACTGACGGTCACGACTGCCTACCCTCTAACCCTGTTCTGAG

CTGCCCCTTGCCCACACACCCCAAACCTGTGTGCAGGATCCGCCTCCATGGAGCTAC

AGCCTCCTGAAGCCTCGATCGCCGTCGTGTCGATTCCGCGCCAGTTGCCTGGCTCAC

ATTCGGAGGCTGGTGTCCAGGGTCTCAGCGCGGGGGACGACTCAGAGTTGGGGTCTC

ACTGTGTTGCCCAGACTGGTCTCGAACTCTTGGCCTCAGGTGATCCTCTTCCCTCAG

CTTCCCAGAATGCCGAGATGATAGAGACGGGGTCTGACTGTGTTACCCAGGCTGGTC

TTCAACTCTTGGCCTCAAGTGATCCTCCTGCCTTAGCTTCCAAGAATGCTGAGGTTA

CAGGCACCATGAGCCAGGACACCGAGGTGGATATGAAGGAGGTGGAGCTGAATGAGT

TAGAGCCCGAGAAGCAGCCGATGAACGCGGCGTCTGGGGCGGCCATGTCCCTGGCGG

GAGCCGAGAAGAATGGTCTGGTGAAGATCAAGGTGGCGGAAGACGAGGCGGAGGCGG

CAGCCGCGGCTAAGTTCACGGGCCTGTCCAAGGAGGAGCTGCTGAAGGTGGCAGGCA

GCCCCGGCTGGGTACGCACCCGCTGGGCACTGCTGCTGCTCTTCTGGCTCGGCTGGC

TCGGCATGCTTGCTGGTGCCGTGGTCATAATCGTGCGAGCGCCGCGTTGTCGCGAGC

TACCGGCGCAGAAGTGGTGGCACACGGGCGCCCTCTACCGCATCGGCGACCTTCAGG

CCTTCCAGGGCCACGGCGCGGGCAACCTGGCGGGTCTGAAGGGGCGTCTCGATTACC

TGAGCTCTCTGAAGGTGAAGGGCCTTGTGCTGGGTCCAATTCACAAGAACCAGAAGG

ATGATGTCGCTCAGACTGACTTGCTGCAGATCGACCCCAATTTTGGCTCCAAGGAAG

ATTTTGACAGTCTCTTGCAATCGGCTAAAAAAAAGAGCATCCGTGTCATTCTGGACC

TTACTCCCAACTACCGGGGTGAGAACTCGTGGTTCTCCACTCAGGTTGACACTGTGG

CCACCAAGGTGAAGGATGCTCTGGAGTTTTGGCTGCAAGCTGGCGTGGATGGGTTCC

AGGTTCGGGACATAGAGAATCTGAAGGATGCATCCTCATTCTTGGCTGAGTGGCAAA

ATATCACCAAGGGCTTCAGTGAAGACAGGCTCTTGATTGCGGGGACTAACTCCTCCG

ACCTTCAGCAGATCCTGAGCCTACTCGAATCCAACAAAGACTTGCTGTTGACTAGCT

CATACCTGTCTGATTCTGGTTCTACTGGGGAGCATACAAAATCCCTAGTCACACAGT

ATTTGAATGCCACTGGCAATCGCTGGTGCAGCTGGAGTTTGTCTCAGGCAAGGCTCC

TGACTTCCTTCTTGCCGGCTCAACTTCTCCGACTCTACCAGCTGATGCTCTTCACCC

TGCCAGGGACCCCTGTTTTCAGCTACGGGGATGAGATTGGCCTGGATGCAGCTGCCC

TTCCTGGACAGCCTATGGAGGCTCCAGTCATGCTGTGGGATGAGTCCAGCTTCCCTG

ACATCCCAGGGGCTGTAAGTGCCAACATGACTGTGAAGGGCCAGAGTGAAGACCCTG

GCTCCCTCCTTTCCTTGTTCCGGCGGCTGAGTGACCAGCGGAGTAAGGAGCGCTCCC

TACTGCATGGGGACTTCCACGCGTTCTCCGCTGGGCCTGGACTCTTCTCCTATATCC

GCCACTGGGACCAGAATGAGCGTTTTCTGGTAGTGCTTAACTTTGGGGATGTGGGCC

TCTCGGCTGGACTGCAGGCCTCCGACCTGCCTGCCAGCGCCAGCCTGCCAGCCAAGG

CTGACCTCCTGCTCAGCACCCAGCCAGGCCGTGAGGAGGGCTCCCCTCTTGAGCTGG

AACGCCTGAAACTGGAGCCTCACGAAGGGCTGCTGCTCCGCTTCCCCTACGCGGCCT

GACTTCAGCCTGACATGGACCCACTACCCTTCTCCTTTCCTTCCCAGGCCCTTTGGC

TTCTGATTTTTCTCTTTTTTAAAAACAAACAAACAAACTGTTGCAGATTATGAGTGA

ACCCCCAAATAGGGTGTTTTCTGCCTTCAAATAAAAGTCACCCCTGCATGGTGAA

(SEQ ID NO: 201)

>NP_002385.3 4F2 cell-surface antigen heavy chain isoform

c [Homo sapiens]

MELQPPEASIAVVSIPRQLPGSHSEAGVQGLSAGDDSELGSHCVAQTGLELLASGDP

LPSASQNAEMIETGSDCVTQAGLQLLASSDPPALASKNAEVTGTMSQDTEVDMKEVE

LNELEPEKQPMNAASGAAMSLAGAEKNGLVKIKVAEDEAEAAAAAKFTGLSKEELLK

VAGSPGWVRTRWALLLLFWLGWLGMLAGAVVIIVRAPRCRELPAQKWWHTGALYRIG

DLQAFQGHGAGNLAGLKGRLDYLSSLKVKGLVLGPIHKNQKDDVAQTDLLQIDPNFG

SKEDFDSLLQSAKKKSIRVILDLTPNYRGENSWESTQVDTVATKVKDALEFWLQAGV

DGFQVRDIENLKDASSFLAEWQNITKGFSEDRLLIAGTNSSDLQQILSLLESNKDLL

LTSSYLSDSGSTGEHTKSLVTQYLNATGNRWCSWSLSQARLLTSFLPAQLLRLYQLM

LFTLPGTPVFSYGDEIGLDAAALPGQPMEAPVMLWDESSFPDIPGAVSANMTVKGQS

EDPGSLLSLFRRLSDQRSKERSLLHGDFHAFSAGPGLFSYIRHWDQNERFLVVLNFG

DVGLSAGLQASDLPASASLPAKADLLLSTPGREEGSPLELERLKLEPHEGLLLREP

YAA (SEQ ID NO: 202)

Human TFR2
>NM_003227.4 Homo sapiens transferrin receptor 2 (TFR2),

transcript variant 1, mRNA

ATCGCTGGGGGACAGCCTGCAGGCTTCAGGAGGGGACACAAGCATGGAGCGGCTTTG

GGGTCTATTCCAGAGAGCGCAACAACTGTCCCCAAGATCCTCTCAGACCGTCTACCA

GCGTGTGGAAGGCCCCCGGAAAGGGCACCTGGAGGAGGAAGAGGAAGACGGGGAGGA

GGGGGCGGAGACATTGGCCCACTTCTGCCCCATGGAGCTGAGGGGCCCTGAGCCCCT

GGGCTCTAGACCCAGGCAGCCAAACCTCATTCCCTGGGCGGCAGCAGGACGGAGGGC

TGCCCCCTACCTGGTCCTGACGGCCCTGCTGATCTTCACTGGGGCCTTCCTACTGGG

CTACGTCGCCTTCCGAGGGTCCTGCCAGGCGTGCGGAGACTCTGTGTTGGTGGTCAG

TGAGGATGTCAACTATGAGCCTGACCTGGATTTCCACCAGGGCAGACTCTACTGGAG

CGACCTCCAGGCCATGTTCCTGCAGTTCCTGGGGGAGGGGCGCCTGGAGGACACCAT

CAGGCAAACCAGCCTTCGGGAACGGGTGGCAGGCTCGGCCGGGATGGCCGCTCTGAC

TCAGGACATTCGCGCGGCGCTCTCCCGCCAGAAGCTGGACCACGTGTGGACCGACAC

GCACTACGTGGGGCTGCAATTCCCGGATCCGGCTCACCCCAACACCCTGCACTGGGT

CGATGAGGCCGGGAAGGTCGGAGAGCAGCTGCCGCTGGAGGACCCTGACGTCTACTG

CCCCTACAGCGCCATCGGCAACGTCACGGGAGAGCTGGTGTACGCCCACTACGGGCG

GCCCGAAGACCTGCAGGACCTGCGGGCCAGGGGCGTGGATCCAGTGGGCCGCCTGCT

GCTGGTGCGCGTGGGGGTGATCAGCTTCGCCCAGAAGGTGACCAATGCTCAGGACTT

CGGGGCTCAAGGAGTGCTCATATACCCAGAGCCAGCGGACTTCTCCCAGGACCCACC

CAAGCCAAGCCTGTCCAGCCAGCAGGCAGTGTATGGACATGTGCACCTGGGAACTGG

AGACCCCTACACACCTGGCTTCCCTTCCTTCAATCAAACCCAGTTCCCTCCAGTTGC

ATCATCAGGCCTTCCCAGCATCCCAGCCCAGCCCATCAGTGCAGACATTGCCTCCCG

CCTGCTGAGGAAGCTCAAAGGCCCTGTGGCCCCCCAAGAATGGCAGGGGAGCCTCCT

AGGCTCCCCTTATCACCTGGGCCCCGGGCCACGACTGCGGCTAGTGGTCAACAATCA

CAGGACCTCCACCCCCATCAACAACATCTTCGGCTGCATCGAAGGCCGCTCAGAGCC

AGATCACTACGTTGTCATCGGGGCCCAGAGGGATGCATGGGGCCCAGGAGCAGCTAA

ATCCGCTGTGGGGACGGCTATACTCCTGGAGCTGGTGCGGACCTTTTCCTCCATGGT

GAGCAACGGCTTCCGGCCCCGCAGAAGTCTCCTCTTCATCAGCTGGGACGGTGGTGA

CTTTGGAAGCGTGGGCTCCACGGAGTGGCTAGAGGGCTACCTCAGCGTGCTGCACCT

CAAAGCCGTAGTGTACGTGAGCCTGGACAACGCAGTGCTGGGGGATGACAAGTTTCA

TGCCAAGACCAGCCCCCTTCTGACAAGTCTCATTGAGAGTGTCCTGAAGCAGGTGGA

TTCTCCCAACCACAGTGGGCAGACTCTCTATGAACAGGTGGTGTTCACCAATCCCAG

CTGGGATGCTGAGGTGATCCGGCCCCTACCCATGGACAGCAGTGCCTATTCCTTCAC

GGCCTTTGTGGGAGTCCCTGCCGTCGAGTTCTCCTTTATGGAGGACGACCAGGCCTA

CCCATTCCTGCACACAAAGGAGGACACTTATGAGAACCTGCATAAGGTGCTGCAAGG

CCGCCTGCCCGCCGTGGCCCAGGCCGTGGCCCAGCTCGCAGGGCAGCTCCTCATCCG

GCTCAGCCACGATCGCCTGCTGCCCCTCGACTTCGGCCGCTACGGGGACGTCGTCCT

CAGGCACATCGGGAACCTCAACGAGTTCTCTGGGGACCTCAAGGCCCGCGGGCTGAC

CCTGCAGTGGGTGTACTCGGCGCGGGGGGACTACATCCGGGCGGCGGAAAAGCTGCG

GCAGGAGATCTACAGCTCGGAGGAGAGAGACGAGCGACTGACACGCATGTACAACGT

GCGCATAATGCGGGTGGAGTTCTACTTCCTTTCCCAGTACGTGTCGCCAGCCGACTC

CCCGTTCCGCCACATCTTCATGGGCCGTGGAGACCACACGCTGGGCGCCCTGCTGGA

CCACCTGCGGCTGCTGCGCTCCAACAGCTCCGGGACCCCCGGGGCCACCTCCTCCAC

TGGCTTCCAGGAGAGCCGTTTCCGGCGTCAGCTAGCCCTGCTCACCTGGACGCTGCA

AGGGGCAGCCAATGCGCTTAGCGGGGATGTCTGGAACATTGATAACAACTTCTGAGG

CCCTGGGGATCCTCACATCCCCGTCCCCCAGTCAAGAGCTCCTCTGCTCCTCGCTTG

AATGATTCAGGGTCAGGGAGGTGGCTCAGAGTCCACCTCTCATTGCTGATCAATTTC

TCATTACCCCTACACATCTCTCCACGGAGCCCAGACCCCAGCACAGATATCCACACA

CCCCAGCCCTGCAGTGTAGCTGACCCTAATGTGACGGTCATACTGTCGGTTAATCAG

AGAGTAGCATCCCTTCAATCACAGCCCCTTCCCCTTTCTGGGGTCCTCCATACCTAG

AGACCACTCTGGGAGGTTTGCTAGGCCCTGGGACCTGGCCAGCTCTGTTAGTGGGAG

AGATCGCTGGCACCATAGCCTTATGGCCAACAGGTGGTCTGTGGTGAAAGGGGCGTG

GAGTTTCAATATCAATAAACCACCTGATATCAATAA (SEQ ID NO: 203)

>NP_003218.2 transferrin receptor protein 2 isoform 1

[Homo sapiens]

MERLWGLFQRAQQLSPRSSQTVYQRVEGPRKGHLEEEEEDGEEGAETLAHFCPMELR

GPEPLGSRPRQPNLIPWAAAGRRAAPYLVLTALLIFTGAFLLGYVAFRGSCQACGDS

VLVVSEDVNYEPDLDFHQGRLYWSDLQAMFLQFLGEGRLEDTIRQTSLRERVAGSAG

MAALTQDIRAALSRQKLDHVWTDTHYVGLQFPDPAHPNTLHWVDEAGKVGEQLPLED

PDVYCPYSAIGNVTGELVYAHYGRPEDLQDLRARGVDPVGRLLLVRVGVISFAQKVT

NAQDFGAQGVLIYPEPADESQDPPKPSLSSQQAVYGHVHLGTGDPYTPGFPSENQTQ

FPPVASSGLPSIPAQPISADIASRLLRKLKGPVAPQEWQGSLLGSPYHLGPGPRLRL

VVNNHRTSTPINNIFGCIEGRSEPDHYVVIGAQRDAWGPGAAKSAVGTAILLELVRT

FSSMVSNGFRPRRSLLFISWDGGDFGSVGSTEWLEGYLSVLHLKAVVYVSLDNAVLG

DDKFHAKTSPLLTSLIESVLKQVDSPNHSGQTLYEQVVFTNPSWDAEVIRPLPMDSS

AYSFTAFVGVPAVEFSFMEDDQAYPFLHTKEDTYENLHKVLQGRLPAVAQAVAQLAG

QLLIRLSHDRLLPLDFGRYGDVVLRHIGNLNEFSGDLKARGLTLQWVYSARGDYIRA

AEKLRQEIYSSEERDERLTRMYNVRIMRVEFYFLSQYVSPADSPFRHIFMGRGDHTL

GALLDHLRLLRSNSSGTPGATSSTGFQESRFRRQLALLTWTLQGAANALSGDVWNID

NNF

(SEQ ID NO: 204)

Human ADAM10
>NM_001110.4 Homo sapiens ADAM metallopeptidase domain 10

(ADAM10), transcript variant 1, mRNA

GTTGCCGGCCCCTGAAGTGGAGCGAGAGGGAGGTGCTTCGCCGTTTCTCCTGCCAGG

GGAGGTCCCGGCTTCCCGTGGAGGCTCCGGACCAAGCCCCTTCAGCTTCTCCCTCCG

GATCGATGTGCTGCTGTTAACCCGTGAGGAGGCGGCGGCGGCGGCAGCGGCAGCGGA

AGATGGTGTTGCTGAGAGTGTTAATTCTGCTCCTCTCCTGGGCGGCGGGGATGGGAG

GTCAGTATGGGAATCCTTTAAATAAATATATCAGACATTATGAAGGATTATCTTACA

ATGTGGATTCATTACACCAAAAACACCAGCGTGCCAAAAGAGCAGTCTCACATGAAG

ACCAATTTTTACGTCTAGATTTCCATGCCCATGGAAGACATTTCAACCTACGAATGA

AGAGGGACACTTCCCTTTTCAGTGATGAATTTAAAGTAGAAACATCAAATAAAGTAC

TTGATTATGATACCTCTCATATTTACACTGGACATATTTATGGTGAAGAAGGAAGTT

TTAGCCATGGGTCTGTTATTGATGGAAGATTTGAAGGATTCATCCAGACTCGTGGTG

GCACATTTTATGTTGAGCCAGCAGAGAGATATATTAAAGACCGAACTCTGCCATTTC

ACTCTGTCATTTATCATGAAGATGATATTAACTATCCCCATAAATACGGTCCTCAGG

GGGGCTGTGCAGATCATTCAGTATTTGAAAGAATGAGGAAATACCAGATGACTGGTG

TAGAGGAAGTAACACAGATACCTCAAGAAGAACATGCTGCTAATGGTCCAGAACTTC

TGAGGAAAAAACGTACAACTTCAGCTGAAAAAAATACTTGTCAGCTTTATATTCAGA

CTGATCATTTGTTCTTTAAATATTACGGAACACGAGAAGCTGTGATTGCCCAGATAT

CCAGTCATGTTAAAGCGATTGATACAATTTACCAGACCACAGACTTCTCCGGAATCC

GTAACATCAGTTTCATGGTGAAACGCATAAGAATCAATACAACTGCTGATGAGAAGG

ACCCTACAAATCCTTTCCGTTTCCCAAATATTGGTGTGGAGAAGTTTCTGGAATTGA

ATTCTGAGCAGAATCATGATGACTACTGTTTGGCCTATGTCTTCACAGACCGAGATT

TTGATGATGGCGTACTTGGTCTGGCTTGGGTTGGAGCACCTTCAGGAAGCTCTGGAG

GAATATGTGAAAAAAGTAAACTCTATTCAGATGGTAAGAAGAAGTCCTTAAACACTG

GAATTATTACTGTTCAGAACTATGGGTCTCATGTACCTCCCAAAGTCTCTCACATTA

CTTTTGCTCACGAAGTTGGACATAACTTTGGATCCCCACATGATTCTGGAACAGAGT

GCACACCAGGAGAATCTAAGAATTTGGGTCAAAAAGAAAATGGCAATTACATCATGT

ATGCAAGAGCAACATCTGGGGACAAACTTAACAACAATAAATTCTCACTCTGTAGTA

TTAGAAATATAAGCCAAGTTCTTGAGAAGAAGAGAAACAACTGTTTTGTTGAATCTG

GCCAACCTATTTGTGGAAATGGAATGGTAGAACAAGGTGAAGAATGTGATTGTGGCT

ATAGTGACCAGTGTAAAGATGAATGCTGCTTCGATGCAAATCAACCAGAGGGAAGAA

AATGCAAACTGAAACCTGGGAAACAGTGCAGTCCAAGTCAAGGTCCTTGTTGTACAG

CACAGTGTGCATTCAAGTCAAAGTCTGAGAAGTGTCGGGATGATTCAGACTGTGCAA

GGGAAGGAATATGTAATGGCTTCACAGCTCTCTGCCCAGCATCTGACCCTAAACCAA

ACTTCACAGACTGTAATAGGCATACACAAGTGTGCATTAATGGGCAATGTGCAGGTT

CTATCTGTGAGAAATATGGCTTAGAGGAGTGTACGTGTGCCAGTTCTGATGGCAAAG

ATGATAAAGAATTATGCCATGTATGCTGTATGAAGAAAATGGACCCATCAACTTGTG

CCAGTACAGGGTCTGTGCAGTGGAGTAGGCACTTCAGTGGTCGAACCATCACCCTGC

AACCTGGATCCCCTTGCAACGATTTTAGAGGTTACTGTGATGTTTTCATGCGGTGCA

GATTAGTAGATGCTGATGGTCCTCTAGCTAGGCTTAAAAAAGCAATTTTTAGTCCAG

AGCTCTATGAAAACATTGCTGAATGGATTGTGGCTCATTGGTGGGCAGTATTACTTA

TGGGAATTGCTCTGATCATGCTAATGGCTGGATTTATTAAGATATGCAGTGTTCATA

CTCCAAGTAGTAATCCAAAGTTGCCTCCTCCTAAACCACTTCCAGGCACTTTAAAGA

GGAGGAGACCTCCACAGCCCATTCAGCAACCCCAGCGTCAGCGGCCCCGAGAGAGTT

ATCAAATGGGACACATGAGACGCTAACTGCAGCTTTTGCCTTGGTTCTTCCTAGTGC

CTACAATGGGAAAACTTCACTCCAAAGAGAAACCTATTAAGTCATCATCTCCAAACT

AAACCCTCACAAGTAACAGTTGAAGAAAAAATGGCAAGAGATCATATCCTCAGACCA

GGTGGAATTACTTAAATTTTAAAGCCTGAAAATTCCAATTTGGGGGTGGGAGGTGGA

AAAGGAACCCAATTTTCTTATGAACAGATATTTTTAACTTAATGGCACAAAGTCTTA

GAATATTATTATGTGCCCCGTGTTCCCTGTTCTTCGTTGCTGCATTTTCTTCACTTG

CAGGCAAACTTGGCTCTCAATAAACTTTTACCACAAATTGAAATAAATATATTTTTT

TCAACTGCCAATCAAGGCTAGGAGGCTCGACCACCTCAACATTGGAGACATCACTTG

CCAATGTACATACCTTGTTATATGCAGACATGTATTTCTTACGTACACTGTACTTCT

GTGTGCAATTGTAAACAGAAATTGCAATATGGATGTTTCTTTGTATTATAAAATTTT

TCCGCTCTTAATTAAAAATTACTGTTTAATTGACATACTCAGGATAACAGAGAATGG

TGGTATTCAGTGGTCCAGGATTCTGTAATGCTTTACACAGGCAGTTTTGAAATGAAA

ATCAATTTACCTTTCTGTTACGATGGAGTTGGTTTTGATACTCATTTTTTCTTTATC

ACATGGCTGCTACGGGCACAAGTGACTATACTGAAGAACACAGTTAAGTGTTGTGCA

AACTGGACATAGCAGCACATACTACTTCAGAGTTCATGATGTAGATGTCTGGTTTCT

GCTTACGTCTTTTAAACTTTCTAATTCAATTCCATTTTTCAATTAATAGGTGAAATT

TTATTCATGCTTTGATAGAAATTATGTCAATGAAATGATTCTTTTTATTTGTAGCCT

ACTTATTTGTGTTTTTCATATATCTGAAATATGCTAATTATGTTTTCTGTCTGATAT

GGAAAAGAAAAGCTGTGTCTTTATCAAAATATTTAAACGGTTTTTTCAGCATATCAT

CACTGATCATTGGTAACCACTAAAGATGAGTAATTTGCTTAAGTAGTAGTTAAAATT

GTAGATAGGCCTTCTGACATTTTTTTTCCTAAAATTTTTAACAGCATTGAAGGTGAA

ACAGCACAATGTCCCATTCCAAATTTATTTTTGAAACAGATGTAAATAATTGGCATT

TTAAAGAGAAAGCAAAAACATTTAATGTATTAACAGGCTTATTGCTATGCAGGAAAT

AGAAGGGGCATTACAAAAATTGAAGCTTGTGACATATTTATTGCTTCTGTTTTCCAA

CTACATCACTTCAACTAGAAGTAAAGCTATGATTTTCCTGACTTCACATAGGAGGCA

AATTTAGAGAAAGTTGTAAAGATTTCTATGTTTTGGGTTTTTTTTTTTCCTTTTTTT

TTTTAAGAGTATAAGGTTTACACAATCATTCTCATAATGTGACGCAAGCCAGCAAGG

CCAAAAATGCTAGAGAAAATAACGGGATCTCTTCCTTGTAAACTTGTACAGTATGTG

GTGACTTTTTCAAAATACAGCTTTTTGTACATGATTTAGAGACAAATTTTGTACATG

AAACCCCAGATAGACTATAAATAATTCTAAACAAACAAGTAGGTAGATATGTATGTA

ATTGCTTTTAAATCATTTAAATGCCTTTGTTTTTGGACTGTGCAAAGGTTGGAAGTG

GGTTTGCATTTCTAAAATGGTGACTTTTATTCTGCAAGAGTTCTTAGTAACTTCTTG

AGTGTGGTAGACTTTGGAACATGTAAATTTTTTGCTTGTAATGTTATCCTGTGGTAG

GATTTTGGCAGGTACACACACTGCCCTATTTTATTTTGAGTCTAAGTTAAATGTTTT

CTGAAAAGAGATACATGCACTGAACTCTTTCCACTGCGAATCAAGATGTGGTAATAT

AAAAGGATCAAGACAAATGAGATCTAATACTACTGTCAGTTTTAATGTCCACTGTGT

TTTATACAGTATCTTTTTTTGTTCACTTTGGAAATTTTTACTAAAAATTGCAAAAAA

TAAAGTATTGTGCAAAGATGTAAGGTTTTTTGAAACTTGAAATGCATTAATAAATAG

ACGATTAAATCAACTTGAAGGTTCTATACTCTTTGAACTCTGAGAACTATCACAAGA

AGCTTCCCACAAGGCAGTGTTTTCTTACAGTTGTCTCTTCCTACAAAAGTATAGATT

ATCTTTATTCTTAATACTTTGGAATCCATGTAGAAAATTTCCAGTTAGATACTCTGC

GTACACACAATAAACCTTTTTAAAACACCCAACTAATCTCAACTGCATTACATTGTT

TCTAATCAATATTCAGTGCTTGTCTTGGTGGAAGAGGTGAGTCATTTTGAAAACTTA

TGGTCTTGTTTTTATGTGTTTTTCAAAGTTTTGAATGCTAAGTACCTCATTTATTTT

AAAAAGCCTAGTTTAATGATAAGTTTGTTTAAAATTTTGAGCCATCATTTTTCTCTT

CATAGCAAATAAGGAGAGAATTGACATTTCAGTGTTACCTAGAAAAGGAATTGTAAG

CCCAGAATAATTCCCTGCATGAGGTAATCTGCTTCAAATTCTTTTTTTAGTCAAGGT

TAGCTATAAGTAATACTTGTTAAATGAGTAAATATGTAATACTTTGTGAATTACTTT

GTTAATTTAGGAGCATCAAATGTATATTATGTTTAGTTATTTATGAAACTCTCAATA

TTGATTGATTTGGGTAATTATAAATTAGTTATTTTTACTTGTAATTGAATGCTTAAA

TTCTGTTTACAGTCCGTCCTCTCTCCCTCCATCCCTCCCTCCCCAGTTTTATAAATT

CAGGTACCAATTCACAAACAAAATCAGAAATAAAATAAATTTATTGACTGCTTCTGG

ATTTAGCATTCCCTGTAGTGTCAAGCAATGTCATGCAGTTTGGGGAAGCATTTATTT

AAGGAAATGACAACTTTCTCTGATCAGTCTTGTTTTGTGAGGTGTCTTCAACACTTT

ATGCTTTGGGTACTTCGTGTTTGTCACAGTCTTAGGATAGTGAAATCTGATTTGTCC

AAGCGGAGCAAACTACTCGACCCTCAGTCCTTGTATTTGTCCCTGTAGTAAGACCTA

ATTATTATTATTTCTTAAAGATGGGATTGGTGTCCTTGGCAACTATGAAATTTCGGG

GCTTGTGCATGAGAAGGCATTTCTTATTAAGTATTTCTAATTGAAGGTATCAGAGTG

TCAAGCATTACAAACCTGGACAGTTCACCTGGAGGAGTACAAGAAGAGATATTCATT

ATCCATATTTAAAGGGTCAAGGTTTCCCAAAACCAGGGTGCAAGCCAGATGTAGTTT

TAAAGCAGCTGCCAGGGACAGTTCATCTTTAGAGAAGTCACTAAAGTTGTAAGAAAT

TTTAGTTTCCCCAAAACCACTTTCAACTTCTTAGAAACTAGAAAGACAATTGGTTTG

CCCCACAGAGGACAACTTCAGTTTCAGCATCTCTCATGTTGTGTTCTTGATTAAAAA

CAACTTCCATTTGATATACTTTTCCGTTTATTACCAGTTTAGTTTTTTCACTATTGT

TTCTGTATTCAACTCTTTATATGATTAGGATAGAAATTTAGCCCTTCTGTTTTATAT

TACTATATTGTTTGTGTGTCTTAGATATATACATGTATGTACTATTTTCAGTAGAAA

TTCATGTATTTTATAATTGGTAAGTTCTTCAGAGCATCTCTTCTATAAAAAGCAACA

GGATGCTAGGTAAAACGGAGCATTGAGCAAAATACTGATTAGTTTTTGCTTTTTCCT

GAAATCTACACTAAAGTGATAGGGTGTGGGGTAATCCAACAAGGACAAGGTGAATTG

AACAAGAACGAAATCTGGAAGCAGATGAAGGAGTACTATTGATTGGGCAGACCCAGG

GAAGTCAAATCCTAAACCAGCAGTGGGAACACAACAGAATGGTGTAGTTTGCACTGG

TAAGATTTGGGTACCTGGCAGGGCTGGGTGCGGTGGCTCACACCTGTAATCCCAGCA

CTTTGGGAGGCCAAGGCGGGTGGATCACTTGAGGTCAGGAGTTCGAGACCACCCTGG

CCAACATGGTGAAACCCCGTCTCTACTAAAAATACAGCTGGGCGTGGTGGCACATGC

TTGTAATCCCAGCTACTCGGGAGGCAGAGGCAGGAGATTTGCTTGAACCCGGGAGGC

AGAGGCAGGAGATTTGCTTGAACCCAGGAGGCAGAGGCTGCAGTGAGCCGCGATTGC

GCCATTGCACTCCAGCCTGGGTGACAGAGCGAGACTCTGTCTCAAAAAAAAAAAAAA

AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAATTTGAGTACCTGGCCTTTGTTAC

TTTTTTTCTATGTGTGTGACAAAAACATAATATGCACACTTTTGTAACCCACCTTTC

TCATTTAATGGTACATTGATAATGTATATCACATTAACTACTCTAAATATTTCTGTG

GATGTATGTTTTTTTTTTTCTTAACCAATTTCCCATTGTTTGGACATGTAGGTTCCA

CATTGTTTATTATTTTAAACAATTCTAAAGAATTTTAAACAATTCTTAGGAAAATCC

TCAGCCTAATAATGAAATTAATTCCTAAAAGTGGAATTGTTGGGGTAAAGGTTTTTT

GAGGGACATTGATAAAAATTATGGTACTGTCTCCCAGATAGATGTACCAAGTTATAC

TACCACGATTTAATATATATATATATATATATTAAATCAGAGTCCCATCCTTAGAAA

TCCACATATATGCAGCCACATGAATGTATTAGAAACAATAATAGAAGACTCATGCTT

AATTCAGTTGATTAGCTTTAGACATAATTCAAATGCAAGTCAAATTGAGTGCCCTAA

TTGTGGTCTCTTAAGTACCATTTTTCTTCAAGGGAACCAGACTCCTTTGGATAAATC

ACTAATTCCACCTGTAAGAAAGAAATGTACAAGAAGAACCTAGGAAACATTGTTTTG

TACCAGATCAGAAAGATTCAGGAGGCACCTTAGAAGTTACCACTGGCCAAGGCTGAG

ATAACTTTAGCATCAGCAAGGATAATATCTGCAAGAGATTGAAACTCATAGTATTGT

ATTTAACTCTGTGAGTTAATGATGGTAGTGGACAGAATTATAGTTACCTTTGGGATA

CGCTTTTAAAGAAATTCCAGGTAATAAGAGAAATGATAGAATTAGGATATCACCATT

TTACCCCCCCAACAATTTATGGATCTAGACAATAATCGCCAGTGACTGCTAACCTCA

CAAAGTGAGAGCAATCAGATTTTGTGCCTCCTAATGGAAGTACATATACCACCTATG

AAGCAGTTCTGCCAAAAGTCACATCTCATCATGATGAAGCCTCCTGATCTAACTACC

CCTTCATTAGAAATACAGGGGACAGAGGGACAAATAATATACAAGGGACTCAATCAG

CAAAATCCAGACTCTGGAAAACTACAAGACATATGGTCCTGCTTCAACAACAGAAAT

GCAAAGAGAAAAGACAACGATGGGTTAAAGGAGACTTAAGAGCTACATCTATCAAGA

CAATTTATGGACTTATTTGGATACTGATTTGAACAAACTGTTGAGACCATTGGAAAA

ATGTGAAAAGTGGATATTTGATATTAAGGTTTTTAATTATTTTTAGGTGTGATAATG

GTATTGTTACATTTTTTAAAGGACCCCTTTTAGAGATGCAAATTGAAACACTTAAAA

AATGAAATGATACGATGTATAAGTTTTTGCTTAAAAATAAGGATTGAAGTTGGCTGG

TGTGTGTGGATATAGTTGAAACAAGATTGGCTGTGAGTTGATAATTATTGAAGCTGG

GTGATGGGCACTTGGGGATTTATTATACTATTTTCTCTACCTGTGTTTATATTTGAA

ATTTTTCATAGAAGTTTTAAAATGTGGCCAGTTGTGATGGCTCATACCTGTAATCCC

AACACTTTGGGAGGCCAAGGTGGGAGGATCACTTGAGCTCAGGAGTTAGAGACCAGC

CTGGGCAAAATAGTGAGACTCCATCTCAAAGAAAAAAAAAAAGTGTTTTAAATGTGA

ATCAAATTCCTATAGAAGCTGATTCATTACTGTTTTTATTTTAGCAGTAATTCATGA

TAATGACCTGTATTCATAATGATTTTCATAATGATTGTTTTAGTGGAATTAAACTTG

AACCAGTCAAGCTAACATAATTATATTCTGCTCCAGTTACAATGAATAATTAATTGA

TTTCAACTGCTAGGGTGAACTCTTGAAGCTATCAGTCATCCAGCAATCTTAGCAAGC

AGGCCATTGGGTCCCTGTTTGCTCTGTCTCTCTCTCTCTCTCTCACTGTTGAAGGGC

TTAGCTAACTACTTAAGTAAAATATTTGTTCTCTGTTAAACATGTCAAGGAGTATGG

TCAGCTTATCCACATTAAGCCTGTGTGTCCCACGTTGGAGTAAATGTTAAGTAGCTC

ACTACAATAAACTAGATTCTTCTGCCCTCTCTTGTTTAAATGATCATGTTCCCTGGA

GGTGGAAATAGATCTTTAAAAAGATATTCTGTAGTTGTTTGTTCTCAGTGTAAAAAA

ATGAGAATAATTTGATAAGAGTGTAGGTTGTCTTATATAAAAAGTGGTTCCATTTGC

ATGAATTTTAGAAAAATCATTTTGGAAAAATGAAGGCTATGTGGTTATACTGAACAC

ATTAAGCAATTTTATTCTTTATTTTAAATGAATATTTTATTATCGTTTTCTTCCCTT

GCCCTTTGGGTATGGGAGTTAGCCTTTGTGTTTCTAAATACAACAGGCCGGTTTTTA

TAAATTAAGGTGTCAATATATTCTTCATTATTTAGTTTTGTGATTGTGGTTAGTTTT

CATTTTTCTTAAGTATCTGCTAGTAGCATCTGTAATTAAGTGAAGTGACCTGTTAAC

CATTTTCCTCTTTCTCCTCCTTTCCTCCTCCTTGAAACATATCAGAGCATGTTTGAA

ATTCTTTGGCTTTTATGGTATGCATTTGCTGATATGCATTGACCAGTTACCTTACTC

ACAGATACTTCTTAGGCACTTGATTGTGCCAGGGCCTTGGCTAGATGATAAGAATAC

AGTAGTGAACTTAACAGTTTCCCTGCCCTGGTGAAGCGTATGGTCTTGTAGGTGAGA

TAGATATCAGATAATCATGTGAATAAATGTACAATTCCAGCTGTGATACATGCTGAG

GAGGAGGTTTTTGGTGATCCAAGAGCTGATCATGCAGAGATAGGACTGAGAAAGGAG

GGTGGGACGTTGTCACAGCTGATAATGCAGAGATAGGACTGAGAAAGGAGGGTGGGA

CATCAGGAAGGTCAGAGAATTCCTTATGAAAGTGATGCTTGAGTCAAAATATGATGG

ATGAAGAGAGTTTAAATAGATTACATAGAATTTTTAATAATGTCGATTGGTTATATA

CTGGGCACTGATAGCTGATTTTTCTTTGGGGAAAGGTATGTCAGCCTAGTCATTCAG

ATTCCTTTATTTTTTTAAATGTTTTTTCATTTTTTGCTTTGCATTGCATTCATTTGC

TGAAGAGCTGGCTTGTACTTTGGCAGGTGTCATACTTGGTTATTCTCCTTAGGATAT

TGGCCCAACAATCTGGGAGTTGTGAAAGGCGCTTCGCTTTTCAGACCTGGGCGTCTG

TATCATGACTATCATAAATTTAGGATTAAGACACCTAGCCTCCTACCAGGATGAATG

AGGTGTCCATGTGACCTGCTGTGCCCTGGAATTTTATACATCTTTCTCTCATAGCAC

ACACCATATTACAATATAATCCTGCCTCATCTAAGCCAAACTTTCGAGAGAATCATT

TACACTCAGTGGCTACTTCAGCTCCCATTCACTTATCAACCTGCTGCAATTTTTCAC

AGCCCCCAAAGGACTGCAGTCTGTGCCTTCAGGGAGCTGAGGGTCTAGCGGAAGGAA

AGAAACCAGCAGTTACAGTACAGAGGGGTTTGTGTTGGAAACTCTACAAACACAGGA

TGCCCTGGTAGCTCAGAGGAAGTGCATATCGAGCATGGTAGGTAGGTAGTGGGAAGA

GCCAAGATGACTTCCCAGAGGAGAAAAGCTGGACCTGAGTTTTGGAGTTTCGGTAAA

AGTTTGCTCTAACTAGTCCAAGCTGCTGTCACAAGCTTTTAGAAATGATGTAACCAT

GGGGCAGTTGACTGTCGTCATGTTCTTTGCTATTTTCATGACTCTGGATGTGCTTTT

CCTATTCCCTGGATTGCCCTTTCCCTCGATTCCTCTGCAGGACTGGGCTTTATTAAT

CTCCATTTCCTTGAGCTTGGCTATAGTAGGTGTTCAATAAACATTTGTTTTGTTGTG

TGCTTTGTAAATAGGCAATGAAGCTGATTTCACAAGATAGGCACAAAAGTTAGTTTC

ATTACAACACATTACCAACAGCTGTATTTTTAACTTTTAACATATCTCATTCTAAAT

CCTGTGGCAGCACAACCTCCTTCCGTCATACCTGGAGATAAATTTTCTTTCAAAATC

TAATATGCACTGTATTTATAGAATATGAAACATACCGACCATGTTTTGCAAAAATGG

GAAAGGCATAACTTAGCTTTGGGGCATGTAAGTAACAACTCCTGATAGGAGAAGAAA

TGTATTCAGAAAGCTCAAATTAGAAATAAAATGGGAGACTCTA (SEQ ID NO:

205)

>NP_001101.1 disintegrin and metalloproteinase domain-

containing protein 10 isoform 1 preproprotein [Homo

sapiens]

MVLLRVLILLLSWAAGMGGQYGNPLNKYIRHYEGLSYNVDSLHQKHQRAKRAVSHED

QFLRLDFHAHGRHENLRMKRDTSLESDEFKVETSNKVLDYDTSHIYTGHIYGEEGSF

SHGSVIDGRFEGFIQTRGGTFYVEPAERYIKDRTLPFHSVIYHEDDINYPHKYGPQG

GCADHSVFERMRKYQMTGVEEVTQIPQEEHAANGPELLRKKRTTSAEKNTCQLYIQT

DHLFFKYYGTREAVIAQISSHVKAIDTIYQTTDESGIRNISEMVKRIRINTTADEKD

PTNPFRFPNIGVEKFLELNSEQNHDDYCLAYVETDRDEDDGVLGLAWVGAPSGSSGG

ICEKSKLYSDGKKKSLNTGIITVQNYGSHVPPKVSHITFAHEVGHNFGSPHDSGTEC

TPGESKNLGQKENGNYIMYARATSGDKLNNNKFSLCSIRNISQVLEKKENNCFVESG

QPICGNGMVEQGEECDCGYSDQCKDECCFDANQPEGRKCKLKPGKQCSPSQGPCCTA

QCAFKSKSEKCRDDSDCAREGICNGFTALCPASDPKPNFTDCNRHTQVCINGQCAGS

ICEKYGLEECTCASSDGKDDKELCHVCCMKKMDPSTCASTGSVQWSRHFSGRTITLQ

PGSPCNDFRGYCDVFMRCRLVDADGPLARLKKAIFSPELYENIAEWIVAHWWAVLLM

GIALIMLMAGFIKICSVHTPSSNPKLPPPKPLPGTLKRRRPPQPIQQPQRQRPRESY

QMGHMRR (SEQ ID NO: 206)

Transmembrane
>NM_001769.4 Homo sapiens CD9 molecule (CD9), transcript

domain 2 or
variant 1, mRNA

transmembrane
AGCCGCCTGCATCTGTATCCAGCGCCAGGTCCCGCCAGTCCCAGCTGCGCGCGCCCC

domain 3 from
CCAGTCCCGCACCCGTTCGGCCCAGGCTAAGTTAGCCCTCACCATGCCGGTCAAAGG

Human CD9
AGGCACCAAGTGCATCAAATACCTGCTGTTCGGATTTAACTTCATCTTCTGGCTTGC

CGGGATTGCTGTCCTTGCCATTGGACTATGGCTCCGATTCGACTCTCAGACCAAGAG

CATCTTCGAGCAAGAAACTAATAATAATAATTCCAGCTTCTACACAGGAGTCTATAT

TCTGATCGGAGCCGGCGCCCTCATGATGCTGGTGGGCTTCCTG

GGCTGCTGCGGGGC

TGTGCAGGAGTCCCAGTGCATGCTGGGACTGTTCTTCGGCTTCCTCTTGGTGATATT

CGCCATTGAAATAGCTGCGGCCATCTGGGGATATTCCCACAAGGATGAGGTGATTAA

GGAAGTCCAGGAGTTTTACAAGGACACCTACAACAAGCTGAAAACCAAGGATGAGCC

CCAGCGGGAAACGCTGAAAGCCATCCACTATGCGTTGAACTGCTGTGGTTTGGCTGG

GGGCGTGGAACAGTTTATCTCAGACATCTGCCCCAAGAAGGACGTACTCGAAACCTT

CACCGTGAAGTCCTGTCCTGATGCCATCAAAGAGGTCTTCGACAATAAATTCCACAT

CATCGGCGCAGTGGGCATCGGCATTGCCGTGGTCATGATATTTGGCATGATCTTCAG

TATGATCTTGTGCTGTGCTATCCGCAGGAACCGCGAGATGGTCTAGAGTCAGCTTAC

ATCCCTGAGCAGGAAAGTTTACCCATGAAGATTGGTGGGATTTTTTGTTTGTTTGTT

TTGTTTTGTTTGTTGTTTGTTGTTTGTTTTTTTGCCACTAATTTTAGTATTCATTCT

GCATTGCTAGATAAAAGCTGAAGTTACTTTATGTTTGTCTTTTAATGCTTCATTCAA

TATTGACATTTGTAGTTGAGCGGGGGGTTTGGTTTGCTTTGGTTTATATTTTTTCAG

TTGTTTGTTTTTGCTTGTTATATTAAGCAGAAATCCTGCAATGAAAGGTACTATATT

TGCTAGACTCTAGACAAGATATTGTACATAAAAGAATTTTTTTGTCTTTAAATAGAT

ACAAATGTCTATCAACTTTAATCAAGTTGTAACTTATATTGAAGACAATTTGATACA

TAATAAAAAATTATGACAATGTCCTGGA (SEQ ID NO: 207)

>NP_001760.1 CD9 antigen isoform 1 [Homo sapiens]

MPVKGGTKCIKYLLFGFNFIFWLAGIAVLAIGLWLREDSQTKSIFEQETNNNNSSFY

TGVYILIGAGALMMLVGFL

GCCGAVQESQCMLGLFFGELLVIFAIEIAAAIWGYSHK

DEVIKEVQEFYKDTYNKLKTKDEPQRETLKAIHYALNCCGLAGGVEQFISDICPKKD

VLETFTVKSCPDAIKEVEDNKFHIIGAVGIGIAVVMIFGMIFSMILCCAIRRNREMV

(SEQ ID NO: 208)

Human CD298
>NM_001679.4 Homo sapiens ATPase Na+/K+ transporting

subunit beta 3 (ATP1B3), mRNA

AGTCGGCTCGAGTACTCCCCGTAACGAGGAGGTGTTCTCGGCCGTCCCACCCTTCAC

TGCCGTCTCCGGGCTGCGCCGCCGGAGCCGGGACGCGCCTCCGCAGCCCTCGCCGCC

TCCATCCCCGCGGCCGCAGCTCCTCTCGCCGTCCGCGCGCACACCATGACGAAGAAC

GAGAAGAAGTCCCTCAACCAGAGCCTGGCCGAGTGGAAGCTCTTCATCTACAACCCG

ACCACCGGAGAATTCCTGGGGCGCACCGCCAAGAGCTGGGGTTTGATCTTGCTCTTC

TACCTAGTTTTTTATGGGTTCCTGGCTGCACTCTTCTCATTCACGATGTGGGTTATG

CTTCAGACTCTCAACGATGAGGTTCCAAAATACCGTGACCAGATTCCTAGCCCAGGA

CTCATGGTTTTTCCAAAACCAGTGACCGCATTGGAATATACATTCAGTAGGTCTGAT

CCAACTTCGTATGCAGGGTACATTGAAGACCTTAAGAAGTTTCTAAAACCATATACT

TTAGAAGAACAGAAGAACCTCACAGTCTGTCCTGATGGAGCACTTTTTGAACAGAAG

GGTCCAGTTTATGTTGCATGTCAGTTTCCTATTTCATTACTTCAAGCATGCAGTGGT

ATGAATGATCCTGATTTTGGCTATTCTCAAGGAAACCCTTGTATTCTTGTGAAAATG

AACAGAATAATTGGATTAAAGCCTGAAGGAGTGCCAAGGATAGATTGTGTTTCAAAG

AATGAAGATATACCAAATGTAGCAGTTTATCCTCATAATGGAATGATAGACTTAAAA

TATTTCCCATATTATGGGAAAAAACTGCATGTTGGGTATCTACAGCCATTGGTTGCT

GTTCAGGTCAGCTTTGCTCCTAACAACACTGGGAAAGAAGTAACAGTTGAGTGCAAG

ATTGATGGATCAGCCAACCTAAAAAGTCAGGATGATCGTGACAAGTTTTTGGGACGA

GTTATGTTCAAAATCACAGCACGTGCATAGTATGAGTAGGATATCTCCACAGAGTAA

ATGTTGTGTTGTCTGTCTTCATTTTGTAACAGCTGGACCTTCCATTCTAGAATTATG

AGACCACCTTGGAGAAAGGTGTGTGGTACATGACATTGGGTTACATCATAACGTGCT

TCCAGATCATAGTGTTCAGTGTCCTCTGAAGTAACTGCCTGTTGCCTCTGCTGCCCT

TTGAACCAGTGTACAGTCGCCAGATAGGGACCGGTGAACACCTGATTCCAAACATGT

AGGATGGGGGTCTTGTCCTCTTTTTATGTGGTTTAATTGCCAAGTGTCTAAAGCTTA

ATATGCCGTGCTATGTAAATATTTTATGGATATAACAACTGTCATATTTTGATGTCA

ACAGAGTTTTAGGGATAAAATGGTACCCGGCCAACATCAAGTGACTTTATAGCTGCA

AGAAATGTGGTATGTGGAGAAGTTCTGTATGTGAGGAAGGAAAAAAAGAAAATAAAA

GTGTGTTTGAAAAATATTATCTTGGGTTCTTTGTAAAATTTATTTTTTACATGCTGA

ATTAGCCTCGATCTTTTTGATTAAGAGCACAAACTTTTTTTTGTAAAACATGTAAAA

AAAAAAACTGGGATTAATTTTTAGTGTTGGAACTGCCTCTTATTTTAGGCTGTAGAT

AAAATAGCATTTTTAGGTTAGCCAGTGTGACTATGCACCTAATTTTTTATGAGATTA

AATTCATAAGACTTAATTTGTACAATAGTTTGTGAAATATCTTGTTACTGCTTTTAT

TTAGCAGACTGTGGACTGTAATAAAGTATATAAATTGTGAAATATAAAAACTTGGAA

CTTATTCAAAGCTTCAAAGCAAA (SEQ ID NO: 209)

>NP_001670.1 sodium/potassium-transporting ATPase subunit

beta-3 [Homo sapiens]

MTKNEKKSLNQSLAEWKLFIYNPTTGEFLGRTAKSWGLILLFYLVFYGFLAALESFT

MWVMLQTLNDEVPKYRDQIPSPGLMVFPKPVTALEYTFSRSDPTSYAGYIEDLKKEL

KPYTLEEQKNLTVCPDGALFEQKGPVYVACQFPISLLQACSGMNDPDFGYSQGNPCI

LVKMNRIIGLKPEGVPRIDCVSKNEDIPNVAVYPHNGMIDLKYFPYYGKKLHVGYLQ

PLVAVQVSFAPNNTGKEVTVECKIDGSANLKSQDDRDKFLGRVMFKITARA (SEQ

ID NO: 210)

Lipid affinity tag
>NM_004985.5 Homo sapiens KRAS proto-oncogene, GTPase

modified from
(KRAS), transcript variant b, mRNA

Human KRAS
CTAGGCGGCGGCCGCGGCGGCGGAGGCAGCAGCGGCGGCGGCAGTGGCGGCGGCGAA

GGTGGCGGCGGCTCGGCCAGTACTCCCGGCCCCCGCCATTTCGGACTGGGAGCGAGC

GCGGCGCAGGCACTGAAGGCGGCGGCGGGGCCAGAGGCTCAGCGGCTCCCAGGTGCG

GGAGAGAGGCCTGCTGAAAATGACTGAATATAAACTTGTGGTAGTTGGAGCTGGTGG

CGTAGGCAAGAGTGCCTTGACGATACAGCTAATTCAGAATCATTTTGTGGACGAATA

TGATCCAACAATAGAGGATTCCTACAGGAAGCAAGTAGTAATTGATGGAGAAACCTG

TCTCTTGGATATTCTCGACACAGCAGGTCAAGAGGAGTACAGTGCAATGAGGGACCA

GTACATGAGGACTGGGGAGGGCTTTCTTTGTGTATTTGCCATAAATAATACTAAATC

ATTTGAAGATATTCACCATTATAGAGAACAAATTAAAAGAGTTAAGGACTCTGAAGA

TGTACCTATGGTCCTAGTAGGAAATAAATGTGATTTGCCTTCTAGAACAGTAGACAC

AAAACAGGCTCAGGACTTAGCAAGAAGTTATGGAATTCCTTTTATTGAAACATCAGC

AAAGACAAGACAGGGTGTTGATGATGCCTTCTATACATTAGTTCGAGAAATTCGAAA

ACATAAAGAAAAGATGAGCAAAGATGGTAAAAAGAAGAAAAAGAAGTCAAAGACAAA

GTGTGTAATTATGTAAATACAATTTGTACTTTTTTCTTAAGGCATACTAGTACAAGT

GGTAATTTTTGTACATTACACTAAATTATTAGCATTTGTTTTAGCATTACCTAATTT

TTTTCCTGCTCCATGCAGACTGTTAGCTTTTACCTTAAATGCTTATTTTAAAATGAC

AGTGGAAGTTTTTTTTTCCTCTAAGTGCCAGTATTCCCAGAGTTTTGGTTTTTGAAC

TAGCAATGCCTGTGAAAAAGAAACTGAATACCTAAGATTTCTGTCTTGGGGCTTTTG

GTGCATGCAGTTGATTACTTCTTATTTTTCTTACCAATTGTGAATGTTGGTGTGAAA

CAAATTAATGAAGCTTTTGAATCATCCCTATTCTGTGTTTTATCTAGTCACATAAAT

GGATTAATTACTAATTTCAGTTGAGACCTTCTAATTGGTTTTTACTGAAACATTGAG

GGAACACAAATTTATGGGCTTCCTGATGATGATTCTTCTAGGCATCATGTCCTATAG

TTTGTCATCCCTGATGAATGTAAAGTTACACTGTTCACAAAGGTTTTGTCTCCTTTC

CACTGCTATTAGTCATGGTCACTCTCCCCAAAATATTATATTTTTTCTATAAAAAGA

AAAAAATGGAAAAAAATTACAAGGCAATGGAAACTATTATAAGGCCATTTCCTTTTC

ACATTAGATAAATTACTATAAAGACTCCTAATAGCTTTTCCTGTTAAGGCAGACCCA

GTATGAAATGGGGATTATTATAGCAACCATTTTGGGGCTATATTTACATGCTACTAA

ATTTTTATAATAATTGAAAAGATTTTAACAAGTATAAAAAATTCTCATAGGAATTAA

ATGTAGTCTCCCTGTGTCAGACTGCTCTTTCATAGTATAACTTTAAATCTTTTCTTC

AACTTGAGTCTTTGAAGATAGTTTTAATTCTGCTTGTGACATTAAAAGATTATTTGG

GCCAGTTATAGCTTATTAGGTGTTGAAGAGACCAAGGTTGCAAGGCCAGGCCCTGTG

TGAACCTTTGAGCTTTCATAGAGAGTTTCACAGCATGGACTGTGTCCCCACGGTCAT

CCAGTGTTGTCATGCATTGGTTAGTCAAAATGGGGAGGGACTAGGGCAGTTTGGATA

GCTCAACAAGATACAATCTCACTCTGTGGTGGTCCTGCTGACAAATCAAGAGCATTG

CTTTTGTTTCTTAAGAAAACAAACTCTTTTTTAAAAATTACTTTTAAATATTAACTC

AAAAGTTGAGATTTTGGGGTGGTGGTGTGCCAAGACATTAATTTTTTTTTTAAACAA

TGAAGTGAAAAAGTTTTACAATCTCTAGGTTTGGCTAGTTCTCTTAACACTGGTTAA

ATTAACATTGCATAAACACTTTTCAAGTCTGATCCATATTTAATAATGCTTTAAAAT

AAAAATAAAAACAATCCTTTTGATAAATTTAAAATGTTACTTATTTTAAAATAAATG

AAGTGAGATGGCATGGTGAGGTGAAAGTATCACTGGACTAGGAAGAAGGTGACTTAG

GTTCTAGATAGGTGTCTTTTAGGACTCTGATTTTGAGGACATCACTTACTATCCATT

TCTTCATGTTAAAAGAAGTCATCTCAAACTCTTAGTTTTTTTTTTTTACAACTATGT

AATTTATATTCCATTTACATAAGGATACACTTATTTGTCAAGCTCAGCACAATCTGT

AAATTTTTAACCTATGTTACACCATCTTCAGTGCCAGTCTTGGGCAAAATTGTGCAA

GAGGTGAAGTTTATATTTGAATATCCATTCTCGTTTTAGGACTCTTCTTCCATATTA

GTGTCATCTTGCCTCCCTACCTTCCACATGCCCCATGACTTGATGCAGTTTTAATAC

TTGTAATTCCCCTAACCATAAGATTTACTGCTGCTGTGGATATCTCCATGAAGTTTT

CCCACTGAGTCACATCAGAAATGCCCTACATCTTATTTCCTCAGGGCTCAAGAGAAT

CTGACAGATACCATAAAGGGATTTGACCTAATCACTAATTTTCAGGTGGTGGCTGAT

GCTTTGAACATCTCTTTGCTGCCCAATCCATTAGCGACAGTAGGATTTTTCAAACCT

GGTATGAATAGACAGAACCCTATCCAGTGGAAGGAGAATTTAATAAAGATAGTGCTG

AAAGAATTCCTTAGGTAATCTATAACTAGGACTACTCCTGGTAACAGTAATACATTC

CATTGTTTTAGTAACCAGAAATCTTCATGCAATGAAAAATACTTTAATTCATGAAGC

TTACTTTTTTTTTTTGGTGTCAGAGTCTCGCTCTTGTCACCCAGGCTGGAATGCAGT

GGCGCCATCTCAGCTCACTGCAACCTCCATCTCCCAGGTTCAAGCGATTCTCGTGCC

TCGGCCTCCTGAGTAGCTGGGATTACAGGCGTGTGCCACTACACTCAACTAATTTTT

GTATTTTTAGGAGAGACGGGGTTTCACCCTGTTGGCCAGGCTGGTCTCGAACTCCTG

ACCTCAAGTGATTCACCCACCTTGGCCTCATAAACCTGTTTTGCAGAACTCATTTAT

TCAGCAAATATTTATTGAGTGCCTACCAGATGCCAGTCACCACACAAGGCACTGGGT

ATATGGTATCCCCAAACAAGAGACATAATCCCGGTCCTTAGGTAGTGCTAGTGTGGT

CTGTAATATCTTACTAAGGCCTTTGGTATACGACCCAGAGATAACACGATGCGTATT

TTAGTTTTGCAAAGAAGGGGTTTGGTCTCTGTGCCAGCTCTATAATTGTTTTGCTAC

GATTCCACTGAAACTCTTCGATCAAGCTACTTTATGTAAATCACTTCATTGTTTTAA

AGGAATAAACTTGATTATATTGTTTTTTTATTTGGCATAACTGTGATTCTTTTAGGA

CAATTACTGTACACATTAAGGTGTATGTCAGATATTCATATTGACCCAAATGTGTAA

TATTCCAGTTTTCTCTGCATAAGTAATTAAAATATACTTAAAAATTAATAGTTTTAT

CTGGGTACAAATAAACAGGTGCCTGAACTAGTTCACAGACAAGGAAACTTCTATGTA

AAAATCACTATGATTTCTGAATTGCTATGTGAAACTACAGATCTTTGGAACACTGTT

TAGGTAGGGTGTTAAGACTTACACAGTACCTCGTTTCTACACAGAGAAAGAAATGGC

CATACTTCAGGAACTGCAGTGCTTATGAGGGGATATTTAGGCCTCTTGAATTTTTGA

TGTAGATGGGCATTTTTTTAAGGTAGTGGTTAATTACCTTTATGTGAACTTTGAATG

GTTTAACAAAAGATTTGTTTTTGTAGAGATTTTAAAGGGGGAGAATTCTAGAAATAA

ATGTTACCTAATTATTACAGCCTTAAAGACAAAAATCCTTGTTGAAGTTTTTTTAAA

AAAAGCTAAATTACATAGACTTAGGCATTAACATGTTTGTGGAAGAATATAGCAGAC

GTATATTGTATCATTTGAGTGAATGTTCCCAAGTAGGCATTCTAGGCTCTATTTAAC

TGAGTCACACTGCATAGGAATTTAGAACCTAACTTTTATAGGTTATCAAAACTGTTG

TCACCATTGCACAATTTTGTCCTAATATATACATAGAAACTTTGTGGGGCATGTTAA

GTTACAGTTTGCACAAGTTCATCTCATTTGTATTCCATTGATTTTTTTTTTCTTCTA

AACATTTTTTCTTCAAACAGTATATAACTTTTTTTAGGGGATTTTTTTTTAGACAGC

AAAAACTATCTGAAGATTTCCATTTGTCAAAAAGTAATGATTTCTTGATAATTGTGT

AGTAATGTTTTTTAGAACCCAGCAGTTACCTTAAAGCTGAATTTATATTTAGTAACT

TCTGTGTTAATACTGGATAGCATGAATTCTGCATTGAGAAACTGAATAGCTGTCATA

AAATGAAACTTTCTTTCTAAAGAAAGATACTCACATGAGTTCTTGAAGAATAGTCAT

AACTAGATTAAGATCTGTGTTTTAGTTTAATAGTTTGAAGTGCCTGTTTGGGATAAT

GATAGGTAATTTAGATGAATTTAGGGGAAAAAAAAGTTATCTGCAGATATGTTGAGG

GCCCATCTCTCCCCCCACACCCCCACAGAGCTAACTGGGTTACAGTGTTTTATCCGA

AAGTTTCCAATTCCACTGTCTTGTGTTTTCATGTTGAAAATACTTTTGCATTTTTCC

TTTGAGTGCCAATTTCTTACTAGTACTATTTCTTAATGTAACATGTTTACCTGGAAT

GTATTTTAACTATTTTTGTATAGTGTAAACTGAAACATGCACATTTTGTACATTGTG

CTTTCTTTTGTGGGACATATGCAGTGTGATCCAGTTGTTTTCCATCATTTGGTTGCG

CTGACCTAGGAATGTTGGTCATATCAAACATTAAAAATGACCACTCTTTTAATTGAA

ATTAACTTTTAAATGTTTATAGGAGTATGTGCTGTGAAGTGATCTAAAATTTGTAAT

ATTTTTGTCATGAACTGTACTACTCCTAATTATTGTAATGTAATAAAAATAGTTACA

GTGAC (SEQ ID NO: 211)

>NP_004976.2 GTPase KRas isoform b [Homo sapiens]

MTEYKLVVVGAGGVGKSALTIQLIQNHFVDEYDPTIEDSYRKQVVIDGETCLLDILD

TAGQEEYSAMRDQYMRTGEGFLCVFAINNTKSFEDIHHYREQIKRVKDSEDVPMVLV

GNKCDLPSRTVDTKQAQDLARSYGIPFIETSAKTRQGVDDAFYTLVREIRKHKEKMS

KDGKKKKKKSKTKCVIM (SEQ ID NO: 212)

>Lipid affinity tag nucleotide sequence

AAAAAGAAGAAAAAGAAGAAGAAGACAAAGTGTGTAATTATG (SEQ ID NO: 213)

>Lipid affinity tag peptide sequence

KKKKKKKKTKCVIM (SEQ ID NO: 214)

Myr/Palm tag
>NM_002356.7 Homo sapiens myristoylated alanine rich

modified from
protein kinase C substrate (MARCKS), mRNA

Human MARCKS
GCACTTGGGCGTTGGACCCCGCATCTTATTAGCAACCAGGGAGATTTCTCCATTTTC

CTCTTGTCTACAGTGCGGCTACAAATCTGGGATTTTTTTATTACTTCTTTTTTTTTC

GAACTACACTTGGGCTCCTTTTTTTGTGCTCGACTTTTCCACCCTTTTTCCCTCCCT

CCTGTGCTGCTGCTTTTTGATCTCTTCGACTAAAATTTTTTTATCCGGAGTGTATTT

AATCGGTTCTGTTCTGTCCTCTCCACCACCCCCACCCCCCTCCCTCCGGTGTGTGTG

CCGCTGCCGCTGTTGCCGCCGCCGCTGCTGCTGCTGCTCGCCCCGTCGTTACACCAA

CCCGAGGCTCTTTGTTTCCCCTCTTGGATCTGTTGAGTTTCTTTGTTGAAGAAGCCA

GCATGGGTGCCCAGTTCTCCAAGACCGCAGCGAAGGGAGAAGCCGCCGCGGAGAGGC

CTGGGGAGGCGGCTGTGGCCTCGTCGCCTTCCAAAGCGAACGGACAGGAGAATGGCC

ACGTGAAGGTAAACGGCGACGCTTCGCCCGCGGCCGCCGAGTCGGGCGCCAAGGAGG

AGCTGCAGGCCAACGGCAGCGCCCCGGCCGCCGACAAGGAGGAGCCCGCGGCCGCCG

GGAGCGGGGCGGCGTCGCCCTCCGCGGCCGAGAAAGGTGAGCCGGCCGCCGCCGCTG

CCCCCGAGGCCGGGGCCAGCCCGGTAGAGAAGGAGGCCCCCGCGGAAGGCGAGGCTG

CCGAGCCCGGCTCGCCCACGGCCGCGGAGGGAGAGGCCGCGTCGGCCGCCTCCTCGA

CTTCTTCGCCCAAGGCCGAGGACGGGGCCACGCCCTCGCCCAGCAACGAGACCCCGA

AAAAAAAAAAGAAGCGCTTTTCCTTCAAGAAGTCTTTCAAGCTGAGCGGCTTCTCCT

TCAAGAAGAACAAGAAGGAGGCTGGAGAAGGCGGTGAGGCTGAGGCGCCCGCTGCCG

AAGGCGGCAAGGACGAGGCCGCCGGGGGCGCAGCTGCGGCCGCCGCCGAGGCGGGCG

CGGCCTCCGGGGAGCAGGCAGCGGCGCCGGGCGAGGAGGCGGCAGCGGGCGAGGAGG

GGGCGGCGGGTGGCGACCCGCAGGAGGCCAAGCCCCAGGAGGCCGCTGTCGCGCCAG

AGAAGCCGCCCGCCAGCGACGAGACCAAGGCCGCCGAGGAGCCCAGCAAGGTGGAGG

AGAAAAAGGCCGAGGAGGCCGGGGCCAGCGCCGCCGCCTGCGAGGCCCCCTCCGCCG

CCGGGCCCGGCGCGCCCCCGGAGCAGGAGGCAGCCCCCGCGGAGGAGCCCGCGGCCG

CCGCAGCCTCGTCAGCCTGCGCAGCCCCCTCACAGGAGGCCCAGCCCGAGTGCAGTC

CAGAAGCCCCCCCAGCGGAGGCGGCAGAGTAAAAGAGCAAGCTTTTGTGAGATAATC

GAAGAACTTTTCTCCCCCGTTTGTTTGTTGGAGTGGTGCCAGGTACTGGTTTTGGAG

AACTTGTCTACAACCAGGGATTGATTTTAAAGATGTCTTTTTTTATTTTACTTTTTT

TTAAGCACCAAATTTTGTTGTTTTTTTTTTTTCTCCCCTCCCCACAGATCCCATCTC

AAATCATTCTGTTAACCACCATTCCAACAGGTCGAGGAGAGCTTAAACACCTTCTTC

CTCTGCCTTGTTTCTCTTTTATTTTTTATTTTTTCGCATCAGTATTAATGTTTTTGC

ATACTTTGCATCTTTATTCAAAAGTGTAAACTTTCTTTGTCAATCTATGGACATGCC

CATATATGAAGGAGATGGGTGGGTCAAAAAGGGATATCAAATGAAGTGATGGGGTCA

CAATGGGGAAATTGAAGTGGTGCATAACATTGCCAAAATAGTGTGCCACTAGAAATG

GTGTAAAGGCTGTCTTTTTTTTTTTTTTAAAAGAAAAGTTATTACCATGTATTTTGT

GAGGCAGGTTTACAACACTACAAGTCTTGAGTTAAGAAGGAAAGAGGAAAAAAGAAA

AAACACCAATACCCAGATTTAAAAAAAAAAAAACGATCATAGTCTTAGGAGTTCATT

TAAACCATAGGAACTTTTCACTTATCTCATGTTAGCTGTACCAGTCAGTGATTAAGT

AGAACTACAAGTTGTATAGGCTTTATTGTTTATTGCTGGTTTATGACCTTAATAAAG

TGTAATTATGTATTACCAGCAGGGTGTTTTTAACTGTGACTATTGTATAAAAACAAA

TCTTGATATCCAGAAGCACATGAAGTTTGCAACTTTCCACCCTGCCCATTTTTGTAA

AACTGCAGTCATCTTGGACCTTTTAAAACACAAATTTTAAACTCAACCAAGCTGTGA

TAAGTGGAATGGTTACTGTTTATACTGTGGTATGTTTTTGATTACAGCAGATAATGC

TTTCTTTTCCAGTCGTCTTTGAGAATAAAGGAAAAAAAATCTTCAGATGCAATGGTT

TTGTGTAGCATCTTGTCTATCATGTTTTGTAAATACTGGAGAAGCTTTGACCAATTT

GACTTAGAGATGGAATGTAACTTTGCTTACAAAAATTGCTATTAAACTCCTGCTTAA

GGTGTTCTAATTTTCTGTGAGCACACTAAAAGCGAAAAATAAATGTGAATAAAATGT

ACAAATTTGTTGTGTTTTTTTATGTTCTAATAATACTGAGACTTCTAGGTCTTAGGT

TAATTTTTAGGAAGATCTTGCATGCCATCAGGAGTAAATTTTATTGTGGTTCTTAAT

CTGAAGTTTTCAAGCTCTGAAATTCATAATCCGCAGTGTCAGATTACGTAGAGGAAG

ATCTTACAACATTTCCATGTCAAATCTGTTACCATTTATTGGCATTTAGTTTTCATT

TAAGAATTGAACATAATTATTTTTATTGTAGCTATATAGCATGTCAGATTAAATCAT

TTACAACAAAAGGGGTGTGAACCTAAGACTATTTAAATGTCTTATGAGAAAATTTCA

TAAAGCCATTCTCTTGTCATTCAGGTCCAGAAACAAATTTTAAACTGAGTGAGAGTC

TATAGAATCCATACTGCAGATGGGTCATGAAATGTGACCAAATGTGTTTCAAAAATT

GATGGTGTATTACCTGCTATTGTAATTGCTTAGTGCTTGGCTAATTTCCAAATTATT

GCATAATATGTTCTACCTTAAGAAAACAGGTTTATGTAACAAAGTAATGGTGTTGAA

TGGATGATGTCAGTTCATGGGCCTTTAGCATAGTTTTAAGCATCCTTTTTTTTTTTT

TTTTTTGAAAGTGTGTTAGCATCTTGTTACTCAAAGGATAAGACAGACAATAATACT

TCACTGAATCTTAATAATCTTTACTAGTTTACCTCCTCTGCTCTTTGCCACCCGATA

ACTGGATATCTTTTCCTTCAAAGGACCCTAAACTGATTGAAATTTAAGATATGTATC

AAAAACATTATTTCATTTAATGCACATCTGTTTTGCTGTTTTTGAGCAGTGTGCAGT

TTAGGGTTCATGATAAATCATTGAACCACATGTGTAACAACTGAATGCCAAATCTTA

AACTCATTAGAAAAATAACAAATTAGGTTTTGACACGCATTCTTAATTGGAATAATG

GATCAAAAATAGTGGTTCATGACCTTACCAAACACCCTTGCTACTAATAAAATCAAA

TAACACTTAGAAGGGTATGTATTTTTAGTTAGGGTTTCTTGATCTTGGAGGATGTTT

GAAAGTTAAAAATTGAATTTGGTAACCAAAGGACTGATTTATGGGTCTTTCCTATCT

TAACCAACGTTTTCTTAGTTACCTAGATGGCCAAGTACAGTGCCTGGTATGTAGTAA

GACTCAGTAAAAAAGTGGATTTTTAAAAATAACTCCCAAAGTGAATAGTCAAAAATC

CTGTTAGCAAACTGTTATATATTGCTAAGTTTGTTCTTTTAACAGCTGGAATTTATT

AAGATGCATTATTTTGATTTTATTCACTGCCTAAAACACTTTGGGTGGTATTGATGG

AGTTGGTGGATTTTCCTCCAAGTGATTAAATGAAATTTGACGTATCTTTTCATCCAA

AGTTTTGTACATCATGTTTTCTAACGGAAAAAAATGTTAATATGGCTTTTTTGTATT

ACTAAAAATAGCTTTGAGATTAAGGAAAAATAAATAACTCTTGTACAGTTCAGTATT

GTCTATTAAATCTGTATTGGCAGTATGTATAATGGCATTTGCTGTGGTTACAAAATA

CTTCCTCTGGGTTATAATAATCATTTGATCCAATTCCTATTGCTTGTAAAATAAAGT

TTTACCAGTTGATATAATCAA (SEQ ID NO: 215)

>NP_002347.5 myristoylated alanine-rich C-kinase

substrate [Homo sapiens]

MGAQFSKTAAKGEAAAERPGEAAVASSPSKANGQENGHVKVNGDASPAAAESGAKEE

LQANGSAPAADKEEPAAAGSGAASPSAAEKGEPAAAAAPEAGASPVEKEAPAEGEAA

EPGSPTAAEGEAASAASSTSSPKAEDGATPSPSNETPKKKKKRFSFKKSFKLSGFSF

KKNKKEAGEGGEAEAPAAEGGKDEAAGGAAAAAAEAGAASGEQAAAPGEEAAAGEEG

AAGGDPQEAKPQEAAVAPEKPPASDETKAAEEPSKVEEKKAEEAGASAAACEAPSAA

GPGAPPEQEAAPAEEPAAAAASSACAAPSQEAQPECSPEAPPAEAAE (SEQ ID

NO: 216)

>Myr/Palm tag modified from Human MARCKS, nucleotide

sequence

ATGGGTTGCTGTTTCTCCAAGACC (SEQ ID NO: 217)

>Myr/Palm tag modified from Human MARCKS, peptide

sequence

MGCCFSKT (SEQ ID NO: 218)

In some embodiments of any of the aspects provided herein, the fusion polypeptide further comprises a peptide linker. The linker may be flexible, rigid, or cleavable. Further, the linker can be linked directly or via another linker (e.g., a peptide of one, two, three, four, five, six, seven, eight, nine, ten or more amino acids) to the fusion polypeptides described herein. Linkers can be configured according to a specific need, e.g., based on at least one of the following characteristics. In some embodiments of any of the aspects, linkers can be configured to have a sufficient length and flexibility such that it can allow for a cleavage at a target site. In some embodiments of any of the aspects, linkers can be configured to allow multimerization of the fusion polypeptides provided herein. In some embodiments of any of the aspects, linkers can be configured to facilitate expression and purification of the fusion proteins or engineered extracellular vesicles provided herein.

In some embodiments of any of the aspects, a linker can be configured to have any length in a form of a peptide, peptidomimetic, an aptamer, a protein, a nucleic acid (e.g., DNA or RNA), or any combinations thereof. For example, in one embodiment, the linker may be a polypeptide linker such as Gly-Ser-Ser-Gly or a variation thereof as known by one of ordinary skill in the art. In another embodiment the linker may be a protein sequence for a self-cleavable peptide. For example, 2A sequences such as P2A, E2A, F2A, and T2A code for self-cleavable peptides by inducing ribosomal slippage on the mRNA at the 2A site which prevents peptide bond formation. The slippage will result in two separate peptides after translation. This allows the expression of two separate proteins from one promoter region. Any combination of the proteins described herein may be expressed with a self-cleavable peptide as known by one of ordinary skill in the art.

In some embodiments of any of the aspects, the polypeptide linker is a non-cleavable linker. In some embodiments of any of the aspects, a linker can be a chemical linker of any length.

In some embodiments of any of the aspects, the linker is an Fc linker. An exemplary nucleic acid sequence encoding an Fc polypeptide is:

>KY053479.1 Synthetic construct Fc-adiponectin gene, complete cds

(SEQ ID NO: 219)

ATGTACAGGATGCAACTCCTGTCTTGCATTGCACTAAGTCTTGCACTTGTCACGAACTCGATATCGGCCA

TGGTTAGATCTGACAAAACTCACACATGCCCACCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGT

CTTCCTCTTCCCCCCAAAACCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTG

GTGGACGTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAGGTGCATAATG

CCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTGGTCAGCGTCCTCACCGTCCTGCA

CCAGGACTGGCTGAATGGCAAGGAGTACAAGTGCAAGGTCTCCAACAAAGCCCTCCCAGCCCCCATCGAG

AAAACCATCTCCAAAGCCAAAGGGCAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGG

AGATGACCAAGAACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCCGTGGA

GTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTGCTGGACTCCGACGGCTCC

TTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGGCAGCAGGGGAACGTCTTCTCATGCTCCG

TGATGCACGAGGCTCTGCACAACCACTACACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAGCCAGCGG

AAGTGGCGGAGGAGGCGGTCCTGGAGAAGGTGCCTATGTATACCGCTCAGCATTCAGTGTGGGATTGGAG

ACTTACGTTACTATCCCCAACATGCCCATTCGCTTTACCAAGATCTTCTACAATCAGCAAAACCACTATG

ATGGCTCCACTGGTAAATTCCACTGCAACATTCCTGGGCTGTACTACTTTGCCTACCACATCACAGTCTA

TATGAAGGATGTGAAGGTCAGCCTCTTCAAGAAGGACAAGGCTATGCTCTTCACCTATGATCAGTACCAG

GAAAATAATGTGGACCAGGCCTCCGGCTCTGTGCTCCTGCATCTGGAGGTGGGCGACCAAGTCTGGCTCC

AGGTGTATGGGGAAGGAGAGCGTAATGGACTCTATGCTGATAATGACAATGACTCCACCTTCACAGGCTT

TCTTCTCTACCATGACACCAACTCTAGAAAGCTTCCTGGAGAAGGTGCCTATGTATACCGCTCAGCATTC

AGTGTGGGATTGGAGACTTACGTTACTATCCCCAACATGCCCATTCGCTTTACCAAGATCTTCTACAATC

AGCAAAACCACTATGATGGCTCCACTGGTAAATTCCACTGCAACATTCCTGGGCTGTACTACTTTGCCTA

CCACATCACAGTCTATATGAAGGATGTGAAGGTCAGCCTCTTCAAGAAGGACAAGGCTATGCTCTTCACC

TATGATCAGTACCAGGAAAATAATGTGGACCAGGCCTCCGGCTCTGTGCTCCTGCATCTGGAGGTGGGCG

ACCAAGTCTGGCTCCAGGTGTATGGGGAAGGAGAGCGTAATGGACTCTATGCTGATAATGACAATGACTC

CACCTTCACAGGCTTTCTTCTCTACCATGACACCAACACTAGTCCTGGAGAAGGTGCCTATGTATACCGC

TCAGCATTCAGTGTGGGATTGGAGACTTACGTTACTATCCCCAACATGCCCATTCGCTTTACCAAGATCT

TCTACAATCAGCAAAACCACTATGATGGCTCCACTGGTAAATTCCACTGCAACATTCCTGGGCTGTACTA

CTTTGCCTACCACATCACAGTCTATATGAAGGATGTGAAGGTCAGCCTCTTCAAGAAGGACAAGGCTATG

CTCTTCACCTATGATCAGTACCAGGAAAATAATGTGGACCAGGCCTCCGGCTCTGTGCTCCTGCATCTGG

AGGTGGGCGACCAAGTCTGGCTCCAGGTGTATGGGGAAGGAGAGCGTAATGGACTCTATGCTGATAATGA

CAATGACTCCACCTTCACAGGCTTTCTTCTCTACCATGACACCAACTAA.

The amino acid sequence of the Fc linker is:

>Fc Translation

(SEQ ID NO: 220)

DKTHTCPPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVDVSHEDPEVKFNWYVDGVEVHNAKTK

PREEQYNSTYRVVSVLTVLHQDWLNGKEYKCKVSNKALPAPIEKTISKAKGQPREPQVYTLPPSREEMTK

NQVSLTCLVKGFYPSDIAVEWESNGQPENNYKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHE

ALHNHYTQKSLSLSPGK.

In some embodiments of any of the aspects, the linker is a P2A peptide linker. P2A is a self-cleaving peptide sequence allowing for expression of two proteins from one promoter. In some embodiments, the P2A linker is encoded by the nucleic acid sequence: GCTACTAACTTCAGCCTGCTGAAGCAG (SEQ ID NO: 221). The amino acid sequence of P2A is ATNFSLKQAGDVENPGP (SEQ ID NO: 222).

In some embodiments of any of the aspects, the linker is provides a multimerization (e.g., dimerization) domain wherein one fusion polypeptide may connect with another fusion polypeptide at each fusion polypeptide's respective multimerization domain. Multimerization of multiple fusion polypeptides will provide multiple fusion polypeptides within close proximity to one another to one or more a target receptor on the target cell, wherein the multiple fusion peptides will enhance receptor clustering on the target cell. Clustering receptors on a target cell will result in enhanced signal transduction. Without receptor clustering a signal may be weaker or not occur all together. For example, Fc domain sequences presented herein dimerize resulting in two fusion polypeptides connected by a covalent bond via the two Fc domains on their respective fusion polypeptide. One preferred embodiment of an Fc domain is from IgG4, herein labeled 4Fc. In other embodiments Fc may be from IgG1, herein labeled Fc. In certain embodiments Fc from other immunoglobulin, (e.g., IgG2, IgG3, etc.) may be used.

Additional non-limiting examples of linkers that can be used and their properties are further described in detail, e.g., in Chen X, Zaro J L, Shen W C. Fusion protein linkers: property, design and functionality. Adv Drug Deliv Rev. 2013; 65(10):1357-1369. doi: 10.1016/j.addr.2012.09.039; O'Shea E K, Lumb K J, Kim P S. Peptide ‘Velcro’: design of a heterodimeric coiled coil. Curr Biol. 1993 Oct. 1; 3(10):658-67. doi: 10.1016/0960-9822(93)90063-t. PMID: 15335856; and Miller K M, Arndt K M, Alber T. Protein fusions to coiled-coil domains. Methods Enzymol. 2000; 328:261-82. doi: 10.1016/s0076-6879(00)28402-4. PMID: 11075350, the contents of which are incorporated herein by reference in their entireties.

The engineered extracellular vesicle compositions provided herein can comprise variations in the configuration of the POI domain, linkers, and/or vesicle targeting domain. The specific combination and localization of these domains can enhance fusion polypeptide anchoring, function, or therapeutic effect, e.g., modulating inflammation.

Thus, in one aspect, provided herein is an engineered extracellular vesicle comprising: at least one fusion polypeptide comprising: (i) at least one protein of interest (POI) domain or a fragment thereof; and (ii) at least one vesicle targeting domain, wherein the POI domain is in an extracellular position relative to a lipid membrane of the extracellular vesicle.

In some embodiments, the POI domain or a fragment thereof is a N-terminal domain of the fusion polypeptide. In some embodiments, the vesicle targeting domain or a fragment thereof is a C-terminal domain of the fusion polypeptide.

In another aspect, provided herein is an engineered extracellular vesicle comprising: at least one fusion polypeptide comprising: (i) at least one protein of interest (POI) domain or a fragment thereof; and (ii) at least one vesicle targeting domain, wherein the POI domain is in an extracellular position relative to a lipid membrane of the extracellular vesicle, and wherein the vesicle targeting domain is a transmembrane domain relative to a lipid membrane of the extracellular vesicle.

In some embodiments, the POI domain or a fragment thereof is a C-terminal domain of the fusion polypeptide. In some embodiments, the vesicle targeting domain or a fragment thereof is a N-terminal domain of the fusion polypeptide. In some embodiments, the vesicle targeting domain is in a luminal position relative to the lipid membrane of the extracellular vesicle.

In some embodiments, the linker is in an exterior position relative to the lipid membrane of the extracellular vesicle. In some embodiments, the linker is a transmembrane linker. In some embodiments, the linker is in a luminal position relative to the lipid membrane of the extracellular vesicle.

The engineered extracellular vesicle compositions provided herein can comprise one or more of the following fusion polypeptide sequences in Table 4. The vector maps depicting the sequences below are shown in the working examples in FIGS. 5A, 5C, 5G, 5I, 5K, and 22-67.

TABLE 4

Full Length Constructs

Fusion
Nucleic Acid Sequence (SEQ ID NO:)

Polypeptide
Amino Acid Sequence (SEQ ID NO:)

hCTLA4-Fc-GPI
>Artificial sequence; hCTLA4-Fc-GPI, DNA

ATGGCTTGCCTTGGATTTCAGCGGCACAAGGCTCAGCTGAACCTGGCTACCAGGACC

TGGCCCTGCACTCTCCTGTTTTTTCTTCTCTTCATCCCTGTCTTCTGCAAAGCAATG

CACGTGGCCCAGCCTGCTGTGGTACTGGCCAGCAGCCGAGGCATCGCCAGCTTTGTG

TGTGAGTATGCATCTCCAGGCAAAGCCACTGAGGTCCGGGTGACAGTGCTTCGGCAG

GCTGACAGCCAGGTGACTGAAGTCTGTGCGGCAACCTACATGATGGGGAATGAGTTG

ACCTTCCTAGATGATTCCATCTGCACGGGCACCTCCAGTGGAAATCAAGTGAACCTC

ACTATCCAAGGACTGAGGGCCATGGACACGGGACTCTACATCTGCAAGGTGGAGCTC

ATGTACCCACCGCCATACTACCTGGGCATAGGCAACGGAACCCAGATTTATGTAATT

GATCCAGAACCGTGCCCAGATTCTGACATCGATGACAAAACTCACACATGCCCACCG

TGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCAAAACCC

AAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTGGACGTG

AGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAGGTGCAT

AATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTGGTCAGC

GTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGCAAGGTC

TCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAAGGGCAG

CCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATGACCAAGAAC

CAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCCGTGGAG

TGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTGCTGGAC

TCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGGCAG

CAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAACCACTACACG

CAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATCCAAATAAAGGAAGTGGAACC

ACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTG

CTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 223)

>Artificial sequence; hCTLA4-Fc-GPI, Amino Acid

MACLGFQRHKAQLNLATRTWPCTLLFFLLFIPVFCKAMHVAQPAVVLASSRGIASFV

CEYASPGKATEVRVTVLRQADSQVTEVCAATYMMGNELTFLDDSICTGTSSGNQVNL

TIQGLRAMDTGLYICKVELMYPPPYYLGIGNGTQIYVIDPEPCPDSDIDDKTHTCPP

CPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVDVSHEDPEVKENWYVDGVEVH

NAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCKVSNKALPAPIEKTISKAKGQ

PREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAVEWESNGQPENNYKTTPPVLD

SDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHYTQKSLSLSPGKIDPNKGSGT

TSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 224)

hPDL1-GPI
>Artificial sequence; hPDL1-GPI, DNA

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGG
CCAAATAAAGGAAGTGGAACCACTTCA

GGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGG

ACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 225)

>Amino Acid Sequence; hPDL1-GPI, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLENVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNER
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 226)

hPDL1-C1C2
>Artificial Sequence; hPDL1-C1C2, DNA

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGGATCGATGTCGAGCCACTGGGCATGGAG

AATGGGAACATTGCCAACTCACAGATCGCCGCCTCATCTGTGCGTGTGACCTTCTTG

GGTTTGCAGCATTGGGTCCCGGAGCTGGCCCGCCTGAACCGCGCAGGCATGGTCAAT

GCCTGGACACCCAGCAGCAATGACGATAACCCCTGGATCCAGGTGAACCTGCTGCGG

AGGATGTGGGTAACAGGTGTGGTGACGCAGGGTGCCAGCCGCTTGGCCAGTCATGAG

TACCTGAAGGCCTTCAAGGTGGCCTACAGCCTTAATGGACACGAATTCGATTTCATC

CATGATGTTAATAAAAAACACAAGGAGTTTGTGGGTAACTGGAACAAAAACGCGGTG

CATGTCAACCTGTTTGAGACCCCTGTGGAGGCTCAGTACGTGAGATTGTACCCCACG

AGCTGCCACACGGCCTGCACTCTGCGCTTTGAGCTACTGGGCTGTGAGCTGAACGGA

TGCGCCAATCCCCTGGGCCTGAAGAATAACAGCATCCCTGACAAGCAGATCACGGCC

TCCAGCAGCTACAAGACCTGGGGCTTGCATCTCTTCAGCTGGAACCCCTCCTATGCA

CGGCTGGACAAGCAGGGCAACTTCAACGCCTGGGTTGCGGGGAGCTACGGTAACGAT

CAGTGGCTGCAGATCTTCCCTGGCAACTGGGACAACCACTCCCACAAGAAGAACTTG

TTTGAGACGCCCATCCTGGCTCGCTATGTGCGCATCCTGCCTGTAGCCTGGCACAAC

CGCATCGCCCTGCGCCTGGAGCTGCTGGGCTGTTAG

(SEQ ID NO: 227)

>Artificial Sequence, hPDL1-C1C2, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLENVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNERIDVEPLGMENGNIANSQIAASSVRVTFLGLQHWVPELARLNRAGMVN

AWTPSSNDDNPWIQVNLLRRMWVTGVVTQGASRLASHEYLKAFKVAYSLNGHEFDFI

HDVNKKHKEFVGNWNKNAVHVNLFETPVEAQYVRLYPTSCHTACTLRFELLGCELNG

CANPLGLKNNSIPDKQITASSSYKTWGLHLFSWNPSYARLDKQGNENAWVAGSYGND

QWLQIFPGNWDNHSHKKNLFETPILARYVRILPVAWHNRIALRLELLGC

(SEQ ID NO: 228)

hPDL1-Fc-GPI
>Artificial Sequence; hPDL1-Fc-GPI, DNA

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGGATCGATGACAAAACTCACACATGCCCA

CCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCAAAA

CCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTGGAC

GTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAGGTG

CATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTGGTC

AGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGCAAG

GTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAAGGG

CAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATGACCAAG

AACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCCGTG

GAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTGCTG

GACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGG

CAGCAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAACCACTAC

ACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATCCAAATAAAGGAAGTGGA

ACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGT

TTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 229)

>Artificial Sequence; hPDL1-Fc-GPI, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNERIDDKTHTCPPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVD

VSHEDPEVKENWYVDGVEVHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCK

VSNKALPAPIEKTISKAKGQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAV

EWESNGQPENNYKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHY

TQKSLSLSPGKIDPNKGSGTTSGTTRLLSGHTCFTLTGLIGTLVTMGLLT

(SEQ ID NO: 230)

hPDL2-C1C2
>Artificial Sequence; hPDL2-C1C2, DNA

ATGATCTTCCTCCTGCTAATGTTGAGCCTGGAATTGCAGCTTCACCAGATAGCAGCT

TTATTCACAGTGACAGTCCCTAAGGAACTGTACATAATAGAGCATGGCAGCAATGTG

ACCCTGGAATGCAACTTTGACACTGGAAGTCATGTGAACCTTGGAGCAATAACAGCC

AGTTTGCAAAAGGTGGAAAATGATACATCCCCACACCGTGAAAGAGCCACTTTGCTG

GAGGAGCAGCTGCCCCTAGGGAAGGCCTCGTTCCACATACCTCAAGTCCAAGTGAGG

GACGAAGGACAGTACCAATGCATAATCATCTATGGGGTCGCCTGGGACTACAAGTAC

CTGACTCTGAAAGTCAAAGCTTCCTACAGGAAAATAAACACTCACATCCTAAAGGTT

CCAGAAACAGATGAGGTAGAGCTCACCTGCCAGGCTACAGGTTATCCTCTGGCAGAA

GTATCCTGGCCAAACGTCAGCGTTCCTGCCAACACCAGCCACTCCAGGACCCCTGAA

GGCCTCTACCAGGTCACCAGTGTTCTGCGCCTAAAGCCACCCCCTGGCAGAAACTTC

AGCTGTGTGTTCTGGAATACTCACGTGAGGGAACTTACTTTGGCCAGCATTGACCTT

CAAAGTCAGATGGAACCCAGGACCCATCCAACTATCGATGTCGAGCCACTGGGCATG

GAGAATGGGAACATTGCCAACTCACAGATCGCCGCCTCATCTGTGCGTGTGACCTTC

TTGGGTTTGCAGCATTGGGTCCCGGAGCTGGCCCGCCTGAACCGCGCAGGCATGGTC

AATGCCTGGACACCCAGCAGCAATGACGATAACCCCTGGATCCAGGTGAACCTGCTG

CGGAGGATGTGGGTAACAGGTGTGGTGACGCAGGGTGCCAGCCGCTTGGCCAGTCAT

GAGTACCTGAAGGCCTTCAAGGTGGCCTACAGCCTTAATGGACACGAATTCGATTTC

ATCCATGATGTTAATAAAAAACACAAGGAGTTTGTGGGTAACTGGAACAAAAACGCG

GTGCATGTCAACCTGTTTGAGACCCCTGTGGAGGCTCAGTACGTGAGATTGTACCCC

ACGAGCTGCCACACGGCCTGCACTCTGCGCTTTGAGCTACTGGGCTGTGAGCTGAAC

GGATGCGCCAATCCCCTGGGCCTGAAGAATAACAGCATCCCTGACAAGCAGATCACG

GCCTCCAGCAGCTACAAGACCTGGGGCTTGCATCTCTTCAGCTGGAACCCCTCCTAT

GCACGGCTGGACAAGCAGGGCAACTTCAACGCCTGGGTTGCGGGGAGCTACGGTAAC

GATCAGTGGCTGCAGATCTTCCCTGGCAACTGGGACAACCACTCCCACAAGAAGAAC

TTGTTTGAGACGCCCATCCTGGCTCGCTATGTGCGCATCCTGCCTGTAGCCTGGCAC

AACCGCATCGCCCTGCGCCTGGAGCTGCTGGGCTGTTAG

(SEQ ID NO: 231)

>Artificial Sequence; hPDL2-C1C2, Amino Acid

MIFLLLMLSLELQLHQIAALFTVTVPKELYIIEHGSNVTLECNFDTGSHVNLGAITA

SLQKVENDTSPHRERATLLEEQLPLGKASFHIPQVQVRDEGQYQCIIIYGVAWDYKY

LTLKVKASYRKINTHILKVPETDEVELTCQATGYPLAEVSWPNVSVPANTSHSRTPE

GLYQVTSVLRLKPPPGRNFSCVFWNTHVRELTLASIDLQSQMEPRTHPTIDVEPLGM

ENGNIANSQIAASSVRVTFLGLQHWVPELARLNRAGMVNAWTPSSNDDNPWIQVNLL

RRMWVTGVVTQGASRLASHEYLKAFKVAYSLNGHEFDFIHDVNKKHKEFVGNWNKNA

VHVNLFETPVEAQYVRLYPTSCHTACTLRFELLGCELNGCANPLGLKNNSIPDKQIT

ASSSYKTWGLHLFSWNPSYARLDKQGNFNAWVAGSYGNDQWLQIFPGNWDNHSHKKN

LFETPILARYVRILPVAWHNRIALRLELLGC

(SEQ ID NO: 232)

hPDL2-Fc-GPI
>Artificial Sequence; hPDL2-Fc-GPI, DNA

ATGATCTTCCTCCTGCTAATGTTGAGCCTGGAATTGCAGCTTCACCAGATAGCAGCT

TTATTCACAGTGACAGTCCCTAAGGAACTGTACATAATAGAGCATGGCAGCAATGTG

ACCCTGGAATGCAACTTTGACACTGGAAGTCATGTGAACCTTGGAGCAATAACAGCC

AGTTTGCAAAAGGTGGAAAATGATACATCCCCACACCGTGAAAGAGCCACTTTGCTG

GAGGAGCAGCTGCCCCTAGGGAAGGCCTCGTTCCACATACCTCAAGTCCAAGTGAGG

GACGAAGGACAGTACCAATGCATAATCATCTATGGGGTCGCCTGGGACTACAAGTAC

CTGACTCTGAAAGTCAAAGCTTCCTACAGGAAAATAAACACTCACATCCTAAAGGTT

CCAGAAACAGATGAGGTAGAGCTCACCTGCCAGGCTACAGGTTATCCTCTGGCAGAA

GTATCCTGGCCAAACGTCAGCGTTCCTGCCAACACCAGCCACTCCAGGACCCCTGAA

GGCCTCTACCAGGTCACCAGTGTTCTGCGCCTAAAGCCACCCCCTGGCAGAAACTTC

AGCTGTGTGTTCTGGAATACTCACGTGAGGGAACTTACTTTGGCCAGCATTGACCTT

CAAAGTCAGATGGAACCCAGGACCCATCCAACTATCGATGACAAAACTCACACATGC

CCACCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCA

AAACCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTG

GACGTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAG

GTGCATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTG

GTCAGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGC

AAGGTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAA

GGGCAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATGACC

AAGAACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCC

GTGGAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTG

CTGGACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGG

TGGCAGCAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAACCAC

TACACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATCCAAATAAAGGAAGT

GGAACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACA

GGTTTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 233)

>Artificial Sequence; hPDL2-Fc-GPI, Amino Acid

MIFLLLMLSLELQLHQIAALFTVTVPKELYIIEHGSNVTLECNFDTGSHVNLGAITA

SLQKVENDTSPHRERATLLEEQLPLGKASFHIPQVQVRDEGQYQCIIIYGVAWDYKY

LTLKVKASYRKINTHILKVPETDEVELTCQATGYPLAEVSWPNVSVPANTSHSRTPE

GLYQVTSVLRLKPPPGRNFSCVFWNTHVRELTLASIDLQSQMEPRTHPTIDDKTHTC

PPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVDVSHEDPEVKENWYVDGVE

VHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCKVSNKALPAPIEKTISKAK

GQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAVEWESNGQPENNYKTTPPV

LDSDGSFFLYSKLTVDKSRWQQGNVESCSVMHEALHNHYTQKSLSLSPGKIDPNKGS

GTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 234)

4F2-h41BBL
>Artificial Sequence; 4F2-41BBL, DNA

ATGAGCCAGGACACCGAGGTGGATATGAAGGAGGTGGAGCTGAATGAGTTAGAGCCC

GAGAAGCAGCCGATGAACGCGGCGTCTGGGGCGGCCATGTCCCTGGCGGGAGCCGAG

AAGAATGGTCTGGTGAAGATCAAGGTGGCGGAAGACGAGGCGGAGGCGGCAGCCGCG

GCTAAGTTCACGGGCCTGTCCAAGGAGGAGCTGCTGAAGGTGGCAGGCAGCCCCGGC

TGGGTACGCACCCGCTGGGCACTGCTGCTGCTCTTCTGGCTCGGCTGGCTCGGCATG

CTTGCTGGTGCCGTGGTCATAATCGTG
GCCTGCCCCTGGGCCGTGTCCGGGGCTCGC

GCCTCGCCCGGCTCCGCGGCCAGCCCGAGACTCCGCGAGGGTCCCGAGCTTTCGCCC

GACGATCCCGCCGGCCTCTTGGACCTGCGGCAGGGCATGTTTGCGCAGCTGGTGGCC

CAAAATGTTCTGCTGATCGATGGGCCCCTGAGCTGGTACAGTGACCCAGGCCTGGCA

GGCGTGTCCCTGACGGGGGGCCTGAGCTACAAAGAGGACACGAAGGAGCTGGTGGTG

GCCAAGGCTGGAGTCTACTATGTCTTCTTTCAACTAGAGCTGCGGCGCGTGGTGGCC

GGCGAGGGCTCAGGCTCCGTTTCACTTGCGCTGCACCTGCAGCCACTGCGCTCTGCT

GCTGGGGCCGCCGCCCTGGCTTTGACCGTGGACCTGCCACCCGCCTCCTCCGAGGCT

CGGAACTCGGCCTTCGGTTTCCAGGGCCGCTTGCTGCACCTGAGTGCCGGCCAGCGC

CTGGGCGTCCATCTTCACACTGAGGCCAGGGCACGCCATGCCTGGCAGCTTACCCAG

GGCGCCACAGTCTTGGGACTCTTCCGGGTGACCCCCGAAATCCCAGCCGGACTCCCT

TCACCGAGGTCGGAATAA

(SEQ ID NO: 235)

>Artificial Sequence; 4F2-h41BBL, Amino Acid

MSQDTEVDMKEVELNELEPEKQPMNAASGAAMSLAGAEKNGLVKIKVAEDEAEAAAA

AKFTGLSKEELLKVAGSPGWVRTRWALLLLFWLGWLGMLAGAVVIIV
ACPWAVSGAR

ASPGSAASPRLREGPELSPDDPAGLLDLRQGMFAQLVAQNVLLIDGPLSWYSDPGLA

GVSLTGGLSYKEDTKELVVAKAGVYYVFFQLELRRVVAGEGSGSVSLALHLQPLRSA

AGAAALALTVDLPPASSEARNSAFGFQGRLLHLSAGQRLGVHLHTEARARHAWQLTQ

GATVLGLFRVTPEIPAGLPSPRSE

(SEQ ID NO: 236)

hPDL1-4Fc-GPI
>Artificial Sequence; hPDL1-4Fc-GPI, DNA

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGG
GAGTCCAAATATGGTCCCCCATGCCCA

TCATGCCCAGCACCTGAGTTCCTGGGGGGACCATCAGTCTTCCTGTTCCCCCCAAAA

CCCAAGGACACTCTCATGATCTCCCGGACCCCTGAGGTCACGTGCGTGGTGGTGGAC

GTGAGCCAGGAAGACCCCGAGGTCCAGTTCAACTGGTACGTGGATGGCGTGGAGGTG

CATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTTCAACAGCACGTACCGTGTGGTC

AGGGTCCTCACCGTCCTGCACCAGGACTGGCTGAACGGTAAGGAGTACAAGTGCAAG

GTCTCCAACAAAGGCCTCCCGTCCTCCATCGAGAAAACCATCTCCAAAGCCAAAGGG

CAGCCCCGAGAGCCACAGGTGTACACCCTGCCCCCATCCCAGGAGGAGATGACCAAG

AACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTACCCCAGCGACATCGCCGTG

GAGTGGGAGAGCAATGGGCAGCCGGAGGACAACTACAAGACCACGCCTCCCGTGCTG

GACTCCGACGGCTCCTTCTTCCTCTACAGCAGGCTAACCGTGGACAAGAGCAGGTGG

CAGGAGGGGAATGTCTTCTCATGCTCCGTGATGCATGAGGCTCTGCACAACCACTAC

ACACAGAAGAGCCTCTCCCTGTCTCCGGGTAAA
CCAAATAAAGGAAGTGGAACCACT

TCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTT

GGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 237)

>Artificial Sequence; hPDL1-4Fc-GPI, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNER
ESKYGPPCPSCPAPEFLGGPSVELFPPKPKDTLMISRTPEVTCVVVD

VSQEDPEVQFNWYVDGVEVHNAKTKPREEQFNSTYRVVRVLTVLHQDWLNGKEYKCK

VSNKGLPSSIEKTISKAKGQPREPQVYTLPPSQEEMTKNQVSLTCLVKGFYPSDIAV

EWESNGQPEDNYKTTPPVLDSDGSFFLYSRLTVDKSRWQEGNVFSCSVMHEALHNHY

TQKSLSLSPGK
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 238)

hPDL1-GPI-P2A-
>Artificial Sequence; hPDL1-GPI-P2A-hFGL1-GPI, DNA

hFGL1-GPI

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGG
CCAAATAAAGGAAGTGGAACCACTTCA

GGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGG

ACGCTAGTAACCATGGGCTTGCTGACTGGAAGCGGAGCTACTAACTTCAGCCTGCTG

AAGCAGGCTGGCGACGTGGAGGAGAACCCTGGACCT
ATGGCAAAGGTGTTCAGTTTC

ATCCTTGTTACCACCGCTCTGACAATGGGCAGGGAAATTTCGGCGCTCGAGGACTGT

GCCCAGGAGCAGATGCGGCTCAGAGCCCAGGTGCGCCTGCTTGAGACCCGGGTCAAA

CAGCAACAGGTCAAGATCAAGCAGCTTTTGCAGGAGAATGAAGTCCAGTTCCTTGAT

AAAGGAGATGAGAATACTGTCATTGATCTTGGAAGCAAGAGGCAGTATGCAGATTGT

TCAGAGATTTTCAATGATGGGTATAAGCTCAGTGGATTTTACAAAATCAAACCTCTC

CAGAGCCCAGCAGAATTTTCTGTTTATTGTGACATGTCCGATGGAGGAGGATGGACT

GTAATTCAGAGACGATCTGATGGCAGTGAAAACTTTAACAGAGGATGGAAAGACTAT

GAAAATGGCTTTGGAAATTTTGTCCAAAAACATGGTGAATATTGGCTGGGCAATAAA

AATCTTCACTTCTTGACCACTCAAGAAGACTACACTTTAAAAATCGACCTTGCAGAT

TTTGAAAAAAATAGCCGTTATGCACAATATAAGAATTTCAAAGTTGGAGATGAAAAG

AATTTCTACGAGTTGAATATTGGGGAATATTCTGGAACAGCTGGAGATTCCCTTGCG

GGGAATTTTCATCCTGAGGTGCAGTGGTGGGCTAGTCACCAAAGAATGAAATTCAGC

ACGTGGGACAGAGATCATGACAACTATGAAGGGAACTGCGCAGAAGAAGATCAGTCT

GGCTGGTGGTTTAACAGGTGTCACTCTGCAAACCTGAATGGTGTATACTACAGCGGC

CCCTACACGGCTAAAACAGACAATGGGATTGTCTGGTACACCTGGCATGGGTGGTGG

TATTCTCTGAAATCTGTGGTTATGAAAATTAGGCCAAATGATTTTATTCCAAATGTA

ATT
CCAAATAAAGGAAGTGGAACCACTTCAGGTACTACCCGTCTTCTATCTGGGCAC

ACGTGTTTCACGTTGACAGGTTTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACT

TAG

(SEQ ID NO: 239)

>Artificial Sequence; hPDL1-GPI-P2A-hFGL1-GPI, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLENVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNER
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLTGS
GATNESLL

KQAGDVEENPGP
MAKVFSFILVTTALTMGREISALEDCAQEQMRLRAQVRLLETRVK

QQQVKIKQLLQENEVQFLDKGDENTVIDLGSKRQYADCSEIFNDGYKLSGFYKIKPL

QSPAEFSVYCDMSDGGGWTVIQRRSDGSENFNRGWKDYENGFGNFVQKHGEYWLGNK

NLHFLTTQEDYTLKIDLADFEKNSRYAQYKNFKVGDEKNFYELNIGEYSGTAGDSLA

GNFHPEVQWWASHQRMKFSTWDRDHDNYEGNCAEEDQSGWWFNRCHSANLNGVYYSG

PYTAKTDNGIVWYTWHGWWYSLKSVVMKIRPNDFIPNVI
PNKGSGTTSGTTRLLSGH

TCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 240)

Myr-mScarlet
>Artificial Sequence; Myr-mScarlet, DNA

ATGGGTTGCTGTTTCTCCAAGACC
GGCTCGAGCGGCGTGAGCAAGGGCGAGGCAGTG

ATCAAGGAGTTCATGCGGTTCAAGGTGCACATGGAGGGCTCCATGAACGGCCACGAG

TTCGAGATCGAGGGCGAGGGCGAGGGCCGCCCCTACGAGGGCACCCAGACCGCCAAG

CTGAAGGTGACCAAGGGTGGCCCCCTGCCCTTCTCCTGGGACATCCTGTCCCCTCAG

TTCATGTACGGCTCCAGGGCCTTCACCAAGCACCCCGCCGACATCCCCGACTACTAT

AAGCAGTCCTTCCCCGAGGGCTTCAAGTGGGAGCGCGTGATGAACTTCGAGGACGGC

GGCGCCGTGACCGTGACCCAGGACACCTCCCTGGAGGACGGCACCCTGATCTACAAG

GTGAAGCTCCGCGGCACCAACTTCCCTCCTGACGGCCCCGTAATGCAGAAGAAGACA

ATGGGCTGGGAAGCGTCCACCGAGCGGTTGTACCCCGAGGACGGCGTGCTGAAGGGC

GACATTAAGATGGCCCTGCGCCTGAAGGACGGCGGCCGCTACCTGGCGGACTTCAAG

ACCACCTACAAGGCCAAGAAGCCCGTGCAGATGCCCGGCGCCTACAACGTCGACCGC

AAGTTGGACATCACCTCCCACAACGAGGACTACACCGTGGTGGAACAGTACGAACGC

TCCGAGGGCCGCCACTCCACCGGCGGCATGGACGAGCTGTACAAG

(SEQ ID NO: 241)

>Artificial Sequence; Myr-mScarlet, Amino Acid

MGCCFSKT
GSSGVSKGEAVIKEFMRFKVHMEGSMNGHEFEIEGEGEGRPYEGTQTAK

LKVTKGGPLPFSWDILSPQFMYGSRAFTKHPADIPDYYKQSFPEGFKWERVMNFEDG

GAVTVTQDTSLEDGTLIYKVKLRGTNFPPDGPVMQKKTMGWEASTERLYPEDGVLKG

DIKMALRLKDGGRYLADFKTTYKAKKPVQMPGAYNVDRKLDITSHNEDYTVVEQYER

SEGRHSTGGMDELYK

(SEQ ID NO: 242)

Myr-NanoLuc
>Artificial Sequence; Myr-NanoLuc, DNA

Luciferase

ATGGGTTGCTGTTTCTCCAAGACC
GGCTCGAGCGGCGTCTTCACACTCGAAGATTTC

GTTGGGGACTGGCGACAGACAGCCGGCTACAACCTGGACCAAGTCCTTGAACAGGGA

GGTGTGTCCAGTTTGTTTCAGAATCTCGGGGTGTCCGTAACTCCGATCCAAAGGATT

GTCCTGAGCGGTGAAAATGGGCTGAAGATCGACATCCATGTCATCATCCCGTATGAA

GGTCTGAGCGGCGACCAAATGGGCCAGATCGAAAAAATTTTTAAGGTGGTGTACCCT

GTGGATGATCATCACTTTAAGGTGATCCTGCACTATGGCACACTGGTAATCGACGGG

GTTACGCCGAACATGATCGACTATTTCGGACGGCCGTATGAAGGCATCGCCGTGTTC

GACGGCAAAAAGATCACTGTAACAGGGACCCTGTGGAACGGCAACAAAATTATCGAC

GAGCGCCTGATCAACCCCGACGGCTCCCTGCTGTTCCGAGTAACCATCAACGGAGTG

ACCGGCTGGCGGCTGTGCGAACGCATTCTGGCGTAA

(SEQ ID NO: 243)

>Artificial Sequence; Myr-NanoLuc, Amino Acid

MGCCFSKT
GSSGVFTLEDFVGDWRQTAGYNLDQVLEQGGVSSLFQNLGVSVTPIQRI

VLSGENGLKIDIHVIIPYEGLSGDQMGQIEKIFKVVYPVDDHHFKVILHYGTLVIDG

VTPNMIDYFGRPYEGIAVEDGKKITVTGTLWNGNKIIDERLINPDGSLLERVTINGV

TGWRLCERILA

(SEQ ID NO: 244)

hSecPDL1-GPI
>Artificial Sequence; hSecPDL1-GPI, DNA

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGGT

AATATTCTGAATGTGTCCATTAAAATATGTCTAACACTGTCCCCTAGCACC
CCAAAT

AAAGGAAGTGGAACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTC

ACGTTGACAGGTTTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 245)

>Artificial Sequence; hSecPDL1-GPI, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLENVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPG

NILNVSIKICLTLSPST
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 246)

Tfr2-h41BBL
>Artificial Sequence; Tfr2-h41BBL, DNA

ATGGAGCGGCTTTGGGGTCTATTCCAGAGAGCGCAACAACTGTCCCCAAGATCCTCT

CAGACCGTCTACCAGCGTGTGGAAGGCCCCCGGAAAGGGCACCTGGAGGAGGAAGAG

GAAGACGGGGAGGAGGGGGCGGAGACATTGGCCCACTTCTGCCCCATGGAGCTGAGG

GGCCCTGAGCCCCTGGGCTCTAGACCCAGGCAGCCAAACCTCATTCCCTGGGCGGCA

GCAGGACGGAGGGCTGCCCCCTACCTGGTCCTGACGGCCCTGCTGATCTTCACTGGG

GCCTTCCTACTGGGCTACGTCGCCTTCCGAGGGTCC

GCCTGCCCCTGGGCCGTGTCC

GGGGCTCGCGCCTCGCCCGGCTCCGCGGCCAGCCCGAGACTCCGCGAGGGTCCCGAG

CTTTCGCCCGACGATCCCGCCGGCCTCTTGGACCTGCGGCAGGGCATGTTTGCGCAG

CTGGTGGCCCAAAATGTTCTGCTGATCGATGGGCCCCTGAGCTGGTACAGTGACCCA

GGCCTGGCAGGCGTGTCCCTGACGGGGGGCCTGAGCTACAAAGAGGACACGAAGGAG

CTGGTGGTGGCCAAGGCTGGAGTCTACTATGTCTTCTTTCAACTAGAGCTGCGGCGC

GTGGTGGCCGGCGAGGGCTCAGGCTCCGTTTCACTTGCGCTGCACCTGCAGCCACTG

CGCTCTGCTGCTGGGGCCGCCGCCCTGGCTTTGACCGTGGACCTGCCACCCGCCTCC

TCCGAGGCTCGGAACTCGGCCTTCGGTTTCCAGGGCCGCTTGCTGCACCTGAGTGCC

GGCCAGCGCCTGGGCGTCCATCTTCACACTGAGGCCAGGGCACGCCATGCCTGGCAG

CTTACCCAGGGCGCCACAGTCTTGGGACTCTTCCGGGTGACCCCCGAAATCCCAGCC

GGACTCCCTTCACCGAGGTCGGAATAA

(SEQ ID NO: 247)

>Artificial Sequence; Tfr2-h41BBL, Amino Acid

MERLWGLFQRAQQLSPRSSQTVYQRVEGPRKGHLEEEEEDGEEGAETLAHFCPMELR

GPEPLGSRPRQPNLIPWAAAGRRAAPYLVLTALLIFTGAFLLGYVAFRGS
ACPWAVS

GARASPGSAASPRLRGPELSPDDPAGLLDLRQGMFAQLVAQNVLLIDGPLSWYSDPG

LAGVSLTGGLSYKEDTKELVVAKAGVYYVFFQLELRRVVAGEGSGSVSLALHLQPLR

SAAGAAALALTVDLPPASSEARNSAFGFQGRLLHLSAGQRLGVHLHTEARARHAWQL

TQGATVLGLFRVTPEIPAGLPSPRSE

(SEQ ID NO: 248)

CD9tm3-h41BBL
>Artificial Sequence; CD9tm3-h41BBL, DNA

ATGGGCTGCTGCGGGGCTGTGCAGGAGTCCCAGTGCATGCTGGGACTGTTCTTCGGC

TTCCTCTTGGTGATATTCGCCATTGAAATAGCTGCGGCCATCTGGGGATATTCCCAC

AAGGATGAG
GCCTGCCCCTGGGCCGTGTCCGGGGCTCGCGCCTCGCCCGGCTCCGCG

GCCAGCCCGAGACTCCGCGAGGGTCCCGAGCTTTCGCCCGACGATCCCGCCGGCCTC

TTGGACCTGCGGCAGGGCATGTTTGCGCAGCTGGTGGCCCAAAATGTTCTGCTGATC

GATGGGCCCCTGAGCTGGTACAGTGACCCAGGCCTGGCAGGCGTGTCCCTGACGGGG

GGCCTGAGCTACAAAGAGGACACGAAGGAGCTGGTGGTGGCCAAGGCTGGAGTCTAC

TATGTCTTCTTTCAACTAGAGCTGCGGCGCGTGGTGGCCGGCGAGGGCTCAGGCTCC

GTTTCACTTGCGCTGCACCTGCAGCCACTGCGCTCTGCTGCTGGGGCCGCCGCCCTG

GCTTTGACCGTGGACCTGCCACCCGCCTCCTCCGAGGCTCGGAACTCGGCCTTCGGT

TTCCAGGGCCGCTTGCTGCACCTGAGTGCCGGCCAGCGCCTGGGCGTCCATCTTCAC

ACTGAGGCCAGGGCACGCCATGCCTGGCAGCTTACCCAGGGCGCCACAGTCTTGGGA

CTCTTCCGGGTGACCCCCGAAATCCCAGCCGGACTCCCTTCACCGAGGTCGGAATAA

(SEQ ID NO: 249)

>Artificial Sequence; CD9tm3-h41BBL, Amino Acid

MGCCGAVQESQCMLGLFFGELLVIFAIEIAAAIWGYSHKDE
ACPWAVSGARASPGSA

ASPRLREGPELSPDDPAGLLDLRQGMFAQLVAQNVLLIDGPLSWYSDPGLAGVSLTG

GLSYKEDTKELVVAKAGVYYVFFQLELRRVVAGEGSGSVSLALHLQPLRSAAGAAAL

ALTVDLPPASSEARNSAFGFQGRLLHLSAGQRLGVHLHTEARARHAWQLTQGATVLG

LFRVTPEIPAGLPSPRSE

(SEQ ID NO: 250)

Myr/Palm-4F2-
>Artificial Sequence; Myr/Palm-4F2-h41BBL, DNA

h41BBL

ATGGGTTGCTGTTTCTCCAAGACC

GGCTCGAGCGGCAGCCAGGACACCGAGGTGGAT

ATGAAGGAGGTGGAGCTGAATGAGTTAGAGCCCGAGAAGCAGCCGATGAACGCGGCG

TCTGGGGCGGCCATGTCCCTGGCGGGAGCCGAGAAGAATGGTCTGGTGAAGATCAAG

GTGGCGGAAGACGAGGCGGAGGCGGCAGCCGCGGCTAAGTTCACGGGCCTGTCCAAG

GAGGAGCTGCTGAAGGTGGCAGGCAGCCCCGGCTGGGTACGCACCCGCTGGGCACTG

CTGCTGCTCTTCTGGCTCGGCTGGCTCGGCATGCTTGCTGGTGCCGTGGTCATAATC

GTG
GCCTGCCCCTGGGCCGTGTCCGGGGCTCGCGCCTCGCCCGGCTCCGCGGCCAGC

CCGAGACTCCGCGAGGGTCCCGAGCTTTCGCCCGACGATCCCGCCGGCCTCTTGGAC

CTGCGGCAGGGCATGTTTGCGCAGCTGGTGGCCCAAAATGTTCTGCTGATCGATGGG

CCCCTGAGCTGGTACAGTGACCCAGGCCTGGCAGGCGTGTCCCTGACGGGGGGCCTG

AGCTACAAAGAGGACACGAAGGAGCTGGTGGTGGCCAAGGCTGGAGTCTACTATGTC

TTCTTTCAACTAGAGCTGCGGCGCGTGGTGGCCGGCGAGGGCTCAGGCTCCGTTTCA

CTTGCGCTGCACCTGCAGCCACTGCGCTCTGCTGCTGGGGCCGCCGCCCTGGCTTTG

ACCGTGGACCTGCCACCCGCCTCCTCCGAGGCTCGGAACTCGGCCTTCGGTTTCCAG

GGCCGCTTGCTGCACCTGAGTGCCGGCCAGCGCCTGGGCGTCCATCTTCACACTGAG

GCCAGGGCACGCCATGCCTGGCAGCTTACCCAGGGCGCCACAGTCTTGGGACTCTTC

CGGGTGACCCCCGAAATCCCAGCCGGACTCCCTTCACCGAGGTCGGAATAA

(SEQ ID NO: 251)

>Artificial Sequence; Myr/Palm-4F2-h41BBL, Amino Acid

MGCCFSKTGSSGSQDTEVDMKEVELNELEPEKQPMNAASGAAMSLAGAEKNGLVKIK

VAEDEAEAAAAAKFTGLSKEELLKVAGSPGWVRTRWALLLLFWLGWLGMLAGAVVII

V
ACPWAVSGARASPGSAASPRLREGPELSPDDPAGLLDLRQGMFAQLVAQNVLLIDG

PLSWYSDPGLAGVSLTGGLSYKEDTKELVVAKAGVYYVFFQLELRRVVAGEGSGSVS

LALHLQPLRSAAGAAALALTVDLPPASSEARNSAFGFQGRLLHLSAGQRLGVHLHTE

ARARHAWQLTQGATVLGLFRVTPEIPAGLPSPRSE

(SEQ ID NO: 252)

Myr/Palm-Link-
>Artificial Sequence; Myr/Palm-Link-41BBL, DNA

41BBL (41BBL

ATGGGTTGCTGTTTCTCCAAGACC
GGCTCGAGCGGCTGGGCCCTGGTCGCGGGGCTG

transmembrane

CTGCTGCTGCTGCTGCTCGCTGCCGCCTGCGCCGTCTTCCTCGCCTGCCCCTGGGCC

domain

GTGTCCGGGGCTCGCGCCTCGCCCGGCTCCGCGGCCAGCCCGAGACTCCGCGAGGGT

included)

CCCGAGCTTTCGCCCGACGATCCCGCCGGCCTCTTGGACCTGCGGCAGGGCATGTTT

GCGCAGCTGGTGGCCCAAAATGTTCTGCTGATCGATGGGCCCCTGAGCTGGTACAGT

GACCCAGGCCTGGCAGGCGTGTCCCTGACGGGGGGCCTGAGCTACAAAGAGGACACG

AAGGAGCTGGTGGTGGCCAAGGCTGGAGTCTACTATGTCTTCTTTCAACTAGAGCTG

CGGCGCGTGGTGGCCGGCGAGGGCTCAGGCTCCGTTTCACTTGCGCTGCACCTGCAG

CCACTGCGCTCTGCTGCTGGGGCCGCCGCCCTGGCTTTGACCGTGGACCTGCCACCC

GCCTCCTCCGAGGCTCGGAACTCGGCCTTCGGTTTCCAGGGCCGCTTGCTGCACCTG

AGTGCCGGCCAGCGCCTGGGCGTCCATCTTCACACTGAGGCCAGGGCACGCCATGCC

TGGCAGCTTACCCAGGGCGCCACAGTCTTGGGACTCTTCCGGGTGACCCCCGAAATC

CCAGCCGGACTCCCTTCACCGAGGTCGGAATAA

(SEQ ID NO: 253)

>Artificial Sequence; Myr/Palm-Link-41BBL, Amino Acid

MGCCFSKT
GSSGWALVAGLLLLLLLAAACAVFLACPWAVSGARASPGSAASPRLREG

PELSPDDPAGLLDLRQGMFAQLVAQNVLLIDGPLSWYSDPGLAGVSLTGGLSYKEDT

KELVVAKAGVYYVFFQLELRRVVAGEGSGSVSLALHLQPLRSAAGAAALALTVDLPP

ASSEARNSAFGFQGRLLHLSAGQRLGVHLHTEARARHAWQLTQGATVLGLFRVTPEI

PAGLPSPRSE

(SEQ ID NO: 254)

hPDL1-Link-GPI
>Artificial Sequence; hPDL1-Link-GPI, DNA

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTG
GGCTCGAGCGGC

CCAAATAAAGGAAGTGGAACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACG

TGTTTCACGTTGACAGGTTTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 255)

>Artificial Sequence; hPDL1-Link-GPI, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELG
SSG

PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 256)

hSecPDL1-
>Artificial Sequence; hSecPDL1-CD9tm2, DNA

CD9tm2

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGGT

AATATTCTGAATGTGTCCATTAAAATATGTCTAACACTGTCCCCTAGCACC
TTCTAC

ACAGGAGTCTATATTCTGATCGGAGCCGGCGCCCTCATGATGCTGGTGGGCTTCCTG

GGCTGCTGCGGGGCTGTGCAGGAGTCCCAGTGCTAG

(SEQ ID NO: 257)

>Artificial Sequence; hSecPDL1-CD9tm2, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPG

NILNVSIKICLTLSPST
FYTGVYILIGAGALMMLVGFLGCCGAVQESQC

(SEQ ID NO: 258)

hSecPDL1-
>Artificial Sequence; hSecPDL1-CD9tm2-KRAS, DNA

CD9tm2-

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

modified KRAS

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGGT

AATATTCTGAATGTGTCCATTAAAATATGTCTAACACTGTCCCCTAGCACC
TTCTAC

ACAGGAGTCTATATTCTGATCGGAGCCGGCGCCCTCATGATGCTGGTGGGCTTCCTG

GGCTGCTGCGGGGCTGTGCAGGAGTCCCAGTGC

AAAAAGAAGAAAAAGAAGTCAAAG

ACAAAGTGTGTAATTATGTAA

(SEQ ID NO: 259)

>Artificial Sequence; hSecPDL1-CD9tm2-KRAS, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPG

NILNVSIKICLTLSPST
FYTGVYILIGAGALMMLVGELGCCGAVQESQC

KKKKKKSK

TKCVIM

(SEQ ID NO: 260)

hSecPDL1-
>Artificial Sequence; hSecPDL1-CD9tm4, DNA

CD9tm4

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGGT

AATATTCTGAATGTGTCCATTAAAATATGTCTAACACTGTCCCCTAGCACC
ATCGGC

GCAGTGGGCATCGGCATTGCCGTGGTCATGATATTTGGCATGATCTTCAGTATGATC

TTGTGCTGTGCTATCCGCAGGAACCGCGAGATGGTCTAG

(SEQ ID NO: 261)

>Artificial Sequence; hSecPDL1-CD9tm4, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPG

NILNVSIKICLTLSPST
IGAVGIGIAVVMIFGMIFSMILCCAIRRNREMV

(SEQ ID NO: 262)

hSecPDL1-CD81
>Artificial Sequence; hSecPDL1-CD81, DNA

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGGT

AATATTCTGAATGTGTCCATTAAAATATGTCTAACACTGTCCCCTAGCACC
CTGTAC

CTCATCGGCATTGCTGCCATCGTGGTCGCTGTGATCATGATCTTCGAGATGATCCTG

AGCATGGTGCTGTGCTGTGGCATCCGGAACAGCTCCGTGTACTGA

(SEQ ID NO: 263)

>Artificial Sequence; hSecPDL1-CD81, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPG

NILNVSIKICLTLSPST
LYLIGIAAIVVAVIMIFEMILSMVLCCGIRNSSVY

(SEQ ID NO: 264)

hCD200-Fc-GPI
>Artificial Sequence; hCD200-Fc-GPI, DNA

ATGGAGAGGCTGGTGATCAGGATGCCCTTCTCTCATCTGTCTACCTACAGCCTGGTT

TGGGTCATGGCAGCAGTGGTGCTGTGCACAGCACAAGTGCAAGTGGTGACCCAGGAT

GAAAGAGAGCAGCTGTACACACCTGCTTCCTTAAAATGCTCTCTGCAAAATGCCCAG

GAAGCCCTCATTGTGACATGGCAGAAAAAGAAAGCTGTAAGCCCAGAAAACATGGTC

ACCTTCAGCGAGAACCATGGGGTGGTGATCCAGCCTGCCTATAAGGACAAGATAAAC

ATTACCCAGCTGGGACTCCAAAACTCAACCATCACCTTCTGGAATATCACCCTGGAG

GATGAAGGGTGTTACATGTGTCTCTTCAATACCTTTGGTTTTGGGAAGATCTCAGGA

ACGGCCTGCCTCACCGTCTATGTACAGCCCATAGTATCCCTTCACTACAAATTCTCT

GAAGACCACCTAAATATCACTTGCTCTGCCACTGCCCGCCCAGCCCCCATGGTCTTC

TGGAAGGTCCCTCGGTCAGGGATTGAAAATAGTACAGTGACTCTGTCTCACCCAAAT

GGGACCACGTCTGTTACCAGCATCCTCCATATCAAAGACCCTAAGAATCAGGTGGGG

AAGGAGGTGATCTGCCAGGTGCTGCACCTGGGGACTGTGACCGACTTTAAGCAAACC

GTCAACAAAGGCATCGATGACAAAACTCACACATGCCCACCGTGCCCAGCACCTGAA

CTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCAAAACCCAAGGACACCCTCATG

ATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTGGACGTGAGCCACGAAGACCCT

GAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAGGTGCATAATGCCAAGACAAAG

CCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTGGTCAGCGTCCTCACCGTCCTG

CACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGCAAGGTCTCCAACAAAGCCCTC

CCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAAGGGCAGCCCCGAGAACCACAG

GTGTACACCCTGCCCCCATCCCGGGAGGAGATGACCAAGAACCAGGTCAGCCTGACC

TGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCCGTGGAGTGGGAGAGCAATGGG

CAGCCGGAGAACAACTACAAGACCACGCCTCCCGTGCTGGACTCCGACGGCTCCTTC

TTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGGCAGCAGGGGAACGTCTTC

TCATGCTCCGTGATGCACGAGGCTCTGCACAACCACTACACGCAGAAGAGCCTCTCC

CTGTCTCCGGGTAAAATCGATCCAAATAAAGGAAGTGGAACCACTTCAGGTACTACC

CGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGGACGCTAGTA

ACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 265)

>Artificial Sequence; hCD200-Fc-GPI, Amino Acid

MERLVIRMPFSHLSTYSLVWVMAAVVLCTAQVQVVTQDEREQLYTPASLKCSLQNAQ

EALIVTWQKKKAVSPENMVTFSENHGVVIQPAYKDKINITQLGLQNSTITFWNITLE

DEGCYMCLFNTFGFGKISGTACLTVYVQPIVSLHYKFSEDHLNITCSATARPAPMVF

WKVPRSGIENSTVTLSHPNGTTSVTSILHIKDPKNQVGKEVICQVLHLGTVTDFKQT

VNKGIDDKTHTCPPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVDVSHEDP

EVKFNWYVDGVEVHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCKVSNKAL

PAPIEKTISKAKGQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAVEWESNG

QPENNYKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHYTQKSLS

LSPGKIDPNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 266)

hFGL1-GPI
>Artificial Sequence; hFGL1-GPI, DNA

ATGGCAAAGGTGTTCAGTTTCATCCTTGTTACCACCGCTCTGACAATGGGCAGGGAA

ATTTCGGCGCTCGAGGACTGTGCCCAGGAGCAGATGCGGCTCAGAGCCCAGGTGCGC

CTGCTTGAGACCCGGGTCAAACAGCAACAGGTCAAGATCAAGCAGCTTTTGCAGGAG

AATGAAGTCCAGTTCCTTGATAAAGGAGATGAGAATACTGTCATTGATCTTGGAAGC

AAGAGGCAGTATGCAGATTGTTCAGAGATTTTCAATGATGGGTATAAGCTCAGTGGA

TTTTACAAAATCAAACCTCTCCAGAGCCCAGCAGAATTTTCTGTTTATTGTGACATG

TCCGATGGAGGAGGATGGACTGTAATTCAGAGACGATCTGATGGCAGTGAAAACTTT

AACAGAGGATGGAAAGACTATGAAAATGGCTTTGGAAATTTTGTCCAAAAACATGGT

GAATATTGGCTGGGCAATAAAAATCTTCACTTCTTGACCACTCAAGAAGACTACACT

TTAAAAATCGACCTTGCAGATTTTGAAAAAAATAGCCGTTATGCACAATATAAGAAT

TTCAAAGTTGGAGATGAAAAGAATTTCTACGAGTTGAATATTGGGGAATATTCTGGA

ACAGCTGGAGATTCCCTTGCGGGGAATTTTCATCCTGAGGTGCAGTGGTGGGCTAGT

CACCAAAGAATGAAATTCAGCACGTGGGACAGAGATCATGACAACTATGAAGGGAAC

TGCGCAGAAGAAGATCAGTCTGGCTGGTGGTTTAACAGGTGTCACTCTGCAAACCTG

AATGGTGTATACTACAGCGGCCCCTACACGGCTAAAACAGACAATGGGATTGTCTGG

TACACCTGGCATGGGTGGTGGTATTCTCTGAAATCTGTGGTTATGAAAATTAGGCCA

AATGATTTTATTCCAAATGTAATT
CCAAATAAAGGAAGTGGAACCACTTCAGGTACT

ACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGGACGCTA

GTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 267)

>Artificial Sequence; hFGL1-GPI, Amino Acid

MAKVFSFILVTTALTMGREISALEDCAQEQMRLRAQVRLLETRVKQQQVKIKQLLQE

NEVQFLDKGDENTVIDLGSKRQYADCSEIFNDGYKLSGFYKIKPLQSPAEFSVYCDM

SDGGGWTVIQRRSDGSENFNRGWKDYENGFGNFVQKHGEYWLGNKNLHFLTTQEDYT

LKIDLADFEKNSRYAQYKNFKVGDEKNFYELNIGEYSGTAGDSLAGNFHPEVQWWAS

HQRMKFSTWDRDHDNYEGNCAEEDQSGWWFNRCHSANLNGVYYSGPYTAKTDNGIVW

YTWHGWWYSLKSVVMKIRPNDFIPNVIPNKGSGTTSGTTRLLSGHTCFTLTGLLGTL

VTMGLLT

(SEQ ID NO: 268)

hGa19-Fc-GPI
>Artificial Sequence; hGal9-Fc-GPI, DNA

ATGGCCTTCAGCGGTTCCCAGGCTCCCTACCTGAGTCCAGCTGTCCCCTTTTCTGGG

ACTATTCAAGGAGGTCTCCAGGACGGACTTCAGATCACTGTCAATGGGACCGTTCTC

AGCTCCAGTGGAACCAGGTTTGCTGTGAACTTTCAGACTGGCTTCAGTGGAAATGAC

ATTGCCTTCCACTTCAACCCTCGGTTTGAAGATGGAGGGTACGTGGTGTGCAACACG

AGGCAGAACGGAAGCTGGGGGCCCGAGGAGAGGAAGACACACATGCCTTTCCAGAAG

GGGATGCCCTTTGACCTCTGCTTCCTGGTGCAGAGCTCAGATTTCAAGGTGATGGTG

AACGGGATCCTCTTCGTGCAGTACTTCCACCGCGTGCCCTTCCACCGTGTGGACACC

ATCTCCGTCAATGGCTCTGTGCAGCTGTCCTACATCAGCTTCCAGAACCCCCGCACA

GTCCCTGTTCAGCCTGCCTTCTCCACGGTGCCGTTCTCCCAGCCTGTCTGTTTCCCA

CCCAGGCCCAGGGGGCGCAGACAAAAACCTCCCGGCGTGTGGCCTGCCAACCCGGCT

CCCATTACCCAGACAGTCATCCACACAGTGCAGAGCGCCCCTGGACAGATGTTCTCT

ACTCCCGCCATCCCACCTATGATGTACCCCCACCCCGCCTATCCGATGCCTTTCATC

ACCACCATTCTGGGAGGGCTGTACCCATCCAAGTCCATCCTCCTGTCAGGCACTGTC

CTGCCCAGTGCTCAGAGGTTCCACATCAACCTGTGCTCTGGGAACCACATCGCCTTC

CACCTGAACCCCCGTTTTGATGAGAATGCTGTGGTCCGCAACACCCAGATCGACAAC

TCCTGGGGGTCTGAGGAGCGAAGTCTGCCCCGAAAAATGCCCTTCGTCCGTGGCCAG

AGCTTCTCAGTGTGGATCTTGTGTGAAGCTCACTGCCTCAAGGTGGCCGTGGATGGT

CAGCACCTGTTTGAATACTACCATCGCCTGAGGAACCTGCCCACCATCAACAGACTG

GAAGTGGGGGGCGACATCCAGCTGACCCATGTGCAGACAATCGATGACAAAACTCAC

ACATGCCCACCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTC

CCCCCAAAACCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTG

GTGGTGGACGTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGC

GTGGAGGTGCATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTAC

CGTGTGGTCAGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTAC

AAGTGCAAGGTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAA

GCCAAAGGGCAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAG

ATGACCAAGAACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGAC

ATCGCCGTGGAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCT

CCCGTGCTGGACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAG

AGCAGGTGGCAGCAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCAC

AACCACTACACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATCCAAATAAA

GGAAGTGGAACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACG

TTGACAGGTTTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 269)

>Artificial Sequence; hGal9-Fc-GPI, Amino Acid

MAFSGSQAPYLSPAVPFSGTIQGGLQDGLQITVNGTVLSSSGTRFAVNFQTGFSGND

IAFHFNPRFEDGGYVVCNTRQNGSWGPEERKTHMPFQKGMPFDLCFLVQSSDFKVMV

NGILFVQYFHRVPFHRVDTISVNGSVQLSYISFQNPRTVPVQPAFSTVPFSQPVCFP

PRPRGRRQKPPGVWPANPAPITQTVIHTVQSAPGQMFSTPAIPPMMYPHPAYPMPFI

TTILGGLYPSKSILLSGTVLPSAQRFHINLCSGNHIAFHLNPRFDENAVVRNTQIDN

SWGSEERSLPRKMPFVRGQSFSVWILCEAHCLKVAVDGQHLFEYYHRLRNLPTINRL

EVGGDIQLTHVQTIDDKTHTCPPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCV

VVDVSHEDPEVKENWYVDGVEVHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEY

KCKVSNKALPAPIEKTISKAKGQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSD

IAVEWESNGQPENNYKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALH

NHYTQKSLSLSPGKIDPNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 270)

hCD200-GPI
>Artificial Sequence; hCD200-GPI, DNA

ATGGAGAGGCTGGTGATCAGGATGCCCTTCTCTCATCTGTCTACCTACAGCCTGGTT

TGGGTCATGGCAGCAGTGGTGCTGTGCACAGCACAAGTGCAAGTGGTGACCCAGGAT

GAAAGAGAGCAGCTGTACACACCTGCTTCCTTAAAATGCTCTCTGCAAAATGCCCAG

GAAGCCCTCATTGTGACATGGCAGAAAAAGAAAGCTGTAAGCCCAGAAAACATGGTC

ACCTTCAGCGAGAACCATGGGGTGGTGATCCAGCCTGCCTATAAGGACAAGATAAAC

ATTACCCAGCTGGGACTCCAAAACTCAACCATCACCTTCTGGAATATCACCCTGGAG

GATGAAGGGTGTTACATGTGTCTCTTCAATACCTTTGGTTTTGGGAAGATCTCAGGA

ACGGCCTGCCTCACCGTCTATGTACAGCCCATAGTATCCCTTCACTACAAATTCTCT

GAAGACCACCTAAATATCACTTGCTCTGCCACTGCCCGCCCAGCCCCCATGGTCTTC

TGGAAGGTCCCTCGGTCAGGGATTGAAAATAGTACAGTGACTCTGTCTCACCCAAAT

GGGACCACGTCTGTTACCAGCATCCTCCATATCAAAGACCCTAAGAATCAGGTGGGG

AAGGAGGTGATCTGCCAGGTGCTGCACCTGGGGACTGTGACCGACTTTAAGCAAACC

GTCAACAAAGGC
CCAAATAAAGGAAGTGGAACCACTTCAGGTACTACCCGTCTTCTA

TCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGGACGCTAGTAACCATGGGC

TTGCTGACTTAG

(SEQ ID NO: 271)

>Artificial Sequence; hCD200-GPI, Amino Acid

MERLVIRMPFSHLSTYSLVWVMAAVVLCTAQVQVVTQDEREQLYTPASLKCSLQNAQ

EALIVTWQKKKAVSPENMVTFSENHGVVIQPAYKDKINITQLGLQNSTITEWNITLE

DEGCYMCLFNTFGFGKISGTACLTVYVQPIVSLHYKFSEDHLNITCSATARPAPMVF

WKVPRSGIENSTVTLSHPNGTTSVTSILHIKDPKNQVGKEVICQVLHLGTVTDFKQT

VNKG
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 272)

hGal9-GPI
>Artificial Sequence; hGal9-GPI, DNA

ATGGCCTTCAGCGGTTCCCAGGCTCCCTACCTGAGTCCAGCTGTCCCCTTTTCTGGG

ACTATTCAAGGAGGTCTCCAGGACGGACTTCAGATCACTGTCAATGGGACCGTTCTC

AGCTCCAGTGGAACCAGGTTTGCTGTGAACTTTCAGACTGGCTTCAGTGGAAATGAC

ATTGCCTTCCACTTCAACCCTCGGTTTGAAGATGGAGGGTACGTGGTGTGCAACACG

AGGCAGAACGGAAGCTGGGGGCCCGAGGAGAGGAAGACACACATGCCTTTCCAGAAG

GGGATGCCCTTTGACCTCTGCTTCCTGGTGCAGAGCTCAGATTTCAAGGTGATGGTG

AACGGGATCCTCTTCGTGCAGTACTTCCACCGCGTGCCCTTCCACCGTGTGGACACC

ATCTCCGTCAATGGCTCTGTGCAGCTGTCCTACATCAGCTTCCAGAACCCCCGCACA

GTCCCTGTTCAGCCTGCCTTCTCCACGGTGCCGTTCTCCCAGCCTGTCTGTTTCCCA

CCCAGGCCCAGGGGGCGCAGACAAAAACCTCCCGGCGTGTGGCCTGCCAACCCGGCT

CCCATTACCCAGACAGTCATCCACACAGTGCAGAGCGCCCCTGGACAGATGTTCTCT

ACTCCCGCCATCCCACCTATGATGTACCCCCACCCCGCCTATCCGATGCCTTTCATC

ACCACCATTCTGGGAGGGCTGTACCCATCCAAGTCCATCCTCCTGTCAGGCACTGTC

CTGCCCAGTGCTCAGAGGTTCCACATCAACCTGTGCTCTGGGAACCACATCGCCTTC

CACCTGAACCCCCGTTTTGATGAGAATGCTGTGGTCCGCAACACCCAGATCGACAAC

TCCTGGGGGTCTGAGGAGCGAAGTCTGCCCCGAAAAATGCCCTTCGTCCGTGGCCAG

AGCTTCTCAGTGTGGATCTTGTGTGAAGCTCACTGCCTCAAGGTGGCCGTGGATGGT

CAGCACCTGTTTGAATACTACCATCGCCTGAGGAACCTGCCCACCATCAACAGACTG

GAAGTGGGGGGCGACATCCAGCTGACCCATGTGCAGACA
CCAAATAAAGGAAGTGGA

ACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGT

TTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 273)

>Artificial Sequence; hGal9-GPI, Amino Acid

MAFSGSQAPYLSPAVPFSGTIQGGLQDGLQITVNGTVLSSSGTRFAVNFQTGFSGND

IAFHFNPRFEDGGYVVCNTRQNGSWGPEERKTHMPFQKGMPFDLCFLVQSSDFKVMV

NGILFVQYFHRVPFHRVDTISVNGSVQLSYISFQNPRTVPVQPAFSTVPFSQPVCFP

PRPRGRRQKPPGVWPANPAPITQTVIHTVQSAPGQMFSTPAIPPMMYPHPAYPMPFI

TTILGGLYPSKSILLSGTVLPSAQRFHINLCSGNHIAFHLNPRFDENAVVRNTQIDN

SWGSEERSLPRKMPFVRGQSFSVWILCEAHCLKVAVDGQHLFEYYHRLRNLPTINRL

EVGGDIQLTHVQT
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 274)

hHVEM-GPI
>Artificial Sequence; hHVEM-GPI, DNA

ATGGAGCCTCCTGGAGACTGGGGGCCTCCTCCCTGGAGATCCACCCCCAAAACCGAC

GTCTTGAGGCTGGTGCTGTATCTCACCTTCCTGGGAGCCCCCTGCTACGCCCCAGCT

CTGCCGTCCTGCAAGGAGGACGAGTACCCAGTGGGCTCCGAGTGCTGCCCCAAGTGC

AGTCCAGGTTATCGTGTGAAGGAGGCCTGCGGGGAGCTGACGGGCACAGTGTGTGAA

CCCTGCCCTCCAGGCACCTACATTGCCCACCTCAATGGCCTAAGCAAGTGTCTGCAG

TGCCAAATGTGTGACCCAGCCATGGGCCTGCGCGCGAGCCGGAACTGCTCCAGGACA

GAGAACGCCGTGTGTGGCTGCAGCCCAGGCCACTTCTGCATCGTCCAGGACGGGGAC

CACTGCGCCGCGTGCCGCGCTTACGCCACCTCCAGCCCGGGCCAGAGGGTGCAGAAG

GGAGGCACCGAGAGTCAGGACACCCTGTGTCAGAACTGCCCCCCGGGGACCTTCTCT

CCCAATGGGACCCTGGAGGAATGTCAGCACCAGACCAAGTGCAGCTGGCTGGTGACG

AAGGCCGGAGCTGGGACCAGCAGCTCCCACTGGGTA

CCAAATAAAGGAAGTGGAACC

ACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTG

CTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 275)

>Artificial Sequence; hHVEM-GPI, Amino Acid

MEPPGDWGPPPWRSTPKTDVLRLVLYLTFLGAPCYAPALPSCKEDEYPVGSECCPKC

SPGYRVKEACGELTGTVCEPCPPGTYIAHLNGLSKCLQCQMCDPAMGLRASRNCSRT

ENAVCGCSPGHFCIVQDGDHCAACRAYATSSPGQRVQKGGTESQDTLCQNCPPGTFS

PNGTLEECQHQTKCSWLVTKAGAGTSSSHWV
PNKGSGTTSGTTRLLSGHTCFTLTGL

LGTLVTMGLLT

(SEQ ID NO: 276)

hPDL2-GPI
>Artificial Sequence; hPDL2-GPI, DNA

ATGATCTTCCTCCTGCTAATGTTGAGCCTGGAATTGCAGCTTCACCAGATAGCAGCT

TTATTCACAGTGACAGTCCCTAAGGAACTGTACATAATAGAGCATGGCAGCAATGTG

ACCCTGGAATGCAACTTTGACACTGGAAGTCATGTGAACCTTGGAGCAATAACAGCC

AGTTTGCAAAAGGTGGAAAATGATACATCCCCACACCGTGAAAGAGCCACTTTGCTG

GAGGAGCAGCTGCCCCTAGGGAAGGCCTCGTTCCACATACCTCAAGTCCAAGTGAGG

GACGAAGGACAGTACCAATGCATAATCATCTATGGGGTCGCCTGGGACTACAAGTAC

CTGACTCTGAAAGTCAAAGCTTCCTACAGGAAAATAAACACTCACATCCTAAAGGTT

CCAGAAACAGATGAGGTAGAGCTCACCTGCCAGGCTACAGGTTATCCTCTGGCAGAA

GTATCCTGGCCAAACGTCAGCGTTCCTGCCAACACCAGCCACTCCAGGACCCCTGAA

GGCCTCTACCAGGTCACCAGTGTTCTGCGCCTAAAGCCACCCCCTGGCAGAAACTTC

AGCTGTGTGTTCTGGAATACTCACGTGAGGGAACTTACTTTGGCCAGCATTGACCTT

CAAAGTCAGATGGAACCCAGGACCCATCCAACT
CCAAATAAAGGAAGTGGAACCACT

TCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTT

GGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 277)

>Artificial Sequence; hPDL2-GPI, Amino Acid

MIFLLLMLSLELQLHQIAALFTVTVPKELYIIEHGSNVTLECNFDTGSHVNLGAITA

SLQKVENDTSPHRERATLLEEQLPLGKASFHIPQVQVRDEGQYQCIIIYGVAWDYKY

LTLKVKASYRKINTHILKVPETDEVELTCQATGYPLAEVSWPNVSVPANTSHSRTPE

GLYQVTSVLRLKPPPGRNFSCVFWNTHVRELTLASIDLQSQMEPRTHPT
PNKGSGTT

SGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 278)

hTSG6-GPI
>Artificial Sequence; hTSG6-GPI, DNA

ATGATCATCTTAATTTACTTATTTCTCTTGCTATGGGAAGACACTCAAGGATGGGGA

TTCAAGGATGGAATTTTTCATAACTCCATATGGCTTGAACGAGCAGCCGGTGTGTAC

CACAGAGAAGCACGGTCTGGCAAATACAAGCTCACCTACGCAGAAGCTAAGGCGGTG

TGTGAATTTGAAGGCGGCCATCTCGCAACTTACAAGCAGCTAGAGGCAGCCAGAAAA

ATTGGATTTCATGTCTGTGCTGCTGGATGGATGGCTAAGGGCAGAGTTGGATACCCC

ATTGTGAAGCCAGGGCCCAACTGTGGATTTGGAAAAACTGGCATTATTGATTATGGA

ATCCGTCTCAATAGGAGTGAAAGATGGGATGCCTATTGCTACAACCCACACGCAAAG

GAGTGTGGTGGCGTCTTTACAGATCCAAAGCAAATTTTTAAATCTCCAGGCTTCCCA

AATGAGTACGAAGATAACCAAATCTGCTACTGGCACATTAGACTCAAGTATGGTCAG

CGTATTCACCTGAGTTTTTTAGATTTTGACCTTGAAGATGACCCAGGTTGCTTGGCT

GATTATGTTGAAATATATGACAGTTACGATGATGTCCATGGCTTTGTGGGAAGATAC

TGTGGAGATGAGCTTCCAGATGACATCATCAGTACAGGAAATGTCATGACCTTGAAG

TTTCTAAGTGATGCTTCAGTGACAGCTGGAGGTTTCCAAATCAAATATGTTGCAATG

GATCCTGTATCCAAATCCAGTCAAGGAAAAAATACAAGTACTACTTCTACTGGAAAT

AAAAACTTTTTAGCTGGAAGATTTAGCCACTTAATCGATCCAAATAAAGGAAGTGGA

ACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGT

TTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 279)

>Artificial Sequence; hTSG6-GPI, Amino Acid

MIILIYLFLLLWEDTQGWGFKDGIFHNSIWLERAAGVYHREARSGKYKLTYAEAKAV

CEFEGGHLATYKQLEAARKIGFHVCAAGWMAKGRVGYPIVKPGPNCGFGKTGIIDYG

IRLNRSERWDAYCYNPHAKECGGVFTDPKQIFKSPGFPNEYEDNQICYWHIRLKYGQ

RIHLSFLDFDLEDDPGCLADYVEIYDSYDDVHGFVGRYCGDELPDDIISTGNVMTLK

FLSDASVTAGGFQIKYVAMDPVSKSSQGKNTSTTSTGNKNFLAGRFSHLIDPNKGSG

TTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 280)

hHVEM-Fc-GPI
>Artificial Sequence; hHVEM-Fc-GPI, DNA

ATGGAGCCTCCTGGAGACTGGGGGCCTCCTCCCTGGAGATCCACCCCCAAAACCGAC

GTCTTGAGGCTGGTGCTGTATCTCACCTTCCTGGGAGCCCCCTGCTACGCCCCAGCT

CTGCCGTCCTGCAAGGAGGACGAGTACCCAGTGGGCTCCGAGTGCTGCCCCAAGTGC

AGTCCAGGTTATCGTGTGAAGGAGGCCTGCGGGGAGCTGACGGGCACAGTGTGTGAA

CCCTGCCCTCCAGGCACCTACATTGCCCACCTCAATGGCCTAAGCAAGTGTCTGCAG

TGCCAAATGTGTGACCCAGCCATGGGCCTGCGCGCGAGCCGGAACTGCTCCAGGACA

GAGAACGCCGTGTGTGGCTGCAGCCCAGGCCACTTCTGCATCGTCCAGGACGGGGAC

CACTGCGCCGCGTGCCGCGCTTACGCCACCTCCAGCCCGGGCCAGAGGGTGCAGAAG

GGAGGCACCGAGAGTCAGGACACCCTGTGTCAGAACTGCCCCCCGGGGACCTTCTCT

CCCAATGGGACCCTGGAGGAATGTCAGCACCAGACCAAGTGCAGCTGGCTGGTGACG

AAGGCCGGAGCTGGGACCAGCAGCTCCCACTGGGTAATCGATGACAAAACTCACACA

TGCCCACCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCC

CCAAAACCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTG

GTGGACGTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTG

GAGGTGCATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGT

GTGGTCAGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAG

TGCAAGGTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCC

AAAGGGCAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATG

ACCAAGAACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATC

GCCGTGGAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCC

GTGCTGGACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGC

AGGTGGCAGCAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAAC

CACTACACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATCCAAATAAAGGA

AGTGGAACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTG

ACAGGTTTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 281)

>Artificial Sequence; hHVEM-Fc-GPI, Amino Acid

MEPPGDWGPPPWRSTPKTDVLRLVLYLTFLGAPCYAPALPSCKEDEYPVGSECCPKC

SPGYRVKEACGELTGTVCEPCPPGTYIAHLNGLSKCLQCQMCDPAMGLRASRNCSRT

ENAVCGCSPGHFCIVQDGDHCAACRAYATSSPGQRVQKGGTESQDTLCQNCPPGTFS

PNGTLEECQHQTKCSWLVTKAGAGTSSSHWVIDDKTHTCPPCPAPELLGGPSVELFP

PKPKDTLMISRTPEVTCVVVDVSHEDPEVKENWYVDGVEVHNAKTKPREEQYNSTYR

VVSVLTVLHQDWLNGKEYKCKVSNKALPAPIEKTISKAKGQPREPQVYTLPPSREEM

TKNQVSLTCLVKGFYPSDIAVEWESNGQPENNYKTTPPVLDSDGSFFLYSKLTVDKS

RWQQGNVFSCSVMHEALHNHYTQKSLSLSPGKIDPNKGSGTTSGTTRLLSGHTCFTL

TGLLGTLVTMGLLT

(SEQ ID NO: 282)

hPDL1-GPI-P2A-
>Artificial Sequence; hPDL1-GPI-P2A-hHVEM-GPI, DNA

hHVEM-GPI

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGG
CCAAATAAAGGAAGTGGAACCACTTCA

GGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGG

ACGCTAGTAACCATGGGCTTGCTGACTGGAAGCGGAGCTACTAACTTCAGCCTGCTG

AAGCAGGCTGGCGACGTGGAGGAGAACCCTGGACCT
ATGGAGCCTCCTGGAGACTGG

GGGCCTCCTCCCTGGAGATCCACCCCCAAAACCGACGTCTTGAGGCTGGTGCTGTAT

CTCACCTTCCTGGGAGCCCCCTGCTACGCCCCAGCTCTGCCGTCCTGCAAGGAGGAC

GAGTACCCAGTGGGCTCCGAGTGCTGCCCCAAGTGCAGTCCAGGTTATCGTGTGAAG

GAGGCCTGCGGGGAGCTGACGGGCACAGTGTGTGAACCCTGCCCTCCAGGCACCTAC

ATTGCCCACCTCAATGGCCTAAGCAAGTGTCTGCAGTGCCAAATGTGTGACCCAGCC

ATGGGCCTGCGCGCGAGCCGGAACTGCTCCAGGACAGAGAACGCCGTGTGTGGCTGC

AGCCCAGGCCACTTCTGCATCGTCCAGGACGGGGACCACTGCGCCGCGTGCCGCGCT

TACGCCACCTCCAGCCCGGGCCAGAGGGTGCAGAAGGGAGGCACCGAGAGTCAGGAC

ACCCTGTGTCAGAACTGCCCCCCGGGGACCTTCTCTCCCAATGGGACCCTGGAGGAA

TGTCAGCACCAGACCAAGTGCAGCTGGCTGGTGACGAAGGCCGGAGCTGGGACCAGC

AGCTCCCACTGGGTA
CCAAATAAAGGAAGTGGAACCACTTCAGGTACTACCCGTCTT

CTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGGACGCTAGTAACCATG

GGCTTGCTGACTTAG

(SEQ ID NO: 283)

>Artificial Sequence; hPDL1-GPI-P2A-hHVEM-GPI, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNER
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLTGS
GATNESLL

KQAGDVEENPGP
MEPPGDWGPPPWRSTPKTDVLRLVLYLTFLGAPCYAPALPSCKED

EYPVGSECCPKCSPGYRVKEACGELTGTVCEPCPPGTYIAHLNGLSKCLQCQMCDPA

MGLRASRNCSRTENAVCGCSPGHFCIVQDGDHCAACRAYATSSPGQRVQKGGTESQD

TLCQNCPPGTFSPNGTLEECQHQTKCSWLVTKAGAGTSSSHWV
PNKGSGTTSGTTRL

LSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 284)

mCTLA4-Fc-GPI
>Artificial Sequence; mCTLA4-Fc-GPI, DNA

ATGGCTTGTCTTGGACTCCGGAGGTACAAAGCTCAACTGCAGCTGCCTTCTAGGACT

TGGCCTTTTGTAGCCCTGCTCACTCTTCTTTTCATCCCAGTCTTCTCTGAAGCCATA

CAGGTGACCCAACCTTCAGTGGTGTTGGCTAGCAGCCATGGTGTCGCCAGCTTTCCA

TGTGAATATTCACCATCACACAACACTGATGAGGTCCGGGTGACTGTGCTGCGGCAG

ACAAATGACCAAATGACTGAGGTCTGTGCCACGACATTCACAGAGAAGAATACAGTG

GGCTTCCTAGATTACCCCTTCTGCAGTGGTACCTTTAATGAAAGCAGAGTGAACCTC

ACCATCCAAGGACTGAGAGCTGTTGACACGGGACTGTACCTCTGCAAGGTGGAACTC

ATGTACCCACCGCCATACTTTGTGGGCATGGGCAACGGGACGCAGATTTATGTCATT

GATCCAGAACCATGCCCGGATTCTGAATCGATGACAAAACTCACACATGCCCACCGT

GCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCAAAACCCA

AGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTGGACGTGA

GCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAGGTGCATA

ATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTGGTCAGCG

TCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGCAAGGTCT

CCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAAGGGCAGC

CCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATGACCAAGAACC

AGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCCGTGGAGT

GGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTGCTGGACT

CCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGGCAGC

AGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAACCACTACACGC

AGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATCCAAATAAAGGAAGTGGAACCA

CTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGC

TTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 285)

>Artificial Sequence; mCTLA4-Fc-GPI, Amino Acid

MACLGLRRYKAQLQLPSRTWPFVALLTLLFIPVFSEAIQVTQPSVVLASSHGVASFP

CEYSPSHNTDEVRVTVLRQTNDQMTEVCATTFTEKNTVGFLDYPFCSGTFNESRVNL

TIQGLRAVDTGLYLCKVELMYPPPYFVGMGNGTQIYVIDPEPCPDSD

IDDKTHTCPPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVDVSHEDPEVKF

NWYVDGVEVHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCKVSNKALPAPI

EKTISKAKGQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAVEWESNGQPEN

NYKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHYTQKSLSLSPG

KIDPNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 286)

mPDL1-C1C2
>Artificial Sequence; mPDL1-C1C2, DNA

ATGAGGATATTTGCTGGCATTATATTCACAGCCTGCTGTCACTTGCTACGGGCGTTT

ACTATCACGGCTCCAAAGGACTTGTACGTGGTGGAGTATGGCAGCAACGTCACGATG

GAGTGCAGATTCCCTGTAGAACGGGAGCTGGACCTGCTTGCGTTAGTGGTGTACTGG

GAAAAGGAAGATGAGCAAGTGATTCAGTTTGTGGCAGGAGAGGAGGACCTTAAGCCT

CAGCACAGCAACTTCAGGGGGAGAGCCTCGCTGCCAAAGGACCAGCTTTTGAAGGGA

AATGCTGCCCTTCAGATCACAGACGTCAAGCTGCAGGACGCAGGCGTTTACTGCTGC

ATAATCAGCTACGGTGGTGCGGACTACAAGCGAATCACGCTGAAAGTCAATGCCCCA

TACCGCAAAATCAACCAGAGAATTTCCGTGGATCCAGCCACTTCTGAGCATGAACTA

ATATGTCAGGCCGAGGGTTATCCAGAAGCTGAGGTAATCTGGACAAACAGTGACCAC

CAACCCGTGAGTGGGAAGAGAAGTGTCACCACTTCCCGGACAGAGGGGATGCTTCTC

AATGTGACCAGCAGTCTGAGGGTCAACGCCACAGCGAATGATGTTTTCTACTGTACG

TTTTGGAGATCACAGCCAGGGCAAAACCACACAGCGGAGCTGATCATCCCAGAACTG

CCTGCAACACATCCTCCACAGAACAGGACTATCGATGTCGAGCCACTGGGCATGGAG

AATGGGAACATTGCCAACTCACAGATCGCCGCCTCATCTGTGCGTGTGACCTTCTTG

GGTTTGCAGCATTGGGTCCCGGAGCTGGCCCGCCTGAACCGCGCAGGCATGGTCAAT

GCCTGGACACCCAGCAGCAATGACGATAACCCCTGGATCCAGGTGAACCTGCTGCGG

AGGATGTGGGTAACAGGTGTGGTGACGCAGGGTGCCAGCCGCTTGGCCAGTCATGAG

TACCTGAAGGCCTTCAAGGTGGCCTACAGCCTTAATGGACACGAATTCGATTTCATC

CATGATGTTAATAAAAAACACAAGGAGTTTGTGGGTAACTGGAACAAAAACGCGGTG

CATGTCAACCTGTTTGAGACCCCTGTGGAGGCTCAGTACGTGAGATTGTACCCCACG

AGCTGCCACACGGCCTGCACTCTGCGCTTTGAGCTACTGGGCTGTGAGCTGAACGGA

TGCGCCAATCCCCTGGGCCTGAAGAATAACAGCATCCCTGACAAGCAGATCACGGCC

TCCAGCAGCTACAAGACCTGGGGCTTGCATCTCTTCAGCTGGAACCCCTCCTATGCA

CGGCTGGACAAGCAGGGCAACTTCAACGCCTGGGTTGCGGGGAGCTACGGTAACGAT

CAGTGGCTGCAGATCTTCCCTGGCAACTGGGACAACCACTCCCACAAGAAGAACTTG

TTTGAGACGCCCATCCTGGCTCGCTATGTGCGCATCCTGCCTGTAGCCTGGCACAAC

CGCATCGCCCTGCGCCTGGAGCTGCTGGGCTGTTAG

(SEQ ID NO: 287)

>Artificial Sequence; mPDL1-C1C2, Amino Acid

MRIFAGIIFTACCHLLRAFTITAPKDLYVVEYGSNVTMECRFPVERELDLLALVVYW

EKEDEQVIQFVAGEEDLKPQHSNFRGRASLPKDQLLKGNAALQITDVKLQDAGVYCC

IISYGGADYKRITLKVNAPYRKINQRISVDPATSEHELICQAEGYPEAEVIWINSDH

QPVSGKRSVTTSRTEGMLLNVTSSLRVNATANDVFYCTFWRSQPGQNHTAELIIPEL

PATHPPQNRTIDVEPLGMENGNIANSQIAASSVRVTFLGLQHWVPELARLNRAGMVN

AWTPSSNDDNPWIQVNLLRRMWVTGVVTQGASRLASHEYLKAFKVAYSLNGHEFDFI

HDVNKKHKEFVGNWNKNAVHVNLFETPVEAQYVRLYPTSCHTACTLRFELLGCELNG

CANPLGLKNNSIPDKQITASSSYKTWGLHLFSWNPSYARLDKQGNENAWVAGSYGND

QWLQIFPGNWDNHSHKKNLFETPILARYVRILPVAWHNRIALRLELLGC

(SEQ ID NO: 288)

mPDL1-Fc-GPI
>Artificial Sequence; mPDL1-Fc-GPI, DNA

ATGAGGATATTTGCTGGCATTATATTCACAGCCTGCTGTCACTTGCTACGGGCGTTT

ACTATCACGGCTCCAAAGGACTTGTACGTGGTGGAGTATGGCAGCAACGTCACGATG

GAGTGCAGATTCCCTGTAGAACGGGAGCTGGACCTGCTTGCGTTAGTGGTGTACTGG

GAAAAGGAAGATGAGCAAGTGATTCAGTTTGTGGCAGGAGAGGAGGACCTTAAGCCT

CAGCACAGCAACTTCAGGGGGAGAGCCTCGCTGCCAAAGGACCAGCTTTTGAAGGGA

AATGCTGCCCTTCAGATCACAGACGTCAAGCTGCAGGACGCAGGCGTTTACTGCTGC

ATAATCAGCTACGGTGGTGCGGACTACAAGCGAATCACGCTGAAAGTCAATGCCCCA

TACCGCAAAATCAACCAGAGAATTTCCGTGGATCCAGCCACTTCTGAGCATGAACTA

ATATGTCAGGCCGAGGGTTATCCAGAAGCTGAGGTAATCTGGACAAACAGTGACCAC

CAACCCGTGAGTGGGAAGAGAAGTGTCACCACTTCCCGGACAGAGGGGATGCTTCTC

AATGTGACCAGCAGTCTGAGGGTCAACGCCACAGCGAATGATGTTTTCTACTGTACG

TTTTGGAGATCACAGCCAGGGCAAAACCACACAGCGGAGCTGATCATCCCAGAACTG

CCTGCAACACATCCTCCACAGAACAGGACTATCGATGACAAAACTCACACATGCCCA

CCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCAAAA

CCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTGGAC

GTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAGGTG

CATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTGGTC

AGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGCAAG

GTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAAGGG

CAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATGACCAAG

AACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCCGTG

GAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTGCTG

GACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGG

CAGCAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAACCACTAC

ACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATCCAAATAAAGGAAGTGGA

ACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGT

TTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 289)

>Artificial Sequence; mPDL1-Fc-GPI, Amino Acid

MRIFAGIIFTACCHLLRAFTITAPKDLYVVEYGSNVTMECRFPVERELDLLALVVYW

EKEDEQVIQFVAGEEDLKPQHSNFRGRASLPKDQLLKGNAALQITDVKLQDAGVYCC

IISYGGADYKRITLKVNAPYRKINQRISVDPATSEHELICQAEGYPEAEVIWTNSDH

QPVSGKRSVTTSRTEGMLLNVTSSLRVNATANDVFYCTFWRSQPGQNHTAELIIPEL

PATHPPQNRTIDDKTHTCPPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVD

VSHEDPEVKFNWYVDGVEVHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCK

VSNKALPAPIEKTISKAKGQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAV

EWESNGQPENNYKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHY

TQKSLSLSPGKIDPNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 290)

mPDL1-GPI
>Artificial Sequence; mPDL1-GPI, DNA

ATGAGGATATTTGCTGGCATTATATTCACAGCCTGCTGTCACTTGCTACGGGCGTTT

ACTATCACGGCTCCAAAGGACTTGTACGTGGTGGAGTATGGCAGCAACGTCACGATG

GAGTGCAGATTCCCTGTAGAACGGGAGCTGGACCTGCTTGCGTTAGTGGTGTACTGG

GAAAAGGAAGATGAGCAAGTGATTCAGTTTGTGGCAGGAGAGGAGGACCTTAAGCCT

CAGCACAGCAACTTCAGGGGGAGAGCCTCGCTGCCAAAGGACCAGCTTTTGAAGGGA

AATGCTGCCCTTCAGATCACAGACGTCAAGCTGCAGGACGCAGGCGTTTACTGCTGC

ATAATCAGCTACGGTGGTGCGGACTACAAGCGAATCACGCTGAAAGTCAATGCCCCA

TACCGCAAAATCAACCAGAGAATTTCCGTGGATCCAGCCACTTCTGAGCATGAACTA

ATATGTCAGGCCGAGGGTTATCCAGAAGCTGAGGTAATCTGGACAAACAGTGACCAC

CAACCCGTGAGTGGGAAGAGAAGTGTCACCACTTCCCGGACAGAGGGGATGCTTCTC

AATGTGACCAGCAGTCTGAGGGTCAACGCCACAGCGAATGATGTTTTCTACTGTACG

TTTTGGAGATCACAGCCAGGGCAAAACCACACAGCGGAGCTGATCATCCCAGAACTG

CCTGCAACACATCCTCCACAGAACAGGACT
CCAAATAAAGGAAGTGGAACCACTTCA

GGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGG

ACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 291)

>Artificial Sequence; mPDL1-GPI, Amino Acid

MRIFAGIIFTACCHLLRAFTITAPKDLYVVEYGSNVTMECRFPVERELDLLALVVYW

EKEDEQVIQFVAGEEDLKPQHSNFRGRASLPKDQLLKGNAALQITDVKLQDAGVYCC

IISYGGADYKRITLKVNAPYRKINQRISVDPATSEHELICQAEGYPEAEVIWINSDH

QPVSGKRSVTTSRTEGMLLNVTSSLRVNATANDVFYCTFWRSQPGQNHTAELIIPEL

PATHPPQNRT
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 292)

mPDL2-C1C2
>Artificial Sequence; mPDL2-C1C2, DNA

ATGCTGCTCCTGCTGCCGATACTGAACCTGAGCTTACAACTTCATCCTGTAGCAGCT

TTATTCACCGTGACAGCCCCTAAAGAAGTGTACACCGTAGACGTCGGCAGCAGTGTG

AGCCTGGAGTGCGATTTTGACCGCAGAGAATGCACTGAACTGGAAGGGATAAGAGCC

AGTTTGCAGAAGGTAGAAAATGATACGTCTCTGCAAAGTGAAAGAGCCACCCTGCTG

GAGGAGCAGCTGCCCCTGGGAAAGGCTTTGTTCCACATCCCTAGTGTCCAAGTGAGA

GATTCCGGGCAGTACCGTTGCCTGGTCATCTGCGGGGCCGCCTGGGACTACAAGTAC

CTGACGGTGAAAGTCAAAGCTTCTTACATGAGGATAGACACTAGGATCCTGGAGGTT

CCAGGTACAGGGGAGGTGCAGCTTACCTGCCAGGCTAGAGGTTATCCCCTAGCAGAA

GTGTCCTGGCAAAATGTCAGTGTTCCTGCCAACACCAGCCACATCAGGACCCCCGAA

GGCCTCTACCAGGTCACCAGTGTTCTGCGCCTCAAGCCTCAGCCTAGCAGAAACTTC

AGCTGCATGTTCTGGAATGCTCACATGAAGGAGCTGACTTCAGCCATCATTGACCCT

CTGAGTCGGATGGAACCCAAAGTCCCCAGAACGATCGATGTCGAGCCACTGGGCATG

GAGAATGGGAACATTGCCAACTCACAGATCGCCGCCTCATCTGTGCGTGTGACCTTC

TTGGGTTTGCAGCATTGGGTCCCGGAGCTGGCCCGCCTGAACCGCGCAGGCATGGTC

AATGCCTGGACACCCAGCAGCAATGACGATAACCCCTGGATCCAGGTGAACCTGCTG

CGGAGGATGTGGGTAACAGGTGTGGTGACGCAGGGTGCCAGCCGCTTGGCCAGTCAT

GAGTACCTGAAGGCCTTCAAGGTGGCCTACAGCCTTAATGGACACGAATTCGATTTC

ATCCATGATGTTAATAAAAAACACAAGGAGTTTGTGGGTAACTGGAACAAAAACGCG

GTGCATGTCAACCTGTTTGAGACCCCTGTGGAGGCTCAGTACGTGAGATTGTACCCC

ACGAGCTGCCACACGGCCTGCACTCTGCGCTTTGAGCTACTGGGCTGTGAGCTGAAC

GGATGCGCCAATCCCCTGGGCCTGAAGAATAACAGCATCCCTGACAAGCAGATCACG

GCCTCCAGCAGCTACAAGACCTGGGGCTTGCATCTCTTCAGCTGGAACCCCTCCTAT

GCACGGCTGGACAAGCAGGGCAACTTCAACGCCTGGGTTGCGGGGAGCTACGGTAAC

GATCAGTGGCTGCAGATCTTCCCTGGCAACTGGGACAACCACTCCCACAAGAAGAAC

TTGTTTGAGACGCCCATCCTGGCTCGCTATGTGCGCATCCTGCCTGTAGCCTGGCAC

AACCGCATCGCCCTGCGCCTGGAGCTGCTGGGCTGTTAG

(SEQ ID NO: 293)

>Artificial Sequence; mPDL2-C1C2, Amino Acid

MLLLLPILNLSLQLHPVAALFTVTAPKEVYTVDVGSSVSLECDFDRRECTELEGIRA

SLQKVENDTSLQSERATLLEEQLPLGKALFHIPSVQVRDSGQYRCLVICGAAWDYKY

LTVKVKASYMRIDTRILEVPGTGEVQLTCQARGYPLAEVSWQNVSVPANTSHIRTPE

GLYQVTSVLRLKPQPSRNFSCMFWNAHMKELTSAIIDPLSRMEPKVPRTIDVEPLGM

ENGNIANSQIAASSVRVTFLGLQHWVPELARLNRAGMVNAWTPSSNDDNPWIQVNLL

RRMWVTGVVTQGASRLASHEYLKAFKVAYSLNGHEFDFIHDVNKKHKEFVGNWNKNA

VHVNLFETPVEAQYVRLYPTSCHTACTLRFELLGCELNGCANPLGLKNNSIPDKQIT

ASSSYKTWGLHLFSWNPSYARLDKQGNFNAWVAGSYGNDQWLQIFPGNWDNHSHKKN

LFETPILARYVRILPVAWHNRIALRLELLGC

(SEQ ID NO: 294)

mPDL2-Fc-GPI
>Artificial Sequence; mPDL2-Fc-GPI, DNA

ATGCTGCTCCTGCTGCCGATACTGAACCTGAGCTTACAACTTCATCCTGTAGCAGCT

TTATTCACCGTGACAGCCCCTAAAGAAGTGTACACCGTAGACGTCGGCAGCAGTGTG

AGCCTGGAGTGCGATTTTGACCGCAGAGAATGCACTGAACTGGAAGGGATAAGAGCC

AGTTTGCAGAAGGTAGAAAATGATACGTCTCTGCAAAGTGAAAGAGCCACCCTGCTG

GAGGAGCAGCTGCCCCTGGGAAAGGCTTTGTTCCACATCCCTAGTGTCCAAGTGAGA

GATTCCGGGCAGTACCGTTGCCTGGTCATCTGCGGGGCCGCCTGGGACTACAAGTAC

CTGACGGTGAAAGTCAAAGCTTCTTACATGAGGATAGACACTAGGATCCTGGAGGTT

CCAGGTACAGGGGAGGTGCAGCTTACCTGCCAGGCTAGAGGTTATCCCCTAGCAGAA

GTGTCCTGGCAAAATGTCAGTGTTCCTGCCAACACCAGCCACATCAGGACCCCCGAA

GGCCTCTACCAGGTCACCAGTGTTCTGCGCCTCAAGCCTCAGCCTAGCAGAAACTTC

AGCTGCATGTTCTGGAATGCTCACATGAAGGAGCTGACTTCAGCCATCATTGACCCT

CTGAGTCGGATGGAACCCAAAGTCCCCAGAACGATCGATGACAAAACTCACACATGC

CCACCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCA

AAACCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTG

GACGTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAG

GTGCATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTG

GTCAGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGC

AAGGTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAA

GGGCAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATGACC

AAGAACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCC

GTGGAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTG

CTGGACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGG

TGGCAGCAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAACCAC

TACACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATCCAAATAAAGGAAGT

GGAACCACTTCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACA

GGTTTGCTTGGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 295)

>Artificial Sequence; mPDL2-Fc-GPI, Amino Acid

MLLLLPILNLSLQLHPVAALFTVTAPKEVYTVDVGSSVSLECDFDRRECTELEGIRA

SLQKVENDTSLQSERATLLEEQLPLGKALFHIPSVQVRDSGQYRCLVICGAAWDYKY

LTVKVKASYMRIDTRILEVPGTGEVQLTCQARGYPLAEVSWQNVSVPANTSHIRTPE

GLYQVTSVLRLKPQPSRNFSCMFWNAHMKELTSAIIDPLSRMEPKVPRTIDDKTHTC

PPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVDVSHEDPEVKENWYVDGVE

VHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCKVSNKALPAPIEKTISKAK

GQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAVEWESNGQPENNYKTTPPV

LDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHYTQKSLSLSPGKIDPNKGS

GTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 296)

mPDL1-mFc-GPI
>Artificial Sequence; mPDL1-mFc-GPI, DNA

ATGAGGATATTTGCTGGCATTATATTCACAGCCTGCTGTCACTTGCTACGGGCGTTT

ACTATCACGGCTCCAAAGGACTTGTACGTGGTGGAGTATGGCAGCAACGTCACGATG

GAGTGCAGATTCCCTGTAGAACGGGAGCTGGACCTGCTTGCGTTAGTGGTGTACTGG

GAAAAGGAAGATGAGCAAGTGATTCAGTTTGTGGCAGGAGAGGAGGACCTTAAGCCT

CAGCACAGCAACTTCAGGGGGAGAGCCTCGCTGCCAAAGGACCAGCTTTTGAAGGGA

AATGCTGCCCTTCAGATCACAGACGTCAAGCTGCAGGACGCAGGCGTTTACTGCTGC

ATAATCAGCTACGGTGGTGCGGACTACAAGCGAATCACGCTGAAAGTCAATGCCCCA

TACCGCAAAATCAACCAGAGAATTTCCGTGGATCCAGCCACTTCTGAGCATGAACTA

ATATGTCAGGCCGAGGGTTATCCAGAAGCTGAGGTAATCTGGACAAACAGTGACCAC

CAACCCGTGAGTGGGAAGAGAAGTGTCACCACTTCCCGGACAGAGGGGATGCTTCTC

AATGTGACCAGCAGTCTGAGGGTCAACGCCACAGCGAATGATGTTTTCTACTGTACG

TTTTGGAGATCACAGCCAGGGCAAAACCACACAGCGGAGCTGATCATCCCAGAACTG

CCTGCAACACATCCTCCACAGAACAGGACT
GGTTGTAAGCCTTGCATATGTACAGTC

CCAGAAGTATCATCTGTCTTCATCTTCCCCCCAAAGCCCAAGGATGTGCTCACCATT

ACTCTGACTCCTAAGGTCACGTGTGTTGTGGTAGACATCAGCAAGGATGATCCCGAG

GTCCAGTTCAGCTGGTTTGTAGATGATGTGGAGGTGCACACAGCTCAGACGCAACCC

CGGGAGGAGCAGTTCAACAGCACTTTCCGCTCAGTCAGTGAACTTCCCATCATGCAC

CAGGACTGGCTCAATGGCAAGGAGTTCAAATGCAGGGTCAACAGTGCAGCTTTCCCT

GCCCCCATCGAGAAAACCATCTCCAAAACCAAAGGCAGACCGAAGGCTCCACAGGTG

TACACCATTCCACCTCCCAAGGAGCAGATGGCCAAGGATAAAGTCAGTCTGACCTGC

ATGATAACAGACTTCTTCCCTGAAGACATTACTGTGGAGTGGCAGTGGAATGGGCAG

CCAGCGGAGAACTACAAGAACACTCAGCCCATCATGGACACAGATGGCTCTTACTTC

GTCTACAGCAAGCTCAATGTGCAGAAGAGCAACTGGGAGGCAGGAAATACTTTCACC

TGCTCTGTGTTACATGAGGGCCTGCACAACCACCATACTGAGAAGAGCCTCTCCCAC

TCTCCTGGTAAA
CCAAATAAAGGAAGTGGAACCACTTCAGGTACTACCCGTCTTCTA

TCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGGACGCTAGTAACCATGGGC

TTGCTGACTTAG

(SEQ ID NO: 297)

>Artificial Sequence; mPDL1-mFc-GPI, Amino Acid

MRIFAGIIFTACCHLLRAFTITAPKDLYVVEYGSNVTMECRFPVERELDLLALVVYW

EKEDEQVIQFVAGEEDLKPQHSNFRGRASLPKDQLLKGNAALQITDVKLQDAGVYCC

IISYGGADYKRITLKVNAPYRKINQRISVDPATSEHELICQAEGYPEAEVIWTNSDH

QPVSGKRSVTTSRTEGMLLNVTSSLRVNATANDVFYCTFWRSQPGQNHTAELIIPEL

PATHPPQNRT
GCKPCICTVPEVSSVFIFPPKPKDVLTITLTPKVTCVVVDISKDDPE

VQFSWFVDDVEVHTAQTQPREEQFNSTFRSVSELPIMHQDWLNGKEFKCRVNSAAFP

APIEKTISKTKGRPKAPQVYTIPPPKEQMAKDKVSLTCMITDFFPEDITVEWQWNGQ

PAENYKNTQPIMDTDGSYFVYSKLNVQKSNWEAGNTFTCSVLHEGLHNHHTEKSLSH

SPGK
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 298)

mPDL2-GPI
>Artificial Sequence; mPDL2-GPI, DNA

ATGCTGCTCCTGCTGCCGATACTGAACCTGAGCTTACAACTTCATCCTGTAGCAGCT

TTATTCACCGTGACAGCCCCTAAAGAAGTGTACACCGTAGACGTCGGCAGCAGTGTG

AGCCTGGAGTGCGATTTTGACCGCAGAGAATGCACTGAACTGGAAGGGATAAGAGCC

AGTTTGCAGAAGGTAGAAAATGATACGTCTCTGCAAAGTGAAAGAGCCACCCTGCTG

GAGGAGCAGCTGCCCCTGGGAAAGGCTTTGTTCCACATCCCTAGTGTCCAAGTGAGA

GATTCCGGGCAGTACCGTTGCCTGGTCATCTGCGGGGCCGCCTGGGACTACAAGTAC

CTGACGGTGAAAGTCAAAGCTTCTTACATGAGGATAGACACTAGGATCCTGGAGGTT

CCAGGTACAGGGGAGGTGCAGCTTACCTGCCAGGCTAGAGGTTATCCCCTAGCAGAA

GTGTCCTGGCAAAATGTCAGTGTTCCTGCCAACACCAGCCACATCAGGACCCCCGAA

GGCCTCTACCAGGTCACCAGTGTTCTGCGCCTCAAGCCTCAGCCTAGCAGAAACTTC

AGCTGCATGTTCTGGAATGCTCACATGAAGGAGCTGACTTCAGCCATCATTGACCCT

CTGAGTCGGATGGAACCCAAAGTCCCCAGAACG
CCAAATAAAGGAAGTGGAACCACT

TCAGGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTT

GGGACGCTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 299)

>Artificial Sequence; mPDL2-GPI, Amino Acid

MLLLLPILNLSLQLHPVAALFTVTAPKEVYTVDVGSSVSLECDFDRRECTELEGIRA

SLQKVENDTSLQSERATLLEEQLPLGKALFHIPSVQVRDSGQYRCLVICGAAWDYKY

LTVKVKASYMRIDTRILEVPGTGEVQLTCQARGYPLAEVSWQNVSVPANTSHIRTPE

GLYQVTSVLRLKPQPSRNFSCMFWNAHMKELTSAIIDPLSRMEPKVPRT
PNKGSGTT

SGTTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 300)

mPDL1-GPI-P2A-
>Artificial Sequence; mPDL1-GPI-P2A-mHVEM-GPI, DNA

mHVEM-GPI

ATGAGGATATTTGCTGGCATTATATTCACAGCCTGCTGTCACTTGCTACGGGCGTTT

ACTATCACGGCTCCAAAGGACTTGTACGTGGTGGAGTATGGCAGCAACGTCACGATG

GAGTGCAGATTCCCTGTAGAACGGGAGCTGGACCTGCTTGCGTTAGTGGTGTACTGG

GAAAAGGAAGATGAGCAAGTGATTCAGTTTGTGGCAGGAGAGGAGGACCTTAAGCCT

CAGCACAGCAACTTCAGGGGGAGAGCCTCGCTGCCAAAGGACCAGCTTTTGAAGGGA

AATGCTGCCCTTCAGATCACAGACGTCAAGCTGCAGGACGCAGGCGTTTACTGCTGC

ATAATCAGCTACGGTGGTGCGGACTACAAGCGAATCACGCTGAAAGTCAATGCCCCA

TACCGCAAAATCAACCAGAGAATTTCCGTGGATCCAGCCACTTCTGAGCATGAACTA

ATATGTCAGGCCGAGGGTTATCCAGAAGCTGAGGTAATCTGGACAAACAGTGACCAC

CAACCCGTGAGTGGGAAGAGAAGTGTCACCACTTCCCGGACAGAGGGGATGCTTCTC

AATGTGACCAGCAGTCTGAGGGTCAACGCCACAGCGAATGATGTTTTCTACTGTACG

TTTTGGAGATCACAGCCAGGGCAAAACCACACAGCGGAGCTGATCATCCCAGAACTG

CCTGCAACACATCCTCCACAGAACAGGACT
CCAAATAAAGGAAGTGGAACCACTTCA

GGTACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGG

ACGCTAGTAACCATGGGCTTGCTGACTGGAAGCGGAGCTACTAACTTCAGCCTGCTG

AAGCAGGCTGGCGACGTGGAGGAGAACCCTGGACCT
ATGGAACCTCTCCCAGGATGG

GGGTCGGCACCCTGGAGCCAGGCCCCTACAGACAACACCTTCAGGCTGGTGCCTTGT

GTCTTCCTTTTGAACTTGCTGCAGCGCATCTCTGCCCAGCCCTCATGCAGACAGGAG

GAGTTCCTTGTGGGAGACGAGTGCTGCCCCATGTGCAACCCAGGTTACCATGTGAAG

CAGGTCTGCAGTGAGCATACAGGCACAGTGTGTGCCCCCTGTCCCCCACAGACATAT

ACCGCCCATGCAAATGGCCTGAGCAAGTGTCTGCCCTGCGGAGTCTGTGATCCAGAC

ATGGGCCTGCTGACCTGGCAGGAGTGCTCCAGCTGGAAGGACACTGTGTGCAGATGC

ATCCCAGGCTACTTCTGTGAGAACCAGGATGGGAGCCACTGTTCCACATGCTTGCAG

CACACCACCTGCCCTCCAGGGCAGAGGGTAGAGAAGAGAGGGACTCACGACCAGGAC

ACTGTATGTGCTGACTGCCTAACAGGGACCTTCTCACTTGGAGGGACTCAGGAGGAA

TGCCTGCCCTGGACCAACTGCAGTGCATTTCAACAGGAAGTAAGACGTGGGACCAAC

AGCACAGACACCACCTGCTCCTCCCAG
CCAAATAAAGGAAGTGGAACCACTTCAGGT

ACTACCCGTCTTCTATCTGGGCACACGTGTTTCACGTTGACAGGTTTGCTTGGGACG

CTAGTAACCATGGGCTTGCTGACTTAG

(SEQ ID NO: 301)

>Artificial Sequence; mPDL1-GPI-P2A-mHVEM-GPI, Amino Acid

MRIFAGIIFTACCHLLRAFTITAPKDLYVVEYGSNVTMECRFPVERELDLLALVVYW

EKEDEQVIQFVAGEEDLKPQHSNFRGRASLPKDQLLKGNAALQITDVKLQDAGVYCC

IISYGGADYKRITLKVNAPYRKINQRISVDPATSEHELICQAEGYPEAEVIWTNSDH

QPVSGKRSVTTSRTEGMLLNVTSSLRVNATANDVFYCTFWRSQPGQNHTAELIIPEL

PATHPPQNRT
PNKGSGTTSGTTRLLSGHTCFTLTGLLGTLVTMGLLTGSGATNFSLL

KQAGDVEENPGP
MEPLPGWGSAPWSQAPTDNTFRLVPCVFLLNLLQRISAQPSCRQE

EFLVGDECCPMCNPGYHVKQVCSEHTGTVCAPCPPQTYTAHANGLSKCLPCGVCDPD

MGLLTWQECSSWKDTVCRCIPGYFCENQDGSHCSTCLQHTTCPPGQRVEKRGTHDQD

TVCADCLTGTFSLGGTQEECLPWTNCSAFQQEVRRGINSTDTTCSSQ
PNKGSGTTSG

TTRLLSGHTCFTLTGLLGTLVTMGLLT

(SEQ ID NO: 302)

hPDL1-ADAM10
>Artificial Sequence; hPDL1-ADAM10, DNA

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGG
TGTGGAAATGGAATGGTAGAACAAGGT

GAAGAATGTGATTGTGGCTATAGTGACCAGTGTAAAGATGAATGCTGCTTCGATGCA

AATCAACCAGAGGGAAGAAAATGCAAACTGAAACCTGGGAAACAGTGCAGTCCAAGT

CAAGGTCCTTGTTGTACAGCACAGTGTGCATTCAAGTCAAAGTCTGAGAAGTGTCGG

GATGATTCAGACTGTGCAAGGGAAGGAATATGTAATGGCTTCACAGCTCTCTGCCCA

GCATCTGACCCTAAACCAAACTTCACAGACTGTAATAGGCATACACAAGTGTGCATT

AATGGGCAATGTGCAGGTTCTATCTGTGAGAAATATGGCTTAGAGGAGTGTACGTGT

GCCAGTTCTGATGGCAAAGATGATAAAGAATTATGCCATGTATGCTGTATGAAGAAA

ATGGACCCATCAACTTGTGCCAGTACAGGGTCTGTGCAGTGGAGTAGGCACTTCAGT

GGTCGAACCATCACCCTGCAACCTGGATCCCCTTGCAACGATTTTAGAGGTTACTGT

GATGTTTTCATGCGGTGCAGATTAGTAGATGCTGATGGTCCTCTAGCTAGGCTTAAA

AAAGCAATTTTTAGTCCAGAGCTCTATGAAAACATTGCTGAATGGATTGTGGCTCAT

TGGTGGGCAGTATTACTTATGGGAATTGCTCTGATCATGCTAATGGCTGGATTTATT

AAGATATGCAGTGTTCATACTCCAAGTAGTAATCCAAAGTTGCCTCCTCCTAAACCA

CTTCCAGGCACTTTAAAGAGGAGGAGACCTCCACAGCCCATTCAGCAACCCCAGCGT

CAGCGGCCCCGAGAGAGTTATCAAATGGGACACATGAGACGCTAA

(SEQ ID NO: 303)

>Artificial Sequence; hPDL1-ADAM10, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLENVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNER
CGNGMVEQGEECDCGYSDQCKDECCFDANQPEGRKCKLKPGKQCSPS

QGPCCTAQCAFKSKSEKCRDDSDCAREGICNGFTALCPASDPKPNETDCNRHTQVCI

NGQCAGSICEKYGLEECTCASSDGKDDKELCHVCCMKKMDPSTCASTGSVQWSRHES

GRTITLQPGSPCNDERGYCDVEMRCRLVDADGPLARLKKAIFSPELYENIAEWIVAH

WWAVLLMGIALIMLMAGFIKICSVHTPSSNPKLPPPKPLPGTLKRRRPPQPIQQPQR

QRPRESYQMGHMRR

(SEQ ID NO: 304)

hPDL1-4Fc-
>Artificial Sequence; hPDL1-4Fc-CD9tm2, DNA

CD9tm2

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGG
GAGTCCAAATATGGTCCCCCATGCCCA

TCATGCCCAGCACCTGAGTTCCTGGGGGGACCATCAGTCTTCCTGTTCCCCCCAAAA

CCCAAGGACACTCTCATGATCTCCCGGACCCCTGAGGTCACGTGCGTGGTGGTGGAC

GTGAGCCAGGAAGACCCCGAGGTCCAGTTCAACTGGTACGTGGATGGCGTGGAGGTG

CATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTTCAACAGCACGTACCGTGTGGTC

AGGGTCCTCACCGTCCTGCACCAGGACTGGCTGAACGGTAAGGAGTACAAGTGCAAG

GTCTCCAACAAAGGCCTCCCGTCCTCCATCGAGAAAACCATCTCCAAAGCCAAAGGG

CAGCCCCGAGAGCCACAGGTGTACACCCTGCCCCCATCCCAGGAGGAGATGACCAAG

AACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTACCCCAGCGACATCGCCGTG

GAGTGGGAGAGCAATGGGCAGCCGGAGGACAACTACAAGACCACGCCTCCCGTGCTG

GACTCCGACGGCTCCTTCTTCCTCTACAGCAGGCTAACCGTGGACAAGAGCAGGTGG

CAGGAGGGGAATGTCTTCTCATGCTCCGTGATGCATGAGGCTCTGCACAACCACTAC

ACACAGAAGAGCCTCTCCCTGTCTCCGGGTAAA
TTCTACACAGGAGTCTATATTCTG

ATCGGAGCCGGCGCCCTCATGATGCTGGTGGGCTTCCTGGGCTGCTGCGGGGCTGTG

CAGGAGTCCCAGTGC

(SEQ ID NO: 305)

>Artificial Sequence; hPDL1-4Fc-CD9tm2, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLENVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNER
ESKYGPPCPSCPAPEFLGGPSVFLFPPKPKDTLMISRTPEVTCVVVD

VSQEDPEVQFNWYVDGVEVHNAKTKPREEQFNSTYRVVRVLTVLHQDWLNGKEYKCK

VSNKGLPSSIEKTISKAKGQPREPQVYTLPPSQEEMTKNQVSLTCLVKGFYPSDIAV

EWESNGQPEDNYKTTPPVLDSDGSFFLYSRLTVDKSRWQEGNVESCSVMHEALHNHY

TQKSLSLSPGK
FYTGVYILIGAGALMMLVGELGCCGAVQESQCVIM

(SEQ ID NO: 306)

hPDL1-4Fc-
>Artificial Sequence; hPDL1-4Fc-CD9tm2-KRAS, DNA

CD9tm2-

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

modified KRas

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGG
GAGTCCAAATATGGTCCCCCATGCCCA

TCATGCCCAGCACCTGAGTTCCTGGGGGGACCATCAGTCTTCCTGTTCCCCCCAAAA

CCCAAGGACACTCTCATGATCTCCCGGACCCCTGAGGTCACGTGCGTGGTGGTGGAC

GTGAGCCAGGAAGACCCCGAGGTCCAGTTCAACTGGTACGTGGATGGCGTGGAGGTG

CATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTTCAACAGCACGTACCGTGTGGTC

AGGGTCCTCACCGTCCTGCACCAGGACTGGCTGAACGGTAAGGAGTACAAGTGCAAG

GTCTCCAACAAAGGCCTCCCGTCCTCCATCGAGAAAACCATCTCCAAAGCCAAAGGG

CAGCCCCGAGAGCCACAGGTGTACACCCTGCCCCCATCCCAGGAGGAGATGACCAAG

AACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTACCCCAGCGACATCGCCGTG

GAGTGGGAGAGCAATGGGCAGCCGGAGGACAACTACAAGACCACGCCTCCCGTGCTG

GACTCCGACGGCTCCTTCTTCCTCTACAGCAGGCTAACCGTGGACAAGAGCAGGTGG

CAGGAGGGGAATGTCTTCTCATGCTCCGTGATGCATGAGGCTCTGCACAACCACTAC

ACACAGAAGAGCCTCTCCCTGTCTCCGGGTAAA
TTCTACACAGGAGTCTATATTCTG

ATCGGAGCCGGCGCCCTCATGATGCTGGTGGGCTTCCTGGGCTGCTGCGGGGCTGTG

CAGGAGTCCCAGTGCAAAAAGAAG

AAAAAGAAGAAGAAGACAAAGTGTGTAATTATG

TAA

(SEQ ID NO: 307)

>Artificial Sequence; hPDL1-4Fc-CD9tm2-KRAS, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNER
ESKYGPPCPSCPAPEFLGGPSVFLFPPKPKDTLMISRTPEVTCVVVD

VSQEDPEVQFNWYVDGVEVHNAKTKPREEQFNSTYRVVRVLTVLHQDWLNGKEYKCK

VSNKGLPSSIEKTISKAKGQPREPQVYTLPPSQEEMTKNQVSLTCLVKGFYPSDIAV

EWESNGQPEDNYKTTPPVLDSDGSFFLYSRLTVDKSRWQEGNVESCSVMHEALHNHY

TQKSLSLSPGK
FYTGVYILIGAGALMMLVGELGCCGAVQESQC
KKKKKKKKTKCVIM

(SEQ ID NO: 308)

hPDL1-Fc-
>Artificial Sequence; hPDL1-Fc-CD9tm2, DNA

CD9tm2

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGGATCGATGACAAAACTCACACATGCCCA

CCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCAAAA

CCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTGGAC

GTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAGGTG

CATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTGGTC

AGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGCAAG

GTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAAGGG

CAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATGACCAAG

AACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCCGTG

GAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTGCTG

GACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGG

CAGCAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAACCACTAC

ACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATTTCTACACAGGAGTCTAT

ATTCTGATCGGAGCCGGCGCCCTCATGATGCTGGTGGGCTTCCTGGGCTGCTGCGGG

GCTGTGCAGGAGTCCCAGTGCGTAATTATGTAA

(SEQ ID NO: 309)

>Artificial Sequence; hPDL1-Fc-CD9tm2, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNERIDDKTHTCPPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVD

VSHEDPEVKENWYVDGVEVHNAKTKPREEQYNSTYRVVSVLTVLHQDWINGKEYKCK

VSNKALPAPIEKTISKAKGQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAV

EWESNGQPENNYKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHY

TQKSLSLSPGKIDFYTGVYILIGAGALMMLVGELGCCGAVQESQCVIM

(SEQ ID NO: 310)

hPDL1-Fc-
>Artificial Sequence; hPDL1-Fc-CD9tm2-KRAS, DNA

CD9tm2-

ATGAGGATATTTGCTGTCTTTATATTCATGACCTACTGGCATTTGCTGAACGCATTT

modified KRAS

ACTGTCACGGTTCCCAAGGACCTATATGTGGTAGAGTATGGTAGCAATATGACAATT

GAATGCAAATTCCCAGTAGAAAAACAATTAGACCTGGCTGCACTAATTGTCTATTGG

GAAATGGAGGATAAGAACATTATTCAATTTGTGCATGGAGAGGAAGACCTGAAGGTT

CAGCATAGTAGCTACAGACAGAGGGCCCGGCTGTTGAAGGACCAGCTCTCCCTGGGA

AATGCTGCACTTCAGATCACAGATGTGAAATTGCAGGATGCAGGGGTGTACCGCTGC

ATGATCAGCTATGGTGGTGCCGACTACAAGCGAATTACTGTGAAAGTCAATGCCCCA

TACAACAAAATCAACCAAAGAATTTTGGTTGTGGATCCAGTCACCTCTGAACATGAA

CTGACATGTCAGGCTGAGGGCTACCCCAAGGCCGAAGTCATCTGGACAAGCAGTGAC

CATCAAGTCCTGAGTGGTAAGACCACCACCACCAATTCCAAGAGAGAGGAGAAGCTT

TTCAATGTGACCAGCACACTGAGAATCAACACAACAACTAATGAGATTTTCTACTGC

ACTTTTAGGAGATTAGATCCTGAGGAAAACCATACAGCTGAATTGGTCATCCCAGAA

CTACCTCTGGCACATCCTCCAAATGAAAGGATCGATGACAAAACTCACACATGCCCA

CCGTGCCCAGCACCTGAACTCCTGGGGGGACCGTCAGTCTTCCTCTTCCCCCCAAAA

CCCAAGGACACCCTCATGATCTCCCGGACCCCTGAGGTCACATGCGTGGTGGTGGAC

GTGAGCCACGAAGACCCTGAGGTCAAGTTCAACTGGTACGTGGACGGCGTGGAGGTG

CATAATGCCAAGACAAAGCCGCGGGAGGAGCAGTACAACAGCACGTACCGTGTGGTC

AGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAATGGCAAGGAGTACAAGTGCAAG

GTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAAGGG

CAGCCCCGAGAACCACAGGTGTACACCCTGCCCCCATCCCGGGAGGAGATGACCAAG

AACCAGGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTATCCCAGCGACATCGCCGTG

GAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAAGACCACGCCTCCCGTGCTG

GACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGG

CAGCAGGGGAACGTCTTCTCATGCTCCGTGATGCACGAGGCTCTGCACAACCACTAC

ACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAAATCGATTTCTACACAGGAGTCTAT

ATTCTGATCGGAGCCGGCGCCCTCATGATGCTGGTGGGCTTCCTGGGCTGCTGCGGG

GCTGTGCAGGAGTCCCAGTGCAAAAAGAAG

AAAAAGAAGAAGAAGACAAAGTGTGTA

ATTATGTAA

(SEQ ID NO: 311)

>Artificial Sequence; hPDL1-Fc-CD9tm2-KRAS, Amino Acid

MRIFAVFIFMTYWHLLNAFTVTVPKDLYVVEYGSNMTIECKFPVEKQLDLAALIVYW

EMEDKNIIQFVHGEEDLKVQHSSYRQRARLLKDQLSLGNAALQITDVKLQDAGVYRC

MISYGGADYKRITVKVNAPYNKINQRILVVDPVTSEHELTCQAEGYPKAEVIWTSSD

HQVLSGKTTTTNSKREEKLFNVTSTLRINTTTNEIFYCTFRRLDPEENHTAELVIPE

LPLAHPPNERIDDKTHTCPPCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVD

VSHEDPEVKENWYVDGVEVHNAKTKPREEQYNSTYRVVSVLTVLHQDWLNGKEYKCK

VSNKALPAPIEKTISKAKGQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAV

EWESNGQPENNYKTTPPVLDSDGSFFLYSKLTVDKSRWQQGNVFSCSVMHEALHNHY

TQKSLSLSPGKIDFYTGVYILIGAGALMMLVGFLGCCGAVQESQCKKKKKKKKTKCV

IM

(SEQ ID NO: 312)

mPDL1-mFc-
>Artificial Sequence; mPDL1-mFc-CD9tm2, DNA

CD9tm2

ATGAGGATATTTGCTGGCATTATATTCACAGCCTGCTGTCACTTGCTACGGGCGTTT

ACTATCACGGCTCCAAAGGACTTGTACGTGGTGGAGTATGGCAGCAACGTCACGATG

GAGTGCAGATTCCCTGTAGAACGGGAGCTGGACCTGCTTGCGTTAGTGGTGTACTGG

GAAAAGGAAGATGAGCAAGTGATTCAGTTTGTGGCAGGAGAGGAGGACCTTAAGCCT

CAGCACAGCAACTTCAGGGGGAGAGCCTCGCTGCCAAAGGACCAGCTTTTGAAGGGA

AATGCTGCCCTTCAGATCACAGACGTCAAGCTGCAGGACGCAGGCGTTTACTGCTGC

ATAATCAGCTACGGTGGTGCGGACTACAAGCGAATCACGCTGAAAGTCAATGCCCCA

TACCGCAAAATCAACCAGAGAATTTCCGTGGATCCAGCCACTTCTGAGCATGAACTA

ATATGTCAGGCCGAGGGTTATCCAGAAGCTGAGGTAATCTGGACAAACAGTGACCAC

CAACCCGTGAGTGGGAAGAGAAGTGTCACCACTTCCCGGACAGAGGGGATGCTTCTC

AATGTGACCAGCAGTCTGAGGGTCAACGCCACAGCGAATGATGTTTTCTACTGTACG

TTTTGGAGATCACAGCCAGGGCAAAACCACACAGCGGAGCTGATCATCCCAGAACTG

CCTGCAACACATCCTCCACAGAACAGGACT
GGTTGTAAGCCTTGCATATGTACAGTC

CCAGAAGTATCATCTGTCTTCATCTTCCCCCCAAAGCCCAAGGATGTGCTCACCATT

ACTCTGACTCCTAAGGTCACGTGTGTTGTGGTAGACATCAGCAAGGATGATCCCGAG

GTCCAGTTCAGCTGGTTTGTAGATGATGTGGAGGTGCACACAGCTCAGACGCAACCC

CGGGAGGAGCAGTTCAACAGCACTTTCCGCTCAGTCAGTGAACTTCCCATCATGCAC

CAGGACTGGCTCAATGGCAAGGAGTTCAAATGCAGGGTCAACAGTGCAGCTTTCCCT

GCCCCCATCGAGAAAACCATCTCCAAAACCAAAGGCAGACCGAAGGCTCCACAGGTG

TACACCATTCCACCTCCCAAGGAGCAGATGGCCAAGGATAAAGTCAGTCTGACCTGC

ATGATAACAGACTTCTTCCCTGAAGACATTACTGTGGAGTGGCAGTGGAATGGGCAG

CCAGCGGAGAACTACAAGAACACTCAGCCCATCATGGACACAGATGGCTCTTACTTC

GTCTACAGCAAGCTCAATGTGCAGAAGAGCAACTGGGAGGCAGGAAATACTTTCACC

TGCTCTGTGTTACATGAGGGCCTGCACAACCACCATACTGAGAAGAGCCTCTCCCAC

TCTCCTGGTAAA
TTCTACACAGGAGTCTATATTCTGATCGGAGCCGGCGCCCTCATG

ATGCTGGTGGGCTTCCTGGGCTGCTGCGGGGCTGTGCAGGAGTCCCAGTGCGTAATT

ATGTAA

(SEQ ID NO: 313)

>Artificial Sequence; mPDL1-mFc-CD9tm2, Amino Acid

MRIFAGIIFTACCHLLRAFTITAPKDLYVVEYGSNVTMECRFPVERELDLLALVVYW

EKEDEQVIQFVAGEEDLKPQHSNFRGRASLPKDQLLKGNAALQITDVKLQDAGVYCC

IISYGGADYKRITLKVNAPYRKINQRISVDPATSEHELICQAEGYPEAEVIWINSDH

QPVSGKRSVTTSRTEGMLLNVTSSLRVNATANDVFYCTFWRSQPGQNHTAELIIPEL

PATHPPQNRT
GCKPCICTVPEVSSVFIFPPKPKDVLTITLTPKVTCVVVDISKDDPE

VQFSWFVDDVEVHTAQTQPREEQFNSTFRSVSELPIMHQDWLNGKEFKCRVNSAAFP

APIEKTISKTKGRPKAPQVYTIPPPKEQMAKDKVSLTCMITDFFPEDITVEWQWNGQ

PAENYKNTQPIMDTDGSYFVYSKLNVQKSNWEAGNTFTCSVLHEGLHNHHTEKSLSH

SPGK
FYTGVYILIGAGALMMLVGFLGCCGAVQESQCVIM

(SEQ ID NO: 314)

mPDL1-mFc-
>Artificial Sequence; mPDL1-mFc-CD9tm2-KRAS, DNA

CD9tm2-

ATGAGGATATTTGCTGGCATTATATTCACAGCCTGCTGTCACTTGCTACGGGCGTTT

modified KRAS

ACTATCACGGCTCCAAAGGACTTGTACGTGGTGGAGTATGGCAGCAACGTCACGATG

GAGTGCAGATTCCCTGTAGAACGGGAGCTGGACCTGCTTGCGTTAGTGGTGTACTGG

GAAAAGGAAGATGAGCAAGTGATTCAGTTTGTGGCAGGAGAGGAGGACCTTAAGCCT

CAGCACAGCAACTTCAGGGGGAGAGCCTCGCTGCCAAAGGACCAGCTTTTGAAGGGA

AATGCTGCCCTTCAGATCACAGACGTCAAGCTGCAGGACGCAGGCGTTTACTGCTGC

ATAATCAGCTACGGTGGTGCGGACTACAAGCGAATCACGCTGAAAGTCAATGCCCCA

TACCGCAAAATCAACCAGAGAATTTCCGTGGATCCAGCCACTTCTGAGCATGAACTA

ATATGTCAGGCCGAGGGTTATCCAGAAGCTGAGGTAATCTGGACAAACAGTGACCAC

CAACCCGTGAGTGGGAAGAGAAGTGTCACCACTTCCCGGACAGAGGGGATGCTTCTC

AATGTGACCAGCAGTCTGAGGGTCAACGCCACAGCGAATGATGTTTTCTACTGTACG

TTTTGGAGATCACAGCCAGGGCAAAACCACACAGCGGAGCTGATCATCCCAGAACTG

CCTGCAACACATCCTCCACAGAACAGGACT
GGTTGTAAGCCTTGCATATGTACAGTC

CCAGAAGTATCATCTGTCTTCATCTTCCCCCCAAAGCCCAAGGATGTGCTCACCATT

ACTCTGACTCCTAAGGTCACGTGTGTTGTGGTAGACATCAGCAAGGATGATCCCGAG

GTCCAGTTCAGCTGGTTTGTAGATGATGTGGAGGTGCACACAGCTCAGACGCAACCC

CGGGAGGAGCAGTTCAACAGCACTTTCCGCTCAGTCAGTGAACTTCCCATCATGCAC

CAGGACTGGCTCAATGGCAAGGAGTTCAAATGCAGGGTCAACAGTGCAGCTTTCCCT

GCCCCCATCGAGAAAACCATCTCCAAAACCAAAGGCAGACCGAAGGCTCCACAGGTG

TACACCATTCCACCTCCCAAGGAGCAGATGGCCAAGGATAAAGTCAGTCTGACCTGC

ATGATAACAGACTTCTTCCCTGAAGACATTACTGTGGAGTGGCAGTGGAATGGGCAG

CCAGCGGAGAACTACAAGAACACTCAGCCCATCATGGACACAGATGGCTCTTACTTC

GTCTACAGCAAGCTCAATGTGCAGAAGAGCAACTGGGAGGCAGGAAATACTTTCACC

TGCTCTGTGTTACATGAGGGCCTGCACAACCACCATACTGAGAAGAGCCTCTCCCAC

TCTCCTGGTAAATTCTACACAGGAGTCTATATTCTGATCGGAGCCGGCGCCCTCATG

ATGCTGGTGGGCTTCCTGGGCTGCTGCGGGGCTGTGCAGGAGTCCCAGTGCAAAAAG

AAGAAAAAGAAGAAGAAGACAAAGTGTGTAATTATGTAA

(SEQ ID NO: 315)

>Artificial Sequence; mPDL1-mFc-CD9tm2-KRAS, Amino Acid

MRIFAGIIFTACCHLLRAFTITAPKDLYVVEYGSNVTMECRFPVERELDLLALVVYW

EKEDEQVIQFVAGEEDLKPQHSNFRGRASLPKDQLLKGNAALQITDVKLQDAGVYCC

IISYGGADYKRITLKVNAPYRKINQRISVDPATSEHELICQAEGYPEAEVIWTNSDH

QPVSGKRSVTTSRTEGMLLNVTSSLRVNATANDVFYCTFWRSQPGQNHTAELIIPEL

PATHPPQNRT
GCKPCICTVPEVSSVFIFPPKPKDVLTITLTPKVTCVVVDISKDDPE

VQFSWFVDDVEVHTAQTQPREEQFNSTFRSVSELPIMHQDWLNGKEFKCRVNSAAFP

APIEKTISKTKGRPKAPQVYTIPPPKEQMAKDKVSLTCMITDFFPEDITVEWQWNGQ

PAENYKNTQPIMDTDGSYFVYSKLNVQKSNWEAGNTFTCSVLHEGLHNHHTEKSLSH

SPGK
FYTGVYILIGAGALMMLVGFLGCCGAVQESQCKKKKKKKKTKCVIM

(SEQ ID NO: 316)

In some embodiments of any of the aspects, the fusion polypeptides provided herein comprise two or more POI domains. The specific combinations of POI domains can be used to regulate inflammatory immune responses. Non-limiting examples of additive and synergistic combinations of POIs that can modulate inflammatory signaling pathways are provided in Table 5 (below).

TABLE 5

Exemplary POI combinations and combined

targets for modulating inflammation.

COMBINED
PUTATIVE ADDITIVE or

POIs (LIGANDS)
TARGETS
SYNERGISTIC MOA

PD-L1 or PD-L2
PD-1
Differential use of Shp

HVEM
BTLA
phosphatases. BTLA inhibits

both TCR and CD28

phosphorylation (via Shp1)

while PD-1 inhibits CD28

phosphorylation (via Shp2).

PD-L1 or PD-L2
PD-1
LAG-3 exerts differential

FGL1
LAG-3
inhibitory impacts on various

types of lymphocytes and

shows synergy with PD-1 to

inhibit immune responses.

PD-L1 or PD-L2
PD-1
PD-1 and Tim-3 have non-

CEACAM-1 or
TIM-3
redundant downstream signaling

GAL9

mechanisms.

PD-L1 or PD-L2
PD-1
Differential use of Shp

CD155
TIGIT
phosphatases. Non-redundantly

regulate T cell responses.

PD-L1 or PD-L2
PD-1
PD-1 and VISTA non-

VSIG3
VISTA
redundantly regulate T cell

responses. VISTA contains

cytosolic SH3 binding domains

for adapter proteins.

CEACAM-1 or GAL9
TIM-3
TIGIT and TIM-3 have non-

CD155
TIGIT
redundant downstream signaling

mechanisms.

PD-L1 or PD-L2
PD-1
PD-1, LAG-3 and TIM-3 have

FGL1
LAG-3
non-redundant downstream

CEACAM-1 or GAL9
TIM-3
signaling mechanisms.

Methods of Preparing Extracellular Vesicle Compositions

In another aspect, provided herein is a method of preparing an engineered extracellular vesicle provided herein. Generally, the method comprises providing a population of cells expressing a vector construct encoding one or more sticky binder (vesicle targeting domain) and one or more signaling domains (POI domain).

The EVs provided herein can be isolated and purified form any biological source, e.g., cells. The cells that produce the engineered EVs provided herein can be from any viable non-human source or organism. Usually the organism is an animal, vertebrate, or mammal. In some embodiments, the cell described herein is from a human. The cells described herein can be from any tissue isolated from an organism by methods known in the art. The scientific literature provides guidance for one of ordinary skill in the art to isolate, prepare, and culture cells as necessary for use in the compositions and methods described herein. One of skill in the art can appreciate that the cell source of the EVs may alter the cellular protein expression and the native or endogenous cargo within the EV. It is contemplated herein that this can be leveraged for therapeutic effect depending on the disease or disorder being treated.

In some embodiments, the population of cells has been altered by exposure to environmental conditions (e.g., hypoxia), small molecule addition, presence/absence of exogenous factors (e.g., growth factors, cytokines) at the time, or substantially contemporaneous with, isolating the plurality of artificial synapses in a manner altering the regulatory state of the cell. In various embodiments, the cells are HEK 293 cells, MSCs, PER.C, fibrosarcoma HT-1080 or HuH7 cell lines.

The method comprises providing a population of cells and culturing the cells in serum-free or un-concentrated conditioned medium. This includes, for example, artificial synapses secreted into media as conditioned by a population of cells in culture, further including cell lines capable of serial passaging. In certain embodiments, the cells in culture are grown to 10, 20, 30, 40, 50, 60, 70, 80, 90, or 90% or more confluency when artificial synapses (engineered EVs) are isolated.

The methods provided herein further comprise contacting the cells provided herein with a nucleic acid vector encoding the at least one fusion polypeptide provided herein. The vector can be added to the cell culture medium of the cells by methods known in the art and discussed further below.

A vector is a nucleic acid construct designed for delivery to a host cell or for transfer of genetic material between different host cells. As used herein, a vector can be viral or non-viral. The term “vector” encompasses any genetic element that is capable of replication when associated with the proper control elements and that can transfer genetic material to cells. A vector can include, but is not limited to, a cloning vector, an expression vector, a plasmid, phage, transposon, cosmid, artificial chromosome, virus, virion, etc. In some embodiments of any of the aspects, the vector is selected from the group consisting of: a plasmid, a cosmid and a viral vector.

“Expression” refers to the cellular processes involved in producing RNA and proteins and as appropriate, secreting proteins, including where applicable, but not limited to, for example, transcription, transcript processing, translation and protein folding, modification and processing. “Expression products” include RNA transcribed from a gene, and polypeptides obtained by translation of mRNA transcribed from a gene.

In some embodiments, a vector is capable of driving expression of one or more sequences in a mammalian cell; i.e., the vector is a mammalian expression vector. Examples of mammalian expression vectors include pCDM8 (Seed, 1987. Nature 329: 840) and pMT2PC (Kaufman, et al., 1987. EMIBO J. 6: 187-195). When used in mammalian cells, the expression vector's control functions are typically provided by one or more regulatory elements. For example, commonly used promoters are derived from polyoma, adenovirus 2, cytomegalovirus, simian virus 40, and others disclosed herein and known in the art. For other suitable expression systems for both prokaryotic and eukaryotic cells see, e.g., Chapters 16 and 17 of Sambrook, et al., MOLECULAR CLONING: A LABORATORY MANUAL. 2nd ed., Cold Spring Harbor Laboratory, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y., 1989.

In some embodiments, the recombinant expression vector is capable of directing expression of the exogenous fusion polypeptide nucleic acid sequence preferentially in a particular cell type (e.g., via tissue-specific regulatory elements).

Tissue-specific and inducible regulatory elements are known in the art. Non-limiting examples of suitable tissue-specific promoters include the albumin promoter (liver-specific; Pinkert, et al., 1987. Genes Dev. 1: 268-277), lymphoid-specific promoters (Calame and Eaton, 1988. Adv. hnmunol. 43: 235-275), in particular promoters of T cell receptors (Winoto and Baltimore, 1989. EMBO J. 8: 729-733) and immunoglobulins (Baneiji, et al., 1983. Cell 33: 729-740; Queen and Baltimore, 1983. Cell 33: 741-748), neuron-specific promoters (e.g., the neurofilament promoter; Byrne and Ruddle, 1989. Proc. Natl. Acad. Sci. USA 86: 5473-5477), pancreas-specific promoters (Edlund, et al., 1985. Science 230: 912-916), and mammary gland-specific promoters (e.g., milk whey promoter; U.S. Pat. No. 4,873,316 and European Application Publication No. 264,166). Developmentally-regulated promoters are also encompassed, e.g., the murine hox promoters (Kessel and Gruss, 1990. Science 249: 374-379) and the α-fetoprotein promoter (Campes and Tilghman, 1989. Genes Dev. 3: 537-546).

In some embodiments, the at least one nucleic acid sequence described herein is delivered to the cell described herein via an integrating vector. Integrating vectors have their delivered genetic material (or a copy of it) permanently incorporated into a host cell chromosome. Non-integrating vectors remain episomal which means the nucleic acid contained therein is never integrated into a host cell chromosome. Examples of integrating vectors include retroviral vectors, lentiviral vectors, hybrid adenoviral vectors, and herpes simplex viral vectors.

In some embodiments, the at least one nucleic acid sequence described herein is delivered to the cell described herein via a non-integrative vector. Non-integrative vectors include non-integrative viral vectors. Non-integrative viral vectors eliminate one of the primary risks posed by integrative retroviruses, as they do not incorporate their genome into the host DNA. One example is the Epstein Barr oriP/Nuclear Antigen-1 (“EBNA1”) vector, which is capable of limited self-replication and known to function in mammalian cells. Containing two elements from Epstein-Barr virus, oriP and EBNA1, binding of the EBNA1 protein to the virus replicon region oriP maintains a relatively long-term episomal presence of plasmids in mammalian cells. This particular feature of the oriP/EBNA1 vector makes it ideal for generation of integration-free host cells. Other non-integrative viral vectors include adenoviral vectors and the adeno-associated viral (AAV) vectors.

Another non-integrative viral vector is RNA Sendai viral vector, which can produce protein without entering the nucleus of an infected cell. The F-deficient Sendai virus vector remains in the cytoplasm of infected cells for a few passages, but is diluted out quickly and completely lost after several passages (e.g., 10 passages). This permits a self-limiting transient expression of a chosen heterologous gene or genes in a target cell. This aspect can be helpful, e.g., for the transient introduction of reprogramming factors, among other uses. As noted above, in some embodiments, the nucleic acid sequence described herein is expressed in the cells from a viral vector.

A “viral vector” includes a nucleic acid vector construct that includes at least one element of viral origin and has the capacity to be packaged into a viral vector particle. The viral vector can contain a nucleic acid encoding a polypeptide described herein in place of non-essential viral genes. The vector and/or particle can be utilized for the purpose of transferring nucleic acids into cells either in vitro or in vivo.

The nucleic acids described herein can be delivered using any transfection reagent or other physical means that facilitates entry of nucleic acids into a cell. Methods of non-viral delivery of nucleic acids include lipofection, nucleofection, microinjection, electroporation, biolistics, virosomes, liposomes, immunoliposomes, polycation or lipid:nucleic acid conjugates, naked DNA, artificial virions, and agent-enhanced uptake of DNA. Lipofection is described in e.g., U.S. Pat. Nos. 5,049,386, 4,946,787; and 4,897,355) and lipofection reagents are sold commercially (e.g., Transfectam™ and Lipofectin™) Cationic and neutral lipids that are suitable for efficient receptor-recognition lipofection of polynucleotides include those of Felgner, WO 91/17424; WO 91/16024. Delivery can be to cells (e.g., in vitro or ex vivo administration) or target tissues (e.g., in vivo administration).

The preparation of lipid:nucleic acid complexes, including targeted liposomes such as immunolipid complexes, is well known to one of skill in the art (see, e.g., Crystal, Science 270:404-410 (1995); Blaese et al., Cancer Gene Ther. 2:291-297 (1995); Behr et al., Bioconjugate Chem. 5:382-389 (1994); Remy et al., Bioconjugate Chem. 5:647-654 (1994); Gao et al., Gene Therapy 2:710-722 (1995); Ahmad et al., Cancer Res. 52:4817-4820 (1992); U.S. Pat. Nos. 4,186,183, 4,217,344, 4,235,871, 4,261,975, 4,485,054, 4,501,728, 4,774,085, 4,837,028, and 4,946,787).

An “agent that increases cellular uptake” is a molecule that facilitates transport of a molecule, e.g., nucleic acid, or peptide or polypeptide, or other molecule that does not otherwise efficiently transit the cell membrane across a lipid membrane. For example, a nucleic acid can be conjugated to a lipophilic compound (e.g., cholesterol, tocopherol, etc.), a cell penetrating peptide (CPP) (e.g., penetratin, TAT, Syn1B, etc.), or a polyamine (e.g., spermine). Further examples of agents that increase cellular uptake are disclosed, for example, in Winkler (2013). Oligonucleotide conjugates for therapeutic applications. Ther. Deliv. 4(7); 791-809. The one or more nucleic acid sequences encoding the fusion polypeptides provided herein can be delivered to the cell by any method discussed above or known in the art.

In some embodiments of any of the aspects, the vectors provided herein comprise a nucleic acid modification by methods known in the art. In some embodiments, the cell can be genetically manipulated to express one or more vectors, each encoding one or more vesicle targeting domains and/or one or more signaling domains. In certain embodiments, the population of cells has been genetically manipulated. This includes, for example, knockout (KO) or transgenic (TG) cell lines, wherein an endogenous gene has been removed and/or an exogenous introduced in a stable, persistent manner. In certain embodiments, this further includes transient knockdown of one or more genes and associated coding and non-coding transcripts within the population of cells, via any number of methods known in the art, such as introduction of dsRNA, siRNA, microRNA, etc. This further includes transient expression of one or more genes and associated coding and non-coding transcripts within the population of cells, via any number of methods known in the art, such as introduction of a vector, plasmid, artificial plasmid, replicative and/or non-replicative virus, etc.

In certain embodiments the cell population has been manipulated to knockout the expression of one or more endogenous gene sequences that encode for metalloendopeptidases. In certain embodiments the cell population has been manipulated to knockout the expression of one or more endogenous gene sequences that code for metalloproteinases. In certain embodiments the cell population has been manipulated to knockout the expression of one or more endogenous gene sequences that encode for a disintegrin and metalloproteinase (ADAM). For example, the cell population can be manipulated to knock of the expression of one or more gene sequences that encode for ADAM1, ADAM2, ADAM7, ADAM8, ADAM9, ADAM10, ADAM11, ADAM12, ADAM15, ADAM17, ADAM18, ADAM19, ADAM20, ADAM21, ADAM22, ADAM23, ADAM28, ADAM29, ADAM30, ADAM33, etc.

In certain embodiments the cell population has been manipulated to knockout the expression of one or more endogenous genes that encode for enzymes that hydrolyze the inositol phosphate linkage in proteins anchored by phosphatidylinositol glycans, thereby preventing the release of proteins attached to the plasma membrane via GPI anchors. For example, the cell population can be manipulated to knock of the expression of phosphatidylinositol-glycan-specific phospholipase D (GPLD1).

In certain embodiments, the population of cells has been genetically manipulated. This includes, for example, knock-in of an exogenous genetic sequence, wherein the exogenous genetic sequence is expressed in a stable, persistent manner. In certain embodiments the cell population has been manipulated to knock-in a recombinase recognition sequences (e.g., FRT), transgenic reporters such as antibiotic resistance genes, fluorescent or enzymatic reporter genes, etc. or the like known in the art.

In some embodiments, the method comprises a step of isolating the engineered extracellular vesicles provided herein. Particulates within the medium are removed by a series of specific centrifugation steps and the media is filtered. The general method of isolating extracellular vesicles as provided herein is depicted in FIG. 21 of the working examples. Methods of isolating and purifying the extracellular vesicles and exosomes are known in the art and further described, e.g., in Whitford W, Guterstam P. Exosome manufacturing status. Future Med Chem. 2019 May; 11(10):1225-1236. doi: 10.4155/fmc-2018-0417. PMID: 31280675, Patel D B, Santoro M, Born L J, Fisher J P, Jay S M. Towards rationally designed biomanufacturing of therapeutic extracellular vesicles: impact of the bioproduction microenvironment. Biotechnol Adv. 2018 December; 36(8):2051-2059. doi: 10.1016/j.biotechadv.2018.09.001. Epub 2018 Sep. 12. PMID: 30218694; PMCID: PMC6250573, Ng K S, Smith J A, McAteer M P, Mead B E, Ware J, Jackson F O, Carter A, Ferreira L, Bure K, Rowley J A, Reeve B, Brindley D A, Karp J M. Bioprocess decision support tool for scalable manufacture of extracellular vesicles. Biotechnol Bioeng. 2019 February; 116(2):307-319. doi: 10.1002/bit.26809. Epub 2018 Nov. 8. PMID: 30063243; PMCID: PMC6322973, Paganini C, Capasso Palmiero U, Pocsfalvi G, Touzet N, Bongiovanni A, Arosio P. Scalable Production and Isolation of Extracellular Vesicles: Available Sources and Lessons from Current Industrial Bioprocesses. Biotechnol J. 2019 October; 14(10):e1800528. doi: 10.1002/biot.201800528. Epub 2019 Jul. 8. PMID: 31140717, which are incorporated herein by reference in their entireties.

In some embodiments, isolating the plurality of engineered EVs (artificial synapses) includes precipitation, centrifugation, filtration, immuno-separation, tangential flow, liquid chromatography, and/or flow fractionation. For example, differential ultracentrifugation has become a technique wherein secreted exosomes are isolated from the supernatants of cultured cells. This approach allows for separation of exosomes from non-membranous particles, by exploiting their relatively low buoyant density. Size exclusion allows for their separation from biochemically similar, but biophysically different microvesicles, which possess larger diameters of up to 1,000 nm. Differences in floatation velocity further allows for separation of differentially sized exosomes. In general, exosome sizes will possess a diameter ranging from 30-300 nm, including sizes of 30-150 nm. Further purification may rely on specific properties of the particular exosomes of interest. This includes, for example, use of immunoadsorption with a protein of interest to select specific vesicles with exoplasmic or outward orientations.

Among current methods (differential centrifugation, discontinuous density gradients, immunoaffinity, ultrafiltration and liquid chromatography (e.g., fast protein liquid chromatography (FPLC)), differential ultracentrifugation is the most commonly used for exosome isolation. This technique utilizes increasing centrifugal force from 2000 xg to 10,000 xg to separate the medium- and larger-sized particles and cell debris from the exosome pellet at 100,000 xg. Centrifugation alone allows for significant separation/collection of exosomes from a conditioned medium, although it is insufficient to remove various protein aggregates, genetic materials, particulates from media and cell debris that are common contaminants. Enhanced specificity of exosome purification may deploy sequential centrifugation in combination with ultrafiltration, or equilibrium density gradient centrifugation in a sucrose density gradient, to provide for the greater purity of the exosome preparation (flotation density 1.1-1.2 g/ml) or application of a discrete sugar cushion in preparation.

Ultrafiltration can be used to purify exosomes without compromising their biological activity. Membranes with different pore sizes—such as 100 kDa molecular weight cut-off (MWCO) or 300 kDa MWCO and gel filtration to eliminate smaller particles—have been used to avoid the use of a nonneutral pH or non-physiological salt concentration. Currently available tangential flow filtration (TFF) systems are scalable (to >10,000 L), allowing one to not only purify, but concentrate the exosome fractions, and such approaches are less time consuming than differential centrifugation. Liquid Chromatography can also be used to purify exosomes to homogeneously sized particles and preserve their biological activity as the preparation is maintained at a physiological pH and salt concentration.

Other chemical methods have exploit differential solubility of exosomes for precipitation techniques, addition to volume-excluding polymers (e.g., polyethylene glycols (PEGs)), possibly combined additional rounds of centrifugation or filtration. For example, a precipitation reagent, ExoQuick®, can be added to conditioned cell media to quickly and rapidly precipitate a population of exosomes, although re-suspension of pellets prepared via this technique may be difficult. Flow field-flow fractionation (FlFFF) is an elution-based technique that is used to separate and characterize macromolecules (e.g., proteins) and nano- to micro-sized particles (e.g., organelles and cells) and which has been successfully applied to fractionate exosomes from culture media.

Beyond these techniques relying on general biochemical and biophysical features, focused techniques may be applied to isolated specific exosomes of interest. This includes relying on antibody immunoaffinity to recognizing certain exosome-associated antigens. Conjugation to magnetic beads, chromatography matrices, plates or microfluidic devices allows isolating of specific exosome populations of interest as may be related to their production from a parent cell of interest or associated cellular regulatory state. Other affinity-capture methods use lectins which bind to specific saccharide residues on the exosome surface.

In several embodiments, isolating a plurality of artificial synapses from the population of cells includes centrifugation of the cells and/or media conditioned by the cells. In several embodiments, ultracentrifugation is used. In several embodiments, isolating a plurality of artificial synapses from the population of cells is via size-exclusion filtration. In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of discontinuous density gradients, immunoaffinity, ultrafiltration, tangential flow and/or liquid chromatography.

In certain embodiments, differential ultracentrifugation includes using centrifugal force from 1000-2000 xg, 2000-3000 xg, 3000-4000 xg, 4000-5000 xg, 5000 xg-6000 xg, 6000-7000 xg, 7000-8000 xg, 8000-9000 xg, 9000-10,000 xg, to 10,000 xg or more to separate larger-sized particles from a plurality of artificial synapses derived from the cells.

In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of filtration or ultrafiltration. In certain embodiments, a size exclusion membrane with different pore sizes is used. For example, a size exclusion membrane can include use of a filter with a pore size of 0.1-0.5 micron (μm), 0.5-1.0 μm, 1-2.5 μm, 2.5-5 μm, 5 or more μm. In certain embodiments, the pore size is about 0.2 μm. In certain embodiments, filtration or ultrafiltration includes size exclusion ranging from 100-500 daltons (Da), 500-1 kDa, 1-2 kDa, 2-5 kDa, 5-10 kDa, 10-25 kDa, 25-50 kDa, 50-100 kDa, 100-250 kDa, 250-500 kDa, 500 or more kDa. In certain embodiments, the size exclusion is for about 2-5 kDa. In certain embodiments, the size exclusion is for about 3 kDa. In other embodiments, filtration or ultrafiltration includes size exclusion includes use of hollow fiber membranes capable of isolating particles ranging from 100-500 daltons (Da), 500-1 kDa, 1-2 kDa, 2-5 kDa, 5-10 kDa, 10-25 kDa, 25-50 kDa, 50-100 kDa, 100-250 kDa, 250-500 kDa, 500 or more kDa. In certain embodiments, the size exclusion is for about 2-5 kDa. In certain embodiments, the size exclusion is for about 3 kDa. In other embodiments, a molecular weight cut-off (MWCO) gel filtration capable of isolating particles ranging from 100-500 daltons (Da), 500-1 kDa, 1-2 kDa, 2-5 kDa, 5-10 kDa, 10-25 kDa, 25-50 kDa, 50-100 kDa, 100-250 kDa, 250-500 kDa, 500 or more kDa. In certain embodiments, the size exclusion is for about 2-5 kDa. In certain embodiments, the size exclusion is for about 3 kDa. In various embodiments, such systems are used in combination with variable fluid flow systems. In certain embodiments, a size exclusion membrane with different pore sizes is used to purify extracellular vesicles from a solution comprising undesirable proteins or nucleic acids.

In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of tangential flow filtration (TFF) systems are used purify and/or concentrate the exosome fractions. In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of liquid chromatography can also be used to purify artificial synapses to homogeneously sized particles. In various embodiments, density gradients as used, such as centrifugation in a sucrose density gradient or application of a discrete sugar cushion in preparation.

In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of a precipitation reagent. For example, a precipitation reagent, ExoQuick®, can be added to conditioned cell media to quickly and rapidly precipitate a population of artificial synapses. In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of volume-excluding polymers (e.g., polyethylene glycols (PEGs)) are used. In another embodiment, isolating a plurality of artificial synapses from the population of cells includes use of flow field-flow fractionation (FlFFF), an elution-based technique.

In certain embodiments, isolating a plurality of artificial synapses from the population of cells includes use of one or more capture agents to isolate one or more artificial synapses possessing specific biomarkers or containing particular biological molecules. In one embodiment, one or more capture agents include at least one antibody. For example, antibody immunoaffinity recognizing exosome-associated antigens is used to capture specific artificial synapses. In other embodiments, the at least one antibody are conjugated to a fixed surface, such as magnetic beads, chromatography matrices, plates or microfluidic devices, thereby allowing isolation of the specific exosome populations of interest. In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of one or more capture agents that is not an antibody. This includes, for example, use of a “bait” molecule presenting an antigenic feature complementary to a corresponding molecule of interest on the exosome surface, such as a receptor or other coupling molecule. In one embodiment, the non-antibody capture agent is a lectin capable of binding to polysaccharide residues on the exosome surface.

In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of ion exchange chromatography. In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of anion exchange chromatography. In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of caion exchange chromatography. In certain embodiments, ion exchange chromatography comprises a chromatography resin with a functional group selected from the group consisting of diethylaminoethyl (DEAE), quaternary aminoethyl (QAE), quaternary ammonium (Q), carboxymethyl (CM), sulfopropyl (SP), or methyl sulfate (S). In certain embodiments, ion exchange chromatography comprises a chromatography resin which may have properties of a weak acid, strong acid, weak base, or strong basic. In certain embodiments, ion exchange chromatography comprises a chromatography selected from the group consisting of DEAE cellulose, DEAE Sephadex, Mono Q, Mini Q, HiTrap Capto, Capto Core 700, HiPrep Q, QAE Sephadex, Q Sepharose, CM Cellulose, SP Sepharose, SOURCE S, EAH-Sepharose, sulfoxyethyl cellulose, CM Sephadex, or CM Sepharose. Isolating a plurality of artificial synapses can be prepared by any of a variety of ion exchange chromatography techniques that are known in the art.

In other embodiments, isolating a plurality of artificial synapses from the population of cells includes use of a nuclease enzyme (e.g., a DNase or RNase). For example, a working concentration of Benzonase® nuclease may be added to an extracellular vesicle sample preparation in the presence of a divalent cation, for example 1-2 mM Mg2⁺, 2-5 mM Mg2⁺, 10-20 mM Mg2⁺, 20-50 mM Mg2⁺, 50-100 mM Mg2⁺, or more than 100 mM Mg2⁺.

Following isolation and purification of the engineered EVs provided herein, EVs can be further evaluated for the desired structural and functional properties by methods known in the art. For example, the engineered exosomes provided herein can be assayed for functional activity on a target cell using a cell-based bioassays (e.g., those commercially available, Promega DiscoverX®), ligand-receptor binding assays, vesicle flow cytometric assays, enzyme-linked immunosorbent assays, tunable resistive pulse sensing (TRPS), nanoparticle tracking analysis (NTA), surface plasmon resonance (SSPR), nucleotide sequencing, lipidomics, proteomics, colorimetric assays, fluorescence assays, luminescence assays, immunoblotting, radioimmunoassays, electron microscopy, or EV automated analysis (e.g., Exoview®). Additional methods of characterizing EVs are found, e.g., in Zhang Y, Bi J, Huang J, Tang Y, Du S, Li P. Exosome: A Review of Its Classification, Isolation Techniques, Storage, Diagnostic and Targeted Therapy Applications. Int J Nanomedicine. 2020 Sep. 22; 15:6917-6934. doi: 10.2147/IJN.S264498. PMID: 33061359; PMCID: PMC7519827, Kluszczyńska K, Czernek L, Cypryk W, Peçzek Ł, Düchler M. Methods for the Determination of the Purity of Exosomes. Curr Pharm Des. 2019; 25(42):4464-4485. doi: 10.2174/1381612825666191206162712. PMID: 31808383, Nolan J P, Duggan E. Analysis of Individual Extracellular Vesicles by Flow Cytometry. Methods Mol Biol. 2018; 1678:79-92. doi: 10.1007/978-1-4939-7346-0_5. PMID: 29071676.; Doyle L M, Wang M Z. Overview of Extracellular Vesicles, Their Origin, Composition, Purpose, and Methods for Exosome Isolation and Analysis. Cells. 2019 Jul. 15; 8(7):727. doi: 10.3390/cells8070727. PMID: 31311206; PMCID: PMC6678302, Pugholm L H, Revenfeld A L, Søndergaard EK, Jørgensen MM. Antibody-Based Assays for Phenotyping of Extracellular Vesicles. Biomed Res Int. 2015; 2015:524817. doi: 10.1155/2015/524817. Epub 2015 Dec. 3. PMID: 26770974; PMCID: PMC4681819, Shao H, Im H, Castro C M, Breakefield X, Weissleder R, Lee H. New Technologies for Analysis of Extracellular Vesicles. Chem Rev. 2018 Feb. 28; 118(4):1917-1950. doi: 10.1021/acs.chemrev.7b00534. Epub 2018 Jan. 31. PMID: 29384376; PMCID: PMC6029891, which are incorporated herein by reference in their entireties.

Pharmaceutical Compositions

Provided herein are compositions comprising the engineered extracellular vesicles (artificial synapses) provided herein.

In one aspect, provided herein is a composition comprising: a plurality of the engineered extracellular vesicles provided herein. In some embodiments of any of the aspects, the compositions and engineered EVs provided herein further comprise a pharmaceutically acceptable carrier.

For clinical use of the methods and compositions described herein, administration of the engineered EVs/artificial synapses provided herein can include formulation into pharmaceutical compositions or pharmaceutical formulations for parenteral administration, e.g., intravenous; mucosal, e.g., intranasal; ocular, or other mode of administration. In some embodiments, the engineered EVs described herein can be administered along with any pharmaceutically acceptable carrier compound, material, or composition which results in an effective treatment in the subject. Thus, a pharmaceutical formulation for use in the methods described herein can contain the engineered EVs described herein in combination with one or more pharmaceutically acceptable ingredients. The phrase “pharmaceutically acceptable” refers to those compounds, materials, compositions, and/or dosage forms which are, within the scope of sound medical judgment, suitable for use in contact with the tissues of human beings and animals without excessive toxicity, irritation, allergic response, or other problem or complication, commensurate with a reasonable benefit/risk ratio. The phrase “pharmaceutically acceptable carrier” as used herein means a pharmaceutically acceptable material, composition or vehicle, such as a liquid or solid filler, diluent, excipient, solvent, media, encapsulating material, manufacturing aid (e.g., lubricant, talc magnesium, calcium or zinc stearate, or steric acid), or solvent encapsulating material, involved in maintaining the stability, solubility, or activity of, an engineered EV as described herein. Each carrier must be “acceptable” in the sense of being compatible with the other ingredients of the formulation and not injurious to the patient. The terms “excipient,” “carrier,” “pharmaceutically acceptable carrier” or the like are used interchangeably herein.

The engineered EVs provided herein can be formulated for administration of the compound to a subject in solid, liquid, or gel form, including those adapted for the following: (1) parenteral administration, for example, by subcutaneous, intramuscular, intravenous or epidural injection as, for example, a sterile solution or suspension, or sustained-release formulation; (2) transdermally; (3) transmucosally; (4) via bronchoalveolar lavage.

In some embodiments, the compositions described herein comprise a particle or polymer-based vehicle. Exemplary particle or polymer-based vehicles include, but are not limited to, nanoparticles, microparticles, polymer microspheres, or polymer-drug conjugates.

In one embodiment of any of the aspects, the compositions described herein further comprise a lipid vehicle. Exemplary lipid vehicles include, but are not limited to, liposomes, phospholipids, micelles, lipid emulsions, and lipid-drug complexes.

Formulations can be adapted for delivery to the airway, e.g., to address respiratory infection. Such formulations can be adapted for delivery as an aerosol, e.g., for inhalation. In some embodiments, the compositions described herein are formulated for aerosol administration, nebulizer administration, tracheal lavage administration, or for a pulmonary delivery device.

As used herein, the term “pulmonary delivery device” refers to a device used to deliver a therapeutic dose of a composition of the present invention to the respiratory system including, but not limited to, a nebulizer, metered-dose inhaler, or dry powder inhaler.

Examples of nebulizers include, but are not limited to, soft mist inhalers (for example Respimat® Boehringer Ingelheim) jet nebulizers (use compressed gas or air), ultrasonic nebulizers (produce aerosols using a piezoelectric crystal vibrating at high frequencies), and vibrating mesh nebulizers.

As used herein, the term “jet nebulizer” refers to a device that flows compressed air or gas through a composition of the present invention for aerosolization. The aerosolized composition of the present invention may be inhaled by a patient. Jet nebulizer may include, but is not limited to, jet nebulizers with a corrugated tube, jet nebulizers with a collection bag, breath enhanced jet nebulizers, breath actuated jet nebulizers, and metered-dose inhalers. Examples of jet nebulizers include, but are not limited to, Circulaire (Westmed INC, Tucson, AZ), Pari Inhalierboy (PARI, Midlothian, VA), Pari LC Plus (PARI, Midlothian, VA), NebuTech (Salter Labs, Arvin, CA), AeroEclipse (Monoghan/Trudell Medical International, London, Ontario, Canada), and Maxin MA-2 (MA-2; Clinova Medical AB, Malmo, Sweden). Examples of ultrasonic nebulizers include, but are not limited to, DeVilbiss-Pulmosonic (Somerset, PA), Omron-Microair (Omron, Kyoto, Japan), Omron NE-U17 (Omron, Kyoto, Japan), Rhone Poulenc-Rorer-Fisoneb (Sanofi, Paris, France), and Beurer Nebulizer IH30 (Beurer GmbH, Neu-Ulm, Germany).

As used herein, the term “mesh nebulizer” refers to forcing a liquid, gel, fluid, solution, tincture, or the like through apertures in a mesh or aperture plate to generate aerosol. Mesh nebulizer may include, but is not limited to, active mesh nebulizers and passive mesh nebulizers. Examples of active mesh nebulizers include, but is not limited to, Aeroneb® (Aerogen, Galway, Ireland) and eFlow® (PARI, Midlothian, VA). Examples of passive mesh nebulizers are, but not limited to, I-neb (Philips Respironics, Newark, USA), AKITA (Activaero, Gemunden/Wohra, Germany), and Microair NE-U22® (Omron, Kyoto, Japan).

For use as aerosols, the compositions described herein can be prepared in a solution or suspension and may be packaged in a pressurized aerosol container together with suitable propellants, for example, hydrocarbon propellants like propane, butane, or isobutane with conventional excipients.

The engineered EVs provided herein can also be administered in a non-pressurized form such as in a nebulizer or atomizer that reduces a liquid to a fine spray. Preferably, by such nebulization small liquid droplets of uniform size are produced from a larger body of liquid in a controlled manner. Nebulization can be achieved by any suitable means therefor, including by using many nebulizers known and marketed today. For example, an AEROMIST™ pneumatic nebulizer available from Inhalation Plastic, Inc. of Niles, Ill.

When the active ingredients are adapted to be administered, either together or individually, via nebulizer(s) they can be in the form of a nebulized aqueous suspension or solution, with or without a suitable pH or tonicity adjustment, either as a unit dose or multi-dose device.

Furthermore, any suitable gas can be used to apply pressure during the nebulization, with preferred gases to date being those which are chemically inert. Exemplary gases including, but are not limited to, nitrogen, argon, or helium can be used to advantage.

In some embodiments, the compositions described herein can also be administered directly to the airways in the form of a dry powder. Thus, the engineered EVs can be administered via an inhaler. Exemplary inhalers include metered dose inhalers and dry powdered inhalers.

A metered dose inhaler or “MDI” is a pressure resistant canister or container filled with a product such as a pharmaceutical composition dissolved in a liquefied propellant or micronized particles suspended in a liquefied propellant. The propellants which can be used include chlorofluorocarbons, hydrocarbons or hydrofluoroalkanes. Commonly used propellants are P134a (tetrafluoroethane) and P227 (heptafluoropropane) each of which may be used alone or in combination. They are optionally used in combination with one or more other propellants and/or one or more surfactants and/or one or more other excipients, for example ethanol, a lubricant, an anti-oxidant and/or a stabilizing agent.

As used herein, the term “dry powder inhaler” refers to a device that delivers a therapeutic dose of a composition of the present invention in a powdered form without propellants to the respiratory system. A dry powder inhaler (i.e., Turbuhaler™ (Astra AB)) is a system operable with a source of pressurized air to produce dry powder particles of a pharmaceutical composition that is compacted into a very small volume. Examples of dry powder inhalers include, but are not limited to, Spinhaler® (Fisons Pharmaceuticals, Rochester, NY), Rotahaler® (GlaxoSmithKline, NC), Turbuhaler® (AstraZeneca, UK), and Diskhaler® (GlaxoSmithKline, NC).

Dry powder aerosols for inhalation therapy are generally produced with mean diameters primarily in the range of <5 μm. As the diameter of particles exceeds 3 μm, there is increasingly less phagocytosis by macrophages. However, increasing the particle size also has been found to minimize the probability of particles (possessing standard mass density) entering the airways and acini due to excessive deposition in the oropharyngeal or nasal regions.

Suitable powder compositions include, by way of illustration, powdered preparations including the engineered EVs described herein. These can be intermixed with lactose, or other inert powders acceptable for intrabronchial administration. The powder compositions can be administered via an aerosol dispenser or encased in a breakable capsule which may be inserted by the patient or clinician into a device that punctures the capsule and blows the powder out in a steady stream suitable for inhalation. The compositions can include propellants, surfactants, and co-solvents and may be filled into conventional aerosol containers that are closed by a suitable metering valve.

Aerosols for the delivery to the respiratory tract are described, for example, by Adjei, A. and Garren, J. Pharm. Res., 1: 565-569 (1990); Zanen, P. and Lamm, J.-W. J. Int. J. Pharm., 114: 111-115 (1995); Gonda, I. “Aerosols for delivery of therapeutic and diagnostic agents to the respiratory tract,” in Critical Reviews in Therapeutic Drug Carrier Systems, 6:273-313 (1990); Anderson et al., Am. Rev. Respir. Dis., 140: 1317-1324 (1989)) and have potential for the systemic delivery of peptides and proteins as well (Patton and Platz, Advanced Drug Delivery Reviews, 8:179-196 (1992)); Timsina et. al., Int. J. Pharm., 101: 1-13 (1995); and Tansey, I. P., Spray Technol. Market, 4:26-29 (1994); French, D. L., Edwards, D. A. and Niven, R. W., Aerosol Sci., 27: 769-783 (1996); Visser, J., Powder Technology 58: 1-10 (1989)); Rudt, S. and R. H. Muller, J. Controlled Release, 22: 263-272 (1992); Tabata, Y, and Y. Ikada, Biomed. Mater. Res., 22: 837-858 (1988); Wall, D. A., Drug Delivery, 2: 10 1-20 1995); Patton, J. and Platz, R., Adv. Drug Del. Rev., 8: 179-196 (1992); Bryon, P., Adv. Drug. Del. Rev., 5: 107-132 (1990); Patton, J. S., et al., Controlled Release, 28: 15 79-85 (1994); Damms, B. and Bains, W., Nature Biotechnology (1996); Niven, R. W., et al., Pharm. Res., 12(9); 1343-1349 (1995); and Kobayashi, S., et al., Pharm. Res., 13(1): 80-83 (1996), the contents of each of which are incorporated herein by reference in their entirety.

Microemulsification technology can improve bioavailability of some lipophilic (water insoluble) pharmaceutical agents. Examples include Trimetrine (Dordunoo, S. K., et al., Drug Development and Industrial Pharmacy, 17(12), 1685-1713, 1991 and REV 5901 (Sheen, P. C., et al., J Pharm Sci 80(7), 712-714, 1991). Among other things, microemulsification provides enhanced bioavailability by preferentially directing absorption to the lymphatic system instead of the circulatory system, which thereby bypasses the liver, and prevents destruction of the cell-based compositions in the hepatobiliary circulation.

The engineered EVs described herein can be formulated with an amphiphilic carrier. Amphiphilic carriers are saturated and monounsaturated polyethyleneglycolyzed fatty acid glycerides, such as those obtained from fully or partially hydrogenated various vegetable oils. Such oils may advantageously consist of tri-, di-, and mono-fatty acid glycerides and di- and mono-polyethyleneglycol esters of the corresponding fatty acids, with a particularly preferred fatty acid composition including capric acid 4-10, capric acid 3-9, lauric acid 40-50, myristic acid 14-24, palmitic acid 4-14 and stearic acid 5-15%. Another useful class of amphiphilic carriers includes partially esterified sorbitan and/or sorbitol, with saturated or mono-unsaturated fatty acids (SPAN-series) or corresponding ethoxylated analogs (TWEEN-series).

Commercially available amphiphilic carriers are particularly contemplated, including Gelucire-series, Labrafil, Labrasol, or Lauroglycol (all manufactured and distributed by Gattefosse Corporation, Saint Priest, France), PEG-mono-oleate, PEG-di-oleate, PEG-mono-laurate and di-laurate, Lecithin, Polysorbate 80, etc. (produced and distributed by a number of companies in USA and worldwide).

The engineered EV compositions provided herein can be formulated with hydrophilic polymers. Hydrophilic polymers are water-soluble, can be covalently attached to a vesicle-forming lipid, and which are tolerated in vivo without toxic effects (i.e., are biocompatible). Suitable polymers include polyethylene glycol (PEG), polylactic (also termed polylactide), polyglycolic acid (also termed polyglycolide), a polylactic-polyglycolic acid copolymer, and polyvinyl alcohol. Other hydrophilic polymers which may be suitable include polyvinylpyrrolidone, polymethoxazoline, polyethyloxazoline, polyhydroxypropyl methacrylamide, polymethacrylamide, polydimethylacrylamide, and derivatized celluloses such as hydroxymethylcellulose or hydroxyethylcellulose.

In certain embodiments, a pharmaceutical composition as described herein comprises a biocompatible polymer selected from the group consisting of polyamides, polycarbonates, polyalkylenes, polymers of acrylic and methacrylic esters, polyvinyl polymers, polyglycolides, polysiloxanes, polyurethanes and co-polymers thereof, celluloses, polypropylene, polyethylenes, polystyrene, polymers of lactic acid and glycolic acid, polyanhydrides, poly(ortho)esters, poly(butic acid), poly(valeric acid), poly(lactide-co-caprolactone), polysaccharides, proteins, polyhyaluronic acids, polycyanoacrylates, and blends, mixtures, or copolymers thereof.

In certain embodiments, a pharmaceutical composition described herein is formulated as a liposome. Liposomes can be prepared by any of a variety of techniques that are known in the art. See, e.g., U.S. Pat. No. 4,235,871; Published PCT applications WO 96/14057; New RRC, Liposomes: A practical approach, IRL Press, Oxford (1990), pages 33-104; Lasic D D, Liposomes from physics to applications, Elsevier Science Publishers BV, Amsterdam, 1993.

Therapeutic formulations of the engineered EV compositions as described herein can be prepared for storage by with optional pharmaceutically acceptable carriers, excipients or stabilizers (Remington's Pharmaceutical Sciences 16th edition, Osol, A. Ed. (1980)), in the form of lyophilized formulations or aqueous solutions. Acceptable carriers, excipients, or stabilizers are nontoxic to recipients at the dosages and concentrations employed, and include buffers such as phosphate, citrate, and other organic acids; antioxidants including ascorbic acid and methionine; preservatives (such as octadecyldimethylbenzyl ammonium chloride; hexamethonium chloride; benzalkonium chloride, benzethonium chloride; phenol, butyl or benzyl alcohol; alkyl parabens such as methyl or propyl paraben; catechol; resorcinol; cyclohexanol; 3-pentanol; and m-cresol); low molecular weight (less than about 10 residues) polypeptides; proteins, such as serum albumin, gelatin, or immunoglobulins; hydrophilic polymers such as polyvinylpyrrolidone; amino acids such as glycine, glutamine, asparagine, histidine, arginine, or lysine; monosaccharides, disaccharides, and other carbohydrates including glucose, mannose, or dextrins; chelating agents such as EDTA; sugars such as sucrose, mannitol, trehalose or sorbitol; salt-forming counter-ions such as sodium; metal complexes (e.g., Zn-protein complexes); and/or non-ionic surfactants such as TWEEN™, PLURONICS™ or polyethylene glycol (PEG).

Vaccine or other pharmaceutical compositions comprising an engineered EV composition as described herein can contain a pharmaceutically acceptable salt, typically, e.g., sodium chloride, and preferably at about physiological concentrations. The formulations of the vaccine or other pharmaceutical compositions described herein can contain a pharmaceutically acceptable preservative. In some embodiments, the preservative concentration ranges from 0.1 to 2.0%, typically v/v. Suitable preservatives include those known in the pharmaceutical arts. Benzyl alcohol, phenol, m-cresol, methylparaben, and propylparaben are examples of preservatives. The formulations of the vaccine or other pharmaceutical compositions described herein can include a pharmaceutically acceptable surfactant at a concentration of 0.005 to 0.02%.

Therapeutic pharmaceutical compositions described herein can also contain more than one active compound as necessary for the particular indication being treated, preferably those with complementary activities that do not adversely affect each other.

In some embodiments in which the engineered EVs are formulated for use in or with a vaccine, the vaccine composition can be formulated with the engineered EVs as an adjuvant. In other embodiments the vaccine composition can be formulated with the engineered EVs and an additional adjuvant, e.g., as known in the art.

As used herein in the context of immunization, immune response and vaccination, the term “adjuvant” refers to any substance than when used in combination with a specific antigen produces a more robust immune response than the antigen alone. When incorporated into a vaccine formulation, an adjuvant acts generally to accelerate, prolong, or enhance the quality of specific immune responses to the vaccine antigen(s). Adjuvants typically promote the accumulation and/or activation of accessory cells or factors to enhance antigen-specific immune responses and thereby enhance the efficacy of vaccines, i.e., antigen-containing or encoding compositions used to induce protective immunity against the antigen.

Adjuvants, in general, include adjuvants that create a depot effect, immune-stimulating adjuvants, and adjuvants that create a depot effect and stimulate the immune system. An adjuvant that creates a depot effect is an adjuvant that causes the antigen to be slowly released in the body, thus prolonging the exposure of immune cells to the antigen. This class of adjuvants includes but is not limited to alum (e.g., aluminum hydroxide, aluminum phosphate); emulsion-based formulations including mineral oil, non-mineral oil, water-in-oil or oil-in-water-in oil emulsion, oil-in-water emulsions such as Seppic ISA series of Montanide adjuvants (e.g., Montanide ISA 720; AirLiquide, Paris, France); MF-59 (a squalene-in-water emulsion stabilized with Span 85 and Tween 80; Chiron Corporation, Emeryville, Calif.); and PROVAX™ (an oil-in-water emulsion containing a stabilizing detergent and a micelle-forming agent; IDEC Pharmaceuticals Corporation, San Diego, Calif).

An immune-stimulating adjuvant is an adjuvant that causes activation of a cell of the immune system. It may, for instance, cause an immune cell to produce and secrete cytokines and interferons. This class of adjuvants includes but is not limited to saponins purified from the bark of the Q. saponaria tree, such as QS21 (a glycolipid that elutes in the 21st peak with HPLC fractionation; Aquila Biopharmaceuticals, Inc., Worcester, Mass.); poly[di(carboxylatophenoxy)phosphazene (PCPP polymer; Virus Research Institute, USA); derivatives of lipopolysaccharides such as monophosphoryl lipid A (MPL; Ribi ImmunoChem Research, Inc., Hamilton, Mont.), muramyl dipeptide (MDP; Ribi) and threonyl-muramyl dipeptide (t-MDP; Ribi); OM-174 (a glucosamine disaccharide related to lipid A; OM Pharma SA, Meyrin, Switzerland); and Leishmania elongation factor (a purified Leishmania protein; Corixa Corporation, Seattle, Wash.). This class of adjuvants also includes CpG DNA.

Adjuvants that create a depot effect and stimulate the immune system are those compounds which have both of the above-identified functions. This class of adjuvants includes but is not limited to ISCOMS (immunostimulating complexes which contain mixed saponins, lipids and form virus-sized particles with pores that can hold antigen; CSL, Melbourne, Australia); SB-AS2 (SmithKline Beecham adjuvant system #2 which is an oil-in-water emulsion containing MPL and QS21: SmithKline Beecham Biologicals [SBB], Rixensart, Belgium); SB-AS4 (SmithKline Beecham adjuvant system #4 which contains alum and MPL; SBB, Belgium); non-ionic block copolymers that form micelles such as CRL 1005 (these contain a linear chain of hydrophobic polyoxypropylene flanked by chains of polyoxyethylene; Vaxcel, Inc., Norcross, Ga.); and Syntex Adjuvant Formulation (SAF, an oil-in-water emulsion containing Tween 80 and a nonionic block copolymer; Syntex Chemicals, Inc., Boulder, Colo.).

The active ingredients of the pharmaceutical compositions described herein can also be entrapped in microcapsules prepared, for example, by coacervation techniques or by interfacial polymerization, for example, hydroxymethylcellulose or gelatin-microcapsules and poly-(methylmethacylate) microcapsules, respectively, in colloidal drug delivery systems (for example, liposomes, albumin microspheres, microemulsions, nano-particles and nanocapsules) or in macroemulsions. Such techniques are disclosed in Remington's Pharmaceutical Sciences 16th edition, Osol, A. Ed. (1980).

In some embodiments, sustained-release preparations can be used. Suitable examples of sustained-release preparations include semipermeable matrices of solid hydrophobic polymers containing a composition described herein in which the matrices are in the form of shaped articles, e.g., films, or microcapsule. Examples of sustained-release matrices include polyesters, hydrogels (for example, poly(2-hydroxyethyl-methacrylate), or poly(vinylalcohol)), polylactides (U.S. Pat. No. 3,773,919), copolymers of L-glutamic acid and y ethyl-L-glutamate, non-degradable ethylene-vinyl acetate, degradable lactic acid-glycolic acid copolymers such as the LUPRON DEPOT™ (injectable microspheres composed of lactic acid-glycolic acid copolymer and leuprolide acetate), and poly-D-(−)-3-hydroxybutyric acid. While polymers such as ethylene-vinyl acetate and lactic acid-glycolic acid enable release of molecules for over 100 days, certain hydrogels release proteins for shorter time periods. When encapsulated, the composition can remain in the body for a long time (e.g., up to about 1 hour, between 1-12 hours, 12-24 hours, 24 hours to 2 days, 2-3 days, 3-4 days, 4-5 days, 5-6 days, 6-7 days, 1-2 weeks, 3-4 weeks, 4 weeks to 2 months, 2-3 months, 3-4 months, 4-5 months, 5-6 months, or more than 6 months, or a variation thereof), denature, or aggregate as a result of exposure to moisture at 37° C., resulting in a loss of biological activity and possible changes in immunogenicity. Rational strategies can be devised for stabilization depending on the mechanism involved. For example, if the aggregation mechanism is discovered to be intermolecular S—S— bond formation through thio-disulfide interchange, stabilization can be achieved by modifying sulfhydryl residues, lyophilizing from acidic solutions, controlling moisture content, using appropriate additives, and developing specific polymer matrix compositions.

Administration, Dosing, Efficacy

The engineered EV compositions, pharmaceutical compositions, or vaccine compositions described herein can be formulated, dosed, and administered in a fashion consistent with good medical practice. Factors for consideration in this context include the particular disorder being treated, the particular subject being treated, the clinical condition of the individual subject, the cause of the disorder, the site of delivery of the vaccine composition, the method of administration, the scheduling of administration, and other factors known to medical practitioners.

Generally, application of artificial synapses as therapy will take into account similar parameters as other therapeutic strategies, including concentration, timing of delivery, and sustained bioavailability at injury/disease site. Extracellular vesicle can be delivered via a number of routes: intravenous, intracoronary, and intramyocardial. Extracellular vesicles (e.g., exosomes), also allow for new delivery routes that were previously infeasible for cell therapy, such as inhalation or injection. These various approaches are described below, including injection, topical application, enteral administration, and pulmonary delivery.

The engineered EV compositions provided herein can be administered to a subject in need thereof by any appropriate route which results in an effective treatment in the subject. As used herein, the terms “administering,” and “introducing” are used interchangeably and refer to the placement of a composition provided herein into a subject by a method or route which results in at least partial localization of such compositions at a desired site, such as a site of inflammation or a tumor, such that a desired effect(s) is produced. The compositions can be administered to a subject by any mode of administration that delivers the composition systemically or to a desired surface or target, and can include, but is not limited to, injection, infusion, instillation, and inhalation administration. To the extent that the composition can be protected from inactivation in the gut, oral administration forms are also contemplated. “Injection” includes, without limitation, intravenous, intramuscular, intra-arterial, intrathecal, intraventricular, intracapsular, intraorbital, retro-orbital, intravitreal, intraocular, intracardiac, intradermal, intraperitoneal, transtracheal, subcutaneous, subcuticular, intraarticular, sub capsular, subarachnoid, intraspinal, intracerebral, intratarsal, and intrasternal, intratumoral injection, and infusion or the like as known in the art.

A therapeutic does of the present invention may be delivered to a patient by means of controlled release, for example but not limited to, implantable pump and implantable cannulas to provide continuous access to the venous or arterial system.

Topical application refers to applying or spreading a composition of the present invention onto surfaces on or in the body, both internally and/or externally, in a therapeutically effective amount for local and/or systemic treatment. Topical application may be epicutaneous wherein a composition of the present invention may be directly applied onto a localized surface of the skin or mucous membranes. Topical application may include transdermal application wherein a composition of the present invention may be absorbed into the body to obtain systemic delivery and systemic distribution. Topical application formulations may include, but are not limited to, creams, foams, gels, lotions, solutions, ointments, dermal patch, transdermal patches, powder, solid, sponge, tape, vapor, paste, film, liposomes, balm, shampoo, spray, or tincture or the like or a combination thereof. A therapeutic dose of a composition of the present invention may be delivered vaginally (for example a vaginal suppository, vaginal ring, douche, intrauterine device, intravesical infusion, and the like) or urethra or the like or a combination thereof.

Enteral administration refers to a composition of the present invention administered via the gastrointestinal tract in a therapeutically effective amount for local or systemic treatment. Enteral administration may include, but is not limited to, delivery of a composition of the present invention via the mouth, sublingual, esophagus, gastric (for example the stomach), small intestines, large intestines or rectum. Oral delivery of the present invention may include, but is not limited to, the use of a capsule, pastille, pill, tablet, solution, gel, suspension, emulsion, syrup, elixir, tincture, mouthwash, lozenges, chewing gum, lollipop, cream, foam, solution, powder, solid, vapor, liposomes, spray, or tincture osmotic-controlled release oral delivery system, or the like. Gastric delivery may involve the use of a tube or nasal passage that leads directly to the stomach, for example, a percutaneous endoscopic gastrostomy tube. Gastric delivery may involve direct injection made through the abdominal wall. Rectal delivery may involve, but is not limited to, the use of a suppository, ointment, enema, murphy drip, or the like. A therapeutic does of the present invention may be delivered to a patient by means of controlled release, for example but not limited to, controlled release drug delivery pellet or pill.

Inhalation (i.e., pulmonary delivery, pulmonary administration refers to delivery to the respiratory system through the respiratory route, including but not limited to, intranasal administration, oral administration, and oral inhalative administration (e.g., intratracheal instillation and intratracheal inhalation) of a therapeutically effective amount for local or systemic treatment. Pulmonary delivery of a therapeutically effective amount of a composition of the present invention may be achieved by dispersion, for example by using a syringe. Pulmonary delivery of a composition of the present invention may be achieved by aerosol administration, wherein aerosol administration may deposit a therapeutically effective amount of the present invention by gravitational sedimentation, inertial impaction, or diffusion.

Intravenous delivery technique can occur through a peripheral or central venous catheter. As the simplest delivery mode, this technique avoids the risk of an invasive procedure. However, intravenous may be regarded as a comparatively inefficient and less localized delivery method, as a high percentage of infused cell exosomes may become sequestered in organs such as the lung, liver, or spleen. Such sequestration may result in few or no cellular exosomes reaching broader circulation or have unintended systemic effects following their distribution.

In certain embodiments, administration can include delivery to a tissue or organ site that is the same as the site of diseased and/or dysfunctional tissue. In certain embodiments, administration can include delivery to a tissue or organ site that is different from the site or diseased and/or dysfunctional tissue. In certain embodiments, the delivery is via inhalation or oral administration. In various embodiments, administration of artificial synapses can include combinations of multiple delivery techniques.

In some embodiments, the compositions described herein are administered by aerosol administration, nebulizer administration, or tracheal lavage administration.

The term “effective amount” as used herein refers to the amount of an engineered EV composition needed to alleviate or prevent at least one or more symptom of a disease or disorder (e.g., autoimmune disease or cancer), and relates to a sufficient amount of pharmacological composition to provide the desired effect, e.g., reduce the pathology, or any symptom associated with or caused by the disease. The term “therapeutically effective amount” therefore refers to an amount of an engineered EV composition or vaccine composition described herein using the methods as disclosed herein, that is sufficient to affect a particular disease state when administered to a typical subject. An effective amount as used herein would also include an amount sufficient to delay the development of a symptom of the disease, alter the course of a symptom disease (for example, but not limited to, slow the progression of a symptom of the disease), or reverse a symptom of the disease. Thus, it is not possible to specify the exact “effective amount.” However, for any given case, an appropriate “effective amount” can be determined by one of ordinary skill in the art using only routine experimentation.

Effective amounts, toxicity, and therapeutic efficacy can be determined by standard pharmaceutical procedures in cell cultures or experimental animals, e.g., for determining the LD50 (the dose lethal to 50% of the population) and the ED50 (the dose therapeutically effective in 50% of the population). The dosage can vary depending upon the dosage form employed and the route of administration utilized. The dose ratio between toxic and therapeutic effects is the therapeutic index and can be expressed as the ratio LD50/ED50. Compositions and methods that exhibit large therapeutic indices are preferred. A therapeutically effective dose can be estimated initially from cell culture assays. Also, a dose can be formulated in animal models to achieve a circulating plasma concentration range that includes the IC50 (i.e., the concentration of the engineered EVs or fusion polypeptides provided herein), which achieves a half-maximal inhibition of symptoms) as determined in cell culture, or in an appropriate animal model. Levels of therapeutic engineered EVs in plasma can be measured, for example, by high performance liquid chromatography, enzyme linked immunosorbent assay (ELISA), flow cytometry, FACS sorting, western blot, mass spectroscopy, tunable resistive pulse sensing, ExoView®, qRT-PCR, next generation sequencing (NGS), or by any analysis technique known by one of ordinary skill in the art. The effects of any particular dosage can be monitored by a suitable bioassay. The dosage can be determined by a physician and adjusted, as necessary, to suit observed effects of the treatment.

The engineered EV compositions, pharmaceutical compositions, or vaccine compositions described herein can be formulated, in some embodiments, with one or more additional therapeutic agents currently used to prevent or treat the infection, for example. The effective amount of such other agents depends on the amount of an engineered EV in the formulation, the type of disorder or treatment, and other factors discussed above. These are generally used in the same dosages and with administration routes as used herein before or about from 1 to 99% of the heretofore employed dosages.

The dosage ranges for the pharmaceutical compositions described herein depend upon the potency and encompass amounts large enough to produce the desired effect. The dosage should not be so large as to cause unacceptable adverse side effects. Generally, the dosage will vary with the age, condition, health, and sex of the patient and can be determined by one of skill in the art. The dosage can also be adjusted by the individual physician in the event of any complication. In some embodiments, the dosage ranges from 0.001 mg/kg body weight to 100 mg/kg body weight. In some embodiments, the dose range is from 5 μg/kg body weight to 100 μg/kg body weight. Alternatively, the dose range can be titrated to maintain serum levels between 0.1 μg/mL and 1000 μg/mL. For systemic administration, subjects can be administered a therapeutic amount, such as, e.g., 0.1 mg/kg, 0.5 mg/kg, 1.0 mg/kg, 2.0 mg/kg, 2.5 mg/kg, 5 mg/kg, 7.5 mg/kg, 10 mg/kg, 15 mg/kg, 20 mg/kg, 25 mg/kg, 30 mg/kg, 40 mg/kg, 50 mg/kg, or more. These doses can be administered by one or more separate administrations, or by continuous infusion. For repeated administrations over several days or longer, depending on the condition, the treatment is sustained until, for example, the infection is treated, as measured by the methods described above or known in the art. However, other dosage regimens can be useful.

In various embodiments, the quantities of artificial synapses that are administered to achieve these effects range from 1×10⁶to 1×10⁷, 1×10⁷to 1×10⁸, 1×10⁸to 1×10¹⁰, 1×10¹⁰to 1×10¹⁰, 1×10¹⁰to 1×10¹¹, 1×10¹¹to 1×10¹², 1×10¹²to 1×10¹³, 1×10¹³to 1×10¹⁴, 1×10¹⁴to 1×10¹⁵, 1×10¹⁵or more EVs/artificial synapses. In other embodiments, the numbers of artificial synapses are relative to the number of cells used in a clinically relevant dose for a cell-therapy method. For example, defining an effective dose range, dosing regimen and route of administration, may be guided by studies using fluorescently labeled artificial synapses, and measuring target tissue retention, which can be >10×, >50×, or >100× background, as measured 5, 10, 15, 30, or 30 or more min as a screening criterion. In certain embodiments, >100× background measured at 30 mins is a baseline measurement for a low and high dose that is then assess for safety and bioactivity (e.g., using MRI endpoints: scar size, global and regional function of the target organ being treated). In various embodiments, single doses are compared to two, three, four, four or more sequentially-applied doses. In various embodiments, the repeated or sequentially-applied doses are provided for treatment of an acute disease and/or condition. In various embodiments, the repeated or sequentially-applied doses are provided for treatment of a chronic disease and/or condition. In other embodiments, administration of the plurality of artificial synapses is adjunctive to standard therapy.

In other embodiments, administering a composition includes 1×10¹⁰or more artificial synapses in a single dose. In various embodiments, exosome quantity may be defined by protein quantity, such as dosages including 1-10, 10-25, 25-50, 50-75, 75-100, or 100 or more mg exosome protein. In other embodiments, a single dose is administered multiple times to the subject. In other embodiments, administering a composition consists of one or more of: injection, topical administration, enteral, intravenous, intra-arterial, or inhalation.

In various embodiments, exosome quantity may be defined by protein quantity, such as dosages including 1-10, 10-25, 25-50, 50-75, 75-100, or 100 or more mg exosome protein. In various embodiments, administering a composition includes multiple dosages of the artificial synapses. In various embodiments, the repeated or sequentially-applied doses are provided for treatment of an acute disease and/or condition. In various embodiments, the repeated or sequentially-applied doses are provided for treatment of a chronic disease and/or condition.

In other embodiments, administering a composition including a plurality of artificial synapses to the subject is adjunctive to standard therapy.

The duration of a therapy using the methods described herein will continue for as long as medically indicated or until a desired therapeutic effect (e.g., those described herein) is achieved. In certain embodiments, the administration of the vaccine composition described herein is continued for 1 month, 2 months, 4 months, 6 months, 8 months, 10 months, 1 year, 2 years, 3 years, 4 years, 5 years, 10 years, 20 years, or for a period of years up to the lifetime of the subject.

As will be appreciated by one of skill in the art, appropriate dosing regimens for a given composition can comprise a single administration/immunization or multiple ones. Subsequent doses may be given repeatedly at time periods, for example, about two weeks or greater up through the entirety of a subject's life, e.g., to provide a sustained preventative effect. Subsequent doses can be spaced, for example, about two weeks, about three weeks, about four weeks, about one month, about two months, about three months, about four months, about five months, about six months, about seven months, about eight months, about nine months, about ten months, about eleven months, or about one year after a primary immunization.

The precise dose to be employed in the formulation will also depend on the route of administration and should be decided according to the judgment of the practitioner and each patient's circumstances. Ultimately, the practitioner or physician will decide the amount of the engineered EV or composition thereof to administer to particular subjects.

Methods of Modulating Inflammation and Treating Autoimmune Diseases

The artificial synapses/engineered EVs and compositions thereof provided herein can be deployed in a therapeutic strategy against virtually any injury/disease, as providing a platform for altering biological signaling. This includes, for example, inflammation and immune signaling, which plays a role in virtually all injuries and diseases in living organisms.

Thus, described herein is a method of modulating inflammation, including selecting a subject afflicted with an inflammatory related disease and/or condition; and administering to the subject a composition including a plurality of artificial synapses (engineered EVs) to the subject, wherein administration of the composition modulates inflammation.

As used herein, the term “inflammation” or “inflamed” refers to activation or recruitment of the immune system or immune cells (e.g., T cells, B cells, macrophages). A tissue that has inflammation can become reddened, white, swollen, hot, painful, sensitivity, exhibit a loss of function, or have a film or mucus. Methods of identifying inflammation are well known in the art. Inflammation typically occurs following injury, infection by a microorganism, exposure to a substance (e.g., a toxin, chemical, or dust) or autoimmune dysfunction. Onset of inflammation may be rapid (e.g., immediately following injury) or slow (e.g., repeated exposure to an irritant such as a chemical over time) with a duration of minutes, hours, days, months, years, or an individual's life.

Inflammation plays a vital role in alerting the immune system of potential danger and damage within a body. Inflammation is necessary to control and repair injury. For example, acute inflammation is a response to physical trauma, infection, and stress. Acute inflammation helps prevent further injury and triggers healing and recovery. Unfortunately, inflammation can become excessive and inappropriately active, lasting beyond the typical recovery time from an injury or infection. Wherein healthy inflammation helps a body respond to injury, chronic inflammation perpetuates injury and may lead to negative consequences to one's health. In particular, autoimmune diseases are chronic diseases from a host's immune system attacking itself, often due to aberrant biological signaling in the host. Restoring normal homeostatic signaling via application of artificial synapses, particularly targeting immune checkpoints, represents a highly promising avenue. For example, surface bound immune-checkpoint proteins or fragments thereof may modulate immune cell stimulation and affect suppression of immune cell function when delivered via artificial synapses. Injection, inhalation, ingestion or topical application of artificial synapses with surface bound immune-checkpoint proteins or fragments thereof may be used to treat immune, auto-immune, inflammatory, and auto-inflammatory conditions. Examples include chronic obstructive pulmonary disease (COPD) which is an inflammatory, progressive, life-threatening lung disease, psoriasis, a common chronic noncommunicable inflammatory skin disease, arthritis, a debilitating and painful degeneration of joints, among others well-understood to one of skill in the art.

In other embodiments, the inflammatory related disease and/or condition is acute, for example septicemia. In other embodiments, the inflammatory related disease and/or condition is chronic, for example chronic obstructive pulmonary disease. In other embodiments, the inflammatory condition is an autoimmune disease wherein the autoimmune disease and/or condition is one or more of polymyositis, dermatomyositis, Graves' disease, Hashimoto's thyroiditis, myasthenia gravis, vasculitis, multiple sclerosis, psoriasis, rheumatoid arthritis, psoriatic arthritis, scleroderma, systemic lupus erythematosus, inflammatory bowel disease, Crohn's disease, hyperthyroidism, autoimmune adrenal insufficiency, Sjogren syndrome, type I diabetes mellitus, autoimmune hemolytic anemia, idiopathic thrombocytopenic purpura, myasthenia gravis, ulcerative colitis, uveitis, polyarteritis nodosa, relapsing polychondritis, Behcet's disease, reactive arthritis, ankylosing spondylitis, Guillain-Barre syndrome, or optic neuropathy. In other embodiments, the disease and/or condition is chronic obstructive pulmonary disease, rheumatoid arthritis, uveoretinitis, psoriasis, and eczema. In other embodiments, the disease and/or condition is irritable bowel disease, multiple sclerosis or lupus

In other embodiments, the inflammatory related disease and/or condition is an ocular disease. As used herein, the terms “ocular disease”, “eye disorder” and “eye disease” are used interchangeably and refer to a disease or disorder that affects the health and/or vision of either one or both eyes or the general area of the eye(s), eye lid(s), or area surrounding or in near proximity to the eye(s). Eye disease may include, but are not limited to, macular degeneration (e.g., age-related macular degeneration), cataracts, diabetic retinopathy, diabetic macular edema, eye floaters, eye flashes, glaucoma, amblyopia, strabismus, retinitis (e.g., CMV retinitis), color blindness, keratoconus, retinal detachment, eyelid twitching, ocular hypertension, blepharitis, uveitis, Bietti's crystalline dystrophy, blepharospasm, cornea and corneal diseases, dry eye, histoplasmosis, macular hole, macular pucker, conjunctivitis, presbyopia, retinoblastoma, retinitis pigmentosa, retinopathy, Stargardt disease, Usher syndrome, uveal Coloma, and vitreous detachment, or the like.

Described herein is a method for treatment including, selecting a subject in need of treatment, administering a composition including a plurality of artificial synapses to the individual, wherein administration of the composition treats the subject. In certain embodiments, the subject is in need to treatment for a disease and/or condition involving tissue damage or dysfunction.

Described herein is a method of treating an autoimmune disease, inflammation, inflammatory disease or condition, or cancer in a subject, the method comprising: administering to a subject an engineered EV or composition thereof as provided herein to the subject.

Measured or measurable parameters include clinically detectable markers of disease, for example, elevated or depressed levels of a clinical or biological marker, as well as parameters related to a clinically accepted scale of symptoms or markers for a disease or disorder. It will be understood, however, that the total usage of the compositions and formulations as disclosed herein will be decided by the attending physician within the scope of sound medical judgment. The exact amount required will vary depending on factors such as the type of disease being treated.

Non-limiting examples of clinical tests that can be used to assess autoimmune diseases, inflammatory conditions, or inflammation parameters include blood tests, skin biopsy, MRI, eye examination, ocular pressure tests, etc. Where necessary or desired, animal models of injury or disease can be used to gauge the effectiveness of a particular composition as described herein. For example, an EAU animal model, as demonstrated in the working examples can be used.

In various embodiments, administration of the plurality of artificial synapses alters gene expression in the damaged or dysfunctional tissue, improves viability of the damaged tissue, and/or enhances regeneration or production of new tissue in the individual. In various embodiments, administration of the plurality of artificial synapses alters gene expression in the damaged or dysfunctional tissue, improves viability of the damaged tissue, and/or enhances regeneration or production of new tissue in the individual.

In various embodiments, the damaged or dysfunctional tissue is in need of repair, regeneration, or improved function due to an acute event. Acute events include, but are not limited to, trauma such as laceration, crush or impact injury, shock, loss of blood or oxygen flow, infection, chemical or heat exposure, poison or venom exposure, drug overuse or overexposure, and the like. Other sources of damage also include, but are not limited to, injury, age-related degeneration, cancer, and infection. In several embodiments, the regenerative cells used to prepare the engineered EVs provided herein are from the same tissue type as is in need of repair or regeneration. In several other embodiments, the regenerative cells are from a tissue type other than the tissue in need of repair or regeneration. In some embodiments, the engineered EVs provided herein are derived from the subject being treated. In some embodiments, the engineered EVs are derived from a donor subject.

In other embodiments, the damaged or dysfunctional tissue is in need of repair, regeneration, or improved function due to damage from chronic disease.

Some Selected Definitions

All references cited herein are incorporated by reference in their entirety as though fully set forth. Unless defined otherwise, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Allen et al., Remington: The Science and Practice of Pharmacy 22^nded., Pharmaceutical Press (Sep. 15, 2012); Hornyak et al., Introduction to Nanoscience and Nanotechnology, CRC Press (2008); Singleton and Sainsbury, Dictionary of Microbiology and Molecular Biology 3^rded., revised ed., J. Wiley & Sons (New York, NY 2006); Smith, March's Advanced Organic Chemistry Reactions, Mechanisms and Structure 7^thed., J. Wiley & Sons (New York, NY 2013); Singleton, Dictionary of DNA and Genome Technology 3^rded., Wiley-Blackwell (Nov. 28, 2012); and Green and Sambrook, Molecular Cloning: A Laboratory Manual 4th ed., Cold Spring Harbor Laboratory Press (Cold Spring Harbor, NY 2012), provide one skilled in the art with a general guide to many of the terms used in the present application. For references on the preparation and structure of antibodies and fusion polypeptides, see, e.g., Greenfield, Antibodies A Laboratory Manual 2^nded., Cold Spring Harbor Press (Cold Spring Harbor NY, 2013); Köhler and Milstein, Derivation of specific antibody-producing tissue culture and tumor lines by cell fusion, Eur. J. Immunol. 1976 July, 6(7):511-9; Queen and Selick, Humanized immunoglobulins, U.S. Pat. No. 5,585,089 (1996 December); and Riechmann et al., Reshaping human antibodies for therapy, Nature 1988 Mar. 24, 332(6162):323-7. See also, Kabat et al., Sequences of Proteins of Immunological Interest, 5th Ed. Public Health Service, National Institutes of Health, Bethesda, Md. (1991), Lanzavecchia et al., Eur. J. Immunol. 17, 105 (1987)), Huston et al., Proc. Natl. Acad. Sci. U.S.A., 85, 5879-5883 (1988), Bird et al., Science 242, 423-426 (1988), Brinkman et al. mAbs Vol 9, No. 2, 182-212 (2017), Chothia & Lesk, J. Mol. Biol, 196:901-917 (1987), Chothia et al., Nature 342:877-883 (1989)), Holliger et al. (1993) Proc. Natl. Acad. Sci. USA 90: 6444-6448; Poljak (1994) Structure 2: 1121-1123); Kontermann and Dubel eds., Antibody Engineering, Springer-Verlag, N.Y. (2001), p. 790 (ISBN 3-540-41354-5, Zapata et al. (1995) Protein Eng. 8(10): 1057-1062; Morrison, et al., Proc. Natl. Acad. Sci. USA, 81:6851 (1984), U.S. Pat. Nos. 4,816,567, 5,693,780, which are incorporated herein by reference in their entireties.

One skilled in the art will recognize many methods and materials similar or equivalent to those described herein, which could be used in the practice of the present invention. Indeed, the present invention is in no way limited to the methods and materials described. For purposes of the present invention, the following terms are defined below.

As used herein, the term “extracellular vesicle” and “vesicle” are used interchangeably and refer to a particle, wherein the particle comprises a phospholipid bilayer that encloses an internal space and an exterior surface and may or may not be derived from a cell. The size of extracellular vesicles can range between 20 nm to 3 μm in diameter but may be smaller than 20 nm or larger than 3 μm. Examples of extracellular vesicles include, but is not limited to, exosomes (for example small exosomes and large exosomes), ectosomes, macrovesicles, microparticles, apoptotic bodies, vesicular organelles, oncosomes (for examples large oncosomes), exospheres, exomeres, cell derived nanovesicles (CDN) (e.g., by genesis via grating or shearing cells), liposomes or the like known by one of ordinary skill in the art. Extracellular vesicles may originate naturally via known or unknown biosynthetic pathways. Extracellular vesicles may be promoted to originate by using mechanical methods such as cell grating or cell shearing wherein a cell is grated or sheared causing portions or parts of the cell membrane to from vesicles. For example, CDNs may be formed by using mechanical methods such as cell grating or cell shearing wherein a cell is grated or sheared causing portions or parts of the cell membrane to from vesicles. Additional non-limiting examples of mechanical methods that can be used to form cell derived nanovesicles are further described in detail, e.g., Goh, W. J., Zou, S., Ong, W. Y. et al. Bioinspired Cell-Derived Nanovesicles versus Exosomes as Drug Delivery Systems: a Cost-Effective Alternative. Sci Rep 7, 14322 (2017). https://doi.org/10.1038/s41598-017-14725-x, the contents of which are incorporated herein by reference in their entireties.

Extracellular vesicles comprise cargo, wherein the term “cargo” refers to peptides, proteins, nucleic acids, lipids, metabolites, carbohydrates, biomolecules, small molecules, large molecules, vesicles, organelles, or fragments thereof. In some embodiments, cargo may refer to existing drugs or therapeutics known in the art. Extracellular vesicle cargo may be located within the internal space of the extracellular vesicle. Extracellular vesicle cargo may be membrane bound and span one or both layers of the extracellular vesicle phospholipid bilayer (for example a transmembrane protein). Extracellular vesicle cargo may be in contact with the external or internal surface of the extracellular vesicle, for example through a covalent bond or a non-covalent bond. The phospholipid bilayer of the extracellular vesicle may comprise one or more transmembrane proteins, wherein a portion of the one or more transmembrane membrane proteins is located within the internal space of the extracellular vesicle. The phospholipid bilayer of the extracellular vesicle may comprise one or more transmembrane proteins, wherein the one or more transmembrane membrane proteins comprises a domain on the exterior of the extracellular vesicle. The phospholipid bilayer of the extracellular vesicle may comprise one or more transmembrane proteins, wherein the one or more transmembrane membrane proteins comprises a domain on the interior of the extracellular vesicle. Cargo may refer to a protein on the luminal side (e.g., in the internal space) of the extracellular vesicle wherein said protein encodes a vesicle targeting domain that may be in contact with the interior phospholipid layer of the extracellular vesicle. Cargo may refer to a protein on the luminal side (e.g., in the internal space) of the extracellular vesicle wherein said protein encodes a vesicle targeting domain that may be in contact with the interior phospholipid layer of the extracellular vesicle and wherein said protein may be presented into the internal space of the extracellular vesicle.

As used herein, the terms “sticky binder” and “vesicle targeting domain” and “anchor protein” are used interchangeably and refer to a protein that is covalently or non-covalently attached to at least one lipid wherein the one or more lipid is embedded within a membrane (e.g., a cell membrane), and the lipid serves to anchor the protein to the membrane. The terms “sticky binder” and “vesicle targeting domain” and “anchor protein” can also mean a protein sequence that encodes for one or more transmembrane domains wherein the one or more transmembrane domains spans at least partly through a phospholipid bilayer, for example the phospholipid bilayer of an extracellular vesicle. The transmembrane domain can be of a Type I or Type II membrane protein. Transmembrane domains can be structurally identified using methods known to those of skill in the art, such as sequence analysis programs that identify hydrophobic and hydrophilic domains (for example TMHMM Server, v. 2.0—DTU, Erik L. L. Sonnhammer, Gunnar von Heijne, and Anders Krogh: A hidden Markov model for predicting transmembrane helices in protein sequences. In Proc. of Sixth Int. Conf. on Intelligent Systems for Molecular Biology, p 175-182 Ed J. Glasgow, T. Littlejohn, F. Major, R. Lathrop, D. Sankoff, and C. Sensen Menlo Park, CA: AAAI Press, 1998, which is incorporated herein by reference in its entirety.)

A vesicle targeting domain may include, but is not limited to, one or more prenylation site, fatty acylation site, and/or glycosylphosphatidylinositol (GPI) linked protein. One preferred embodiment of a vesicle targeting domain is the GPI sequence from CD55. Another preferred embodiment of a vesicle targeting domain is the GPI sequence from CD59. Another embodiment of a vesicle targeting domain is the C1C2 domain from MFGE8. Other embodiments of sequences for vesicle targeting domains include transmembrane regions of CD9 (for example transmembrane 2 or 3 of CD9, CD9tm2 or CD9tm3, respectively), K-Ras (for example K-Ras4A and K-Ras4B), transmembrane domain from A Disintegrin and Metalloproteinase Domain-containing protein 10 (ADAM10, also known as CDw156 or CD156c) or other ADAM proteins. Vesicle targeting domains may include one or more sequences from 4F2 (for example 4F2 encoded by the solute carrier family 3 member 2 (SLC3A2) gene which makes up the heavy subunit of CD98). Vesicle targeting domains can include a sequence for one or more myristoylation sites. For example, the protein sequence for a myristoylation site from myristoylated alanine-rich C-kinase substrate (MARCKS) protein. Vesicle targeting domains can include a sequence for one or more palmitoylation sites. For example, the myristoylation sequence from the MARCKS protein may be modified to encode for a palmitoylation site. All variants, isoforms, or fragments or the like known by one of ordinary skill in the art are encompassed by the present invention.

Vesicle targeting domains may include transmembrane sequences from Homo sapiens transferrin receptor 2 (TFR2), transcript variant 1 (transferrin receptor protein 2 isoform 1) or versions therefore. In a preferred embodiment, the vesicle targeting domain may be a transmembrane domain from CD298.

As used herein, the terms “proteins” and “peptides” and “polypeptides” are used interchangeably herein to designate a series of amino acid residues connected to the other by peptide bonds between the alpha-amino and carboxy groups of adjacent residues. Although “protein” is often used in reference to relatively large polypeptides, and “peptide” is often used in reference to small polypeptides, usage of these terms in the art overlaps and varies. The term “peptide” as used herein refers to peptides, polypeptides, proteins and fragments of proteins, unless otherwise noted. The terms “protein” and “peptide” are used interchangeably herein when referring to a gene product and fragments thereof. Thus, exemplary peptides or proteins include gene products, naturally occurring proteins, homologs, orthologs, paralogs, fragments and other equivalents, variants, fragments, and analogs of the foregoing.

As used herein, the term “linker” refers to a synthetic protein sequence of amino acids that is used to connect two polypeptide domains via peptide bonds.

As used herein, the term “fusion protein” refers to a single chimeric protein comprising a protein of interest (e.g., checkpoint protein) joined to an exogenous protein or protein fragment (e.g., an anchor protein), wherein the components of the fusion protein are linked to each other by peptide-bonds, either directly or through a peptide linker. The anchor protein of the fusion protein may enhance incorporation of the fusion protein onto and/or into the membrane of a vesicle, for example the internal and/or external leaflet of the phospholipid bilayer of an exosome membrane. The fusion protein may have at least a part of an amino acid sequence of an immune checkpoint protein or proteins involved in immune synapses. The fusion protein may have at least a part of an amino acid sequence of A2AR, VTCN1, Galectin 9, FGL-1, PECAM-1, TSG-6, STAB-1, NRP1, NRP2, SEMA3A, SEMA3F, RGMB, TIM-3, TIGIT, HLA class I, HLA class II, VISTA, HMGB1, phosphatidylserine, T-cell receptor (TCR), SHP-1, SHP-2, FBXO38, SH2D1A, B7RP1, IDO, NOX2, TNFRSF18, B7-H4, B7-H5, SISP1, B7-H6, B7-H7, APLNR, IFN γ, PD-1, WNT5A, IL-6, IL-10, NKG2 family of C-type lectin receptors, ligands of NKG2 family, killer cell immunoglobulin-like receptors, CD2, CD4, CD8, CD27, CD27 ligand (CD70), CD28, CD28H, CD39, CD40, CD44, CD47, CD63, CD66a, CD80, B7-2, CD86, CD73, CD94, CD96, CD101, CD112, CD112R, CD122, CD134, CD137 (4-1BB), CD137 ligand (4-1BBL), CD152, CD154, CD155, CD158, CD158a, CD158g, CD158h, KIR2DL1, KIR2DS1, KIRDS3, KIR2DS5, CD160, CD172a, CD200, CD200R, CD223, CD226, CD252, CD270, CD272, CD273, CD274, CD275, CD276, CD278, CD279 (PD-1), CD279 ligand (PD-L1/PDL-2), CD328, CD329, and/or CD337. The fusion protein may have a polypeptide linker sequence (e.g., an Fc domain and/or a GSSG linker), followed by an amino acid sequence coding for an anchor protein sequence (e.g., a prenylation site, fatty acylation site, or a GPI sequence) or any isoform, fragment, variation thereof, or a ligand to the aforementioned proteins thereof, or the like known by one of ordinary skill in the art. All variants are encompassed by the present invention.

As used herein, the term “immune synapse” and “cell synapse” are used interchangeably and refer to cell-to-cell interaction wherein said interaction results in activation, suppression, and/or adhesion of either one or more cells. Immune synapse or cell synapse are mediated by proteins that may be cytoplasmic, membrane bound, membrane associated, and/or secreted. Immune or cell synapses may be mediated by one or more “immune checkpoint proteins” which herein refers to any protein that is involved in maintaining immune homeostasis or plays a role in regulating immune activation or suppression. Immune checkpoint proteins may be cytoplasmic, membrane bound, membrane associated, and/or secreted.

As used herein, the term “fragment” or “active fragment” refers to a portion of a nucleic acid or polypeptide provided herein that retains the ability to be expressed by the engineered EVs provided herein. In some embodiments, the active fragment retains the ability to activate a target polypeptide, thereby increasing the activity of said target polypeptide (e.g., suppressing an immune response).

As used herein, the terms “specifically bind” and/or “specifically recognize” or “substantially binds” refers to the affinity of a binding molecule for a target molecule compared to the binding molecule's affinity for non-target molecules. A binding molecule (e.g., a POI domain) that specifically binds a target molecule (e.g., a target polypeptide provided herein) does not substantially recognize or bind non-target molecules. e.g., an antibody “specifically binds” and/or “specifically recognize” another molecule, meaning that this interaction is dependent on the presence of the binding specificity of the molecule structure, e.g., an antigenic epitope. As used herein, “non-specific binding” and “background binding” refers to the interaction that does not depend on the presence of specific structure (e.g., a specific antigenic epitopes). Methods of measuring binding of a polypeptide to a target are known in the art (e.g., differential scanning calorimetry, isothermal titration calorimetry, spectroscopy, crystallography, surface plasmon resonance, co-immunoprecipitation, pulldown assays, crosslinking, yeast two-hybrid system, tandem affinity purification-mass spectroscopy, protein microarrays, bio-layer interferometry, far-Western blots, computational prediction, analytical ultracentrifugation, light scattering, fluorescence spectroscopy, resonance energy transfer, ELISA or ELISPOT assays, or the like known by one of ordinary skill in the art).

As used herein, the terms “treat,” “treatment,” “treating,” or “amelioration” refer to therapeutic treatments, wherein the object is to reverse, alleviate, ameliorate, inhibit, slow down or stop the progression or severity of a condition associated with, a disease or disorder. The term “treating” includes reducing or alleviating at least one adverse effect or symptom of a condition, disease or disorder associated with an infection or a cancer. Treatment is generally “effective” if one or more symptoms or clinical markers are reduced. Alternatively, treatment is “effective” if the progression of a disease is reduced or halted. That is, “treatment” includes not just the improvement of symptoms or markers, but also a cessation or at least slowing of progress or worsening of symptoms that would be expected in absence of treatment. Beneficial or desired clinical results include, but are not limited to, alleviation of one or more symptom(s), diminishment of extent of disease, stabilized (i.e., not worsening) state of disease, delay or slowing of disease progression, amelioration or palliation of the disease state, and remission (whether partial or total), whether detectable or undetectable. The term “treatment” of a disease also includes providing relief from the symptoms or side-effects of the disease (including palliative treatment).

As used herein “preventing” or “prevention” refers to any methodology where the disease state does not occur due to the actions of the methodology (such as, for example, administration of a composition or construct as described herein). In one aspect, it is understood that prevention can also mean that the disease is not established to the extent that occurs in untreated controls. Accordingly, prevention of a disease encompasses a reduction in the likelihood that a subject can develop the disease, relative to an untreated subject (e.g., a subject who is not treated with the methods or compositions described herein).

As used herein, the terms “autoimmune condition” and “autoimmune disease” are used interchangeably and refer to any disease characterized by abnormal functioning of the immune system and may include, but is not limited to, achalasia, Addison's disease, adult Still's disease, agammaglobulinemia, alopecia areata, amyloidosis, ankylosing spondylitis, anti-GBM/Anti-TBM nephritis, antiphospholipid syndrome, autoimmune angioedema, autoimmune dysautonomia, autoimmune encephalomyelitis, autoimmune hepatitis, autoimmune inner ear disease (AIED), autoimmune myocarditis, autoimmune oophoritis, autoimmune orchitis, autoimmune pancreatitis, autoimmune retinopathy, autoimmune urticaria, axonal & neuronal neuropathy (AMAN), Baló disease, Behcet's disease, benign mucosal pemphigoid, bullous pemphigoid, Castleman disease, celiac disease, Chagas disease, chronic inflammatory demyelinating polyneuropathy (CIDP), chronic recurrent multifocal osteomyelitis (CRMO), Churg-Strauss syndrome (CSS), eosinophilic granulomatosis (EGPA), cicatricial pemphigoid, Cogan's syndrome, cold agglutinin disease, congenital heart block, coxsackie myocarditis, CREST syndrome, Crohn's disease, dermatitis herpetiformis, dermatomyositis, Devic's disease (neuromyelitis optica), discoid lupus, Dressler's syndrome, endometriosis, eosinophilic esophagitis (EoE), eosinophilic fasciitis, erythema nodosum, essential mixed cryoglobulinemia, Evans syndrome, fibromyalgia, fibrosing alveolitis, giant cell arteritis (temporal arteritis), giant cell myocarditis, glomerulonephritis, Goodpasture's syndrome, granulomatosis with polyangiitis, Graves' disease, Guillain-Barre syndrome, Hashimoto's thyroiditis, hemolytic anemia, Henoch-Schonlein purpura (HSP), Herpes gestationis or pemphigoid gestationis (PG), hidradenitis suppurativa (HS) (acne inversa), hypogammalglobulinemia, IgA nephropathy, IgG4-related sclerosing disease, immune thrombocytopenic purpura (ITP), inclusion body myositis (IBM), interstitial cystitis (IC), juvenile arthritis, type 1 diabetes, juvenile myositis (JM), Kawasaki disease, Lambert-Eaton syndrome, leukocytoclastic vasculitis, lichen planus, lichen sclerosus, ligneous conjunctivitis, linear IgA disease (LAD), lupus, lyme disease chronic, Meniere's disease, microscopic polyangiitis (MPA), mixed connective tissue disease (MCTD), Mooren's ulcer, Mucha-Habermann disease, multifocal motor neuropathy (MMN) or MMNCB, multiple sclerosis, myasthenia gravis, myositis, narcolepsy, neonatal Lupus, neuromyelitis optica, neutropenia, ocular cicatricial pemphigoid, optic neuritis, palindromic rheumatism (PR), PANDA, paraneoplastic cerebellar degeneration (PCD), paroxysmal nocturnal hemoglobinuria (PNH), Parry Romberg syndrome, pars planitis (peripheral uveitis), Parsonage-Turner syndrome, pemphigus, peripheral neuropathy, perivenous encephalomyelitis, pernicious anemia (PA), POEMS syndrome, polyarteritis nodosa, polyglandular syndromes type I, II, III, polymyalgia rheumatica, polymyositis, postmyocardial infarction syndrome, postpericardiotomy syndrome, primary biliary cirrhosis, primary sclerosing cholangitis, progesterone dermatitis, psoriasis, psoriatic arthritis, pure red cell aplasia (PRCA), pyoderma gangrenosum, Raynaud's phenomenon, reactive arthritis, reflex sympathetic dystrophy, relapsing polychondritis, restless legs syndrome (RLS), retroperitoneal fibrosis, rheumatic fever, rheumatoid arthritis, sarcoidosis, Schmidt syndrome, scleritis, scleroderma, Sjögren's syndrome, sperm & testicular autoimmunity, stiff person syndrome (SPS), subacute bacterial endocarditis (SBE), Susac's syndrome, sympathetic ophthalmia (SO), takayasu's arteritis, temporal arteritis/Giant cell arteritis, thrombocytopenic purpura (TTP), Tolosa-Hunt syndrome (THS), transverse myelitis, type 1 diabetes, ulcerative colitis (UC), undifferentiated connective tissue disease (UCTD), uveitis, vasculitis, vitiligo, Vogt-Koyanagi-Harada disease. An autoimmune condition or autoimmune diseases may be caused by, but not limited to, a natural predisposition, a infection (e.g., bacteria or virus), drugs, vaccination, environmental triggers (e.g., toxins or chemicals such as dust, silica, oil, benzene, tri- or per-chloroethylene etc.), stress, cancer, blood or tissue or organ transplantation, or unknown etiology. Autoimmune disorders may result in but not limited to the destruction of body tissue, abnormal growth of an organ or tissue, changes in organ or tissue function (e.g., changes in blood vessels, connective tissue, function of endocrine glands, joints, muscles, blood cells, skin, etc.).

As used herein, the term “cancer” refers to a hyperproliferation of cells that exhibit a loss of normal cellular control that results in unregulated growth, lack of differentiation, local tissue invasion, and metastasis. The methods and compositions described herein can be used for the treatment of solid tumors (e.g., cancer) or non-solid tumors, such as leukemia, blood cell cancers, and the like. Solid tumors can be found in bones, muscles, the brain, or organs, and can be sarcomas or carcinomas. Where the methods and compositions described herein can overcome barriers of tumor treatment, including, but not limited to barriers to treatment or inhibition of metastases, it is contemplated that aspects of the technology described herein can be used to treat all types of solid and non-solid tumor cancers, including cancers not listed in the instant specification. The compositions and methods described herein, without limitation, include methods of treating cancer, methods of inhibiting metastases, and methods of inducing an anti-tumor immune response.

As used herein, the terms “subject”, “individual”, “host”, and “patient” are used interchangeably and may refer to any animal, mammal, bird, fish, reptile, and amphibian, for example, human, monkey, dog, cat, horse, pig, cattle, ox, donkey, rabbit, sheep, goat, mouse, rat, guinea pig, llama, chicken, goose, duck, turkey, or the like receiving or registered to receive a therapeutic amount of a composition of the present invention for medical care or treatment.

As used herein, the term “injection” refers to any process or method which allows the person skilled in the art to administer any therapeutic to a target site by penetration. Examples of injection are, but not limited to, subcutaneous, subcuticular, subcapsular, subarachnoid, intradermal, intramuscular, intravenous, intra-arterial, intraventricular, intracapsular, intraorbital, intraocular, intrathoracic, intraperitoneal, intravitreal, retro-orbital, intranasal, intracerebral, intrathymic, intraspinal, intrasternal, intra-articular, intracavernous, intracardiac, intraosseous, intrathecal, transtracheal, epidural, or the like as known in the art. A therapeutic does of the present invention may be delivered to a patient by means of controlled release, for example but not limited to, implantable pump and implantable cannulas to provide continuous access to the venous or arterial system.

As used herein, the term “topical application” refers to applying or spreading a composition of the present invention onto surfaces on or in the body, both internally and/or externally, in a therapeutically effective amount for local and/or systemic treatment. Topical application may be epicutaneous wherein a composition of the present invention may be directly applied onto a localized surface of the skin or mucous membranes. Topical application may include transdermal application wherein a composition of the present invention may be absorbed into the body to obtain systemic delivery and systemic distribution. For example, a transdermal patch may be applied onto the body to deliver a therapeutic dose of a composition of the invention presented herein. Topical application formulations may include, but are not limited to, creams, foams, gels, lotions, solutions, ointments, dermal patch, transdermal patches, powder, solid, sponge, tape, vapor, paste, film, liposomes, balm, shampoo, spray, or tincture. A therapeutic dose of a composition of the present invention may be delivered vaginally (for example a vaginal suppository, vaginal ring, douche, intrauterine device, intravesical infusion, and the like) or urethra.

As used herein, the term “enteral administration” refers to a composition of the present invention administered via the gastrointestinal tract in a therapeutically effective amount for local or systemic treatment. Enteral administration may include, but is not limited to, delivery of a composition of the present invention via the mouth, sublingual, esophagus, gastric (for example the stomach), small intestines, large intestines or rectum. Oral delivery of the present invention may include, but is not limited to, the use of a capsule, pastille, pill, tablet, solution, gel, suspension, emulsion, syrup, elixir, tincture, mouthwash, lozenges, chewing gum, lollipop, osmotic-controlled release oral delivery system, or the like. Gastric delivery may involve the use of a tube or nasal passage that leads directly to the stomach, for example, a percutaneous endoscopic gastrostomy tube. Gastric delivery may involve direct injection made through the abdominal wall. Rectal delivery may involve, but is not limited to, the use of a suppository, ointment, enema, murphy drip, or the like. A therapeutic does of the present invention may be delivered to a patient by means of controlled release, for example but not limited to, controlled release drug delivery pellet or pill.

As used herein, the terms “pulmonary system” or “respiratory system” are used interchangeably and refer, but are not limited, to the respiratory region, conducting airways, nasal cavity, sinuses, nasopharynx, oropharynx, larynx, trachea, bronchi, bronchioles, respiratory bronchioles, alveolar ducts, alveolar sacs, respiratory epithelium (e.g., alveolar epithelial cells), endothelial cells, or the like.

As used herein, the terms “pulmonary delivery” and “pulmonary administration” are used interchangeably and refer to delivering a composition of the present invention to the respiratory system through the respiratory route, including but not limited to, intranasal administration, oral administration, and oral inhalative administration (e.g., intratracheal instillation and intratracheal inhalation) of a therapeutically effective amount for local or systemic treatment. Pulmonary delivery of a therapeutically effective amount of a composition of the present invention may be achieved by dispersion, for example by using a syringe. Pulmonary delivery of a composition of the present invention may be achieved by aerosol administration, wherein aerosol administration may deposit a therapeutically effective amount of the present invention by gravitational sedimentation, inertial impaction, or diffusion.

Pulmonary delivery of a therapeutically effective amount of a composition of the present invention may be deposited on any mucus layer of the respiratory system, for example, but not limited to, the mucus layer which coats the walls of conducting airways, the smaller airway, and/or alveolar space.

As used herein, an “appropriate control” refers to an untreated, otherwise identical cell or population (e.g., a subject who was not administered the composition described herein, or was administered by only a subset of agents provided herein, as compared to a non-control cell).

As used herein, a “reference level” can refer to one or more parameters or markers as measured for a normal, otherwise unaffected cell population or tissue (e.g., a biological sample obtained from a healthy subject, or a biological sample obtained from the subject at a prior time point, or a biological sample that has not yet been contacted with a pathogen as described herein). For measuring or monitoring therapeutic efficacy, a level determined prior to treatment or earlier in treatment can also provide a reference level for a given parameter or value.

As used herein, the term “modulates” refers to an effect including increasing or decreasing a given parameter as those terms are defined herein.

The terms “increased,” “increase,” “increases,” or “enhance” or “activate” are all used herein to generally mean an increase of a property, level, or other parameter by a statistically significant amount; for the avoidance of any doubt, the terms “increased”, “increase” or “enhance” or “activate” means an increase of at least 10% as compared to a reference level, for example an increase of at least about 20%, or at least about 30%, or at least about 40%, or at least about 50%, or at least about 60%, or at least about 70%, or at least about 80%, or at least about 90% or up to and including a 100% increase or any increase between 10-100% as compared to a reference level, or at least about a 2-fold, or at least about a 3-fold, or at least about a 4-fold, or at least about a 5-fold or at least about a 10-fold increase, at least about a 20-fold increase, at least about a 50-fold increase, at least about a 100-fold increase, at least about a 1000-fold increase or more as compared to a reference level. For example, increasing activity can refer to activating a receptor or a signaling pathway (e.g., antibody production or inflammation).

The terms “decrease,” “reduced,” “reduction,” or “inhibit” are all used herein to mean a decrease or lessening of a property, level, or other parameter by a statistically significant amount. In some embodiments of any of the aspects, “reduce,” “reduction” or “decrease” or “inhibit” typically means a decrease by at least 10% as compared to a reference level (e.g., the absence of a given treatment) and can include, for example, a decrease by at least about 10%, at least about 20%, at least about 25%, at least about 30%, at least about 35%, at least about 40%, at least about 45%, at least about 50%, at least about 55%, at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90%, at least about 95%, at least about 98%, at least about 99%, or more.

As used herein, “reduction” or “inhibition” does not encompass a complete inhibition or reduction as compared to a reference level. “Complete inhibition” is a 100% inhibition as compared to a reference level. A decrease can be preferably down to a level accepted as within the range of normal for an individual without a given disorder.

As used herein the term “comprising” or “comprises” is used in reference to compositions, methods, and respective component(s) thereof, that are essential to the method or composition, yet open to the inclusion of unspecified elements, whether essential or not.

As used herein the term “consisting essentially of” refers to those elements required for a given embodiment. The term permits the presence of elements that do not materially affect the basic and novel or functional characteristic(s) of that embodiment.

The term “consisting of” refers to compositions, methods, and respective components thereof as described herein, which are exclusive of any element not recited in that description of the embodiment.

As used in this specification and the appended claims, the singular forms “a,” “an,” and “the” include plural references unless the context clearly dictates otherwise. Thus for example, references to “the method” includes one or more methods, and/or steps of the type described herein and/or which will become apparent to those persons skilled in the art upon reading this disclosure and so forth. Similarly, the word “or” is intended to include “and” unless the context clearly indicates otherwise. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of this disclosure, suitable methods and materials are described below. The abbreviation, “e.g.” is derived from the Latin exempli gratia, and is used herein to indicate a non-limiting example. Thus, the abbreviation “e.g.” is synonymous with the term “for example.”

The abbreviation, “etc.” is derived from the Latin et cetera, and is used herein to indicate a non-limiting list. Thus, the abbreviation “etc.” is synonymous with the term “and other similar things”, or “and so forth”.

Other than in the operating examples, or where otherwise indicated, all numbers expressing quantities of ingredients or reaction conditions used herein should be understood as modified in all instances by the term “about.” The term “about” when used in connection with percentages can mean 10%.

The term “statistically significant” or “significantly” refers to statistical significance and generally means a two-standard deviation (2SD) difference, above or below a reference value. Additional definitions are provided in the text of individual sections below.

It should be understood that this invention is not limited to the particular methodology, protocols, and reagents, etc., described herein and as such may vary. The terminology used herein is for the purpose of describing particular embodiments only, and is not intended to limit the scope of the present invention, which is defined solely by the claims.

As used herein and in the claims, the singular forms include the plural reference and vice versa unless the context clearly indicates otherwise. The term “or” is inclusive unless modified, for example, by “either.” Other than in the operating examples, or where otherwise indicated, all numbers expressing quantities of ingredients or reaction conditions used herein should be understood as modified in all instances by the term “about.”

Unless otherwise explained, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs.

It is to be understood that the foregoing description and the following examples are illustrative only and are not to be taken as limitations upon the scope of the invention. Various changes and modifications to the disclosed embodiments, which will be apparent to those of skill in the art, may be made without departing from the spirit and scope of the present invention. Further, all patents, patent applications, and publications identified are expressly incorporated herein by reference for the purpose of describing and disclosing, for example, the methodologies described in such publications that might be used in connection with the present invention. These publications are provided solely for their disclosure prior to the filing date of the present application. Nothing in this regard should be construed as an admission that the inventors are not entitled to antedate such disclosure by virtue of prior invention or for any other reason. All statements as to the date or representation as to the contents of these documents are based on the information available to the applicants and do not constitute any admission as to the correctness of the dates or contents of these documents.

All patents and other publications identified are expressly incorporated herein by reference for the purpose of describing and disclosing, for example, the methodologies described in such publications that could be used in connection with the present invention. These publications are provided solely for their disclosure prior to the filing date of the present application. Nothing in this regard should be construed as an admission that the inventors are not entitled to antedate such disclosure by virtue of prior invention or for any other reason. All statements as to the date or representation as to the contents of these documents is based on the information available to the applicants and does not constitute any admission as to the correctness of the dates or contents of these documents.

Some embodiments of the technology described herein can be defined according to any of the following numbered paragraphs:

1. An engineered extracellular vesicle comprising:

- at least one fusion polypeptide comprising:
  - (i) at least one protein of interest (POI) domain or a fragment thereof, and
  - (ii) at least one vesicle targeting domain,
- wherein the POI domain is in an extracellular position relative to a lipid membrane of the extracellular vesicle.

2. The engineered extracellular vesicle of paragraph 1, wherein the extracellular vesicle is an exosome.

3. The engineered extracellular vesicle of paragraph 1 or paragraph 2, wherein the protein of interest (POI) domain or a fragment thereof is a N-terminal domain of the fusion polypeptide.

4. The engineered extracellular vesicle of any one of paragraphs 1-3, wherein the vesicle targeting domain is a C-terminal domain of the fusion polypeptide.

5. The engineered extracellular vesicle of any one of paragraphs 1-4, wherein the fusion polypeptide comprises at least two POI domains and/or at least two exosome targeting domains.

6. The engineered extracellular vesicle of any one of paragraphs 1-5, wherein the fusion polypeptide further comprises a peptide linker.

7. The engineered extracellular vesicle of any one of paragraphs 1-6, wherein the fusion polypeptide further comprises a fragment crystallizable region (Fc) domain.

8. The engineered extracellular vesicle of any one of paragraphs 1-7, wherein the vesicle targeting domain is in a luminal position relative to the lipid membrane of the extracellular vesicle.

9. The engineered extracellular vesicle of any one of paragraphs 1-7, wherein the vesicle targeting domain in an exterior position relative to the lipid membrane of the extracellular vesicle.

10. The engineered extracellular vesicle of any one of paragraphs 1-9, wherein the POI domain is selected from the group consisting of: Table 1.

11. The engineered extracellular vesicle of any one of paragraphs 1-10, wherein the POI domain is PD-L1 or a fragment thereof.

12. The engineered extracellular vesicle of any one of paragraphs 1-11, wherein the POI domain is PD-L2 or a fragment thereof.

13. The engineered extracellular vesicle of any one of paragraphs 1-12, wherein the POI domain is FGL1 or a fragment thereof.

14. The engineered extracellular vesicle of any one of paragraphs 1-13, wherein the POI domain is 4-1BBL or a fragment thereof.

15. The engineered extracellular vesicle of any one of paragraphs 1-14, wherein the POI domain is CTLA-4 or a fragment thereof.

16. The engineered extracellular vesicle of any one of paragraphs 1-15, wherein the POI domain substantially binds to one or more of a target polypeptide.

17. The engineered extracellular vesicle of paragraph 16, wherein the target polypeptide is selected from the group consisting of: Table 2.

18. The engineered extracellular vesicle of any one of paragraphs 1-17, wherein the vesicle targeting domain is selected from the group consisting of; Table 3.

19. The engineered extracellular vesicle of any one of paragraphs 1-18, wherein the linker is in an exterior position relative to the lipid membrane of the extracellular vesicle.

20. The engineered extracellular vesicle of any one of paragraphs 1-18, wherein the linker is a transmembrane linker.

21. The engineered extracellular vesicle of any one of paragraphs 1-18, wherein the linker is in a luminal position relative to the lipid membrane of the extracellular vesicle.

22. The engineered extracellular vesicle of any one of paragraphs 1-21, wherein the extracellular vesicle does not comprise an endogenous POI polypeptide.

23. A composition comprising a plurality of the engineered extracellular vesicles of any one of paragraphs 1-22.

24. The composition of paragraph 23, further comprising a pharmaceutically acceptable carrier.

25. An engineered extracellular vesicle comprising:

- (a) a first fusion polypeptide comprising:
  - (i) at least one protein of interest (POI) domain or a fragment thereof, and
  - (ii) at least one vesicle targeting domain,
- wherein the at least one POI domain is in an extracellular position relative to a lipid membrane of the extracellular vesicle,
- (b) a second fusion polypeptide comprising:
  - (i) at least one protein of interest (POI) domain or a fragment thereof; and
  - (ii) at least one vesicle targeting domain,
- wherein the POI domain is in an extracellular position relative to a lipid membrane of the extracellular vesicle,
- and wherein the at least one vesicle targeting domain is within a lipid membrane of the extracellular vesicle.

26. A composition comprising two or more of the engineered extracellular vesicles selected from any one of paragraphs 1-25.

27. An extracellular vesicle composition comprising:

- a plurality of artificial synapses,
- wherein each artificial synapse comprises (i) an extracellular vesicle; (ii) one or more sticky binders; and (iii) one or more signaling domains.
  
  The composition of paragraph 27, wherein the extracellular vesicle comprises an exosome.

28. The composition of paragraph 27, wherein the one or more sticky binders is selected from the group consisting of: a GPI anchor, a fatty acetylation site, and a prenylation site.

30. The composition of paragraph 27, wherein the signaling domain comprises one or more of: PD-L1, PD-L2, CTLA-4 (CD152), 4-1BBL (CD137L), HVEM (CD270), FGL1, OX-2 (CD200), Galectin-9, PVR (CD155), Nectin-2 (CD112) isoform alpha, Nectin-2 (CD112) isoform beta, Nectin-2 (CD112) isoform delta, IL-10, TSG-6, B7-H3 (CD276), B7-H4 (VTCN1), B7-H5 (VISTA), B7-H7 (HHLA2), BTNL1, VSIG8, VSIG3 (IGSF11), VSIG4, TIM-3 (HAVCR2), TIM-4 (TIMD4), CEACAM1, BTN3A1, BTN3A2, BTN2A1, BTNL8, BTN2A2, BTN1A1, TIGIT, CD27L (CD70), CD30L (CD153), GITRL, CD40L (CD154), LIGHT (CD258), TL1, CD80, CD86, LFA-3 (CD58), SLAM (CD150), CD40, CD28, CD28H, CD2, LFA-3 (CD58), CD48, CD226, DR3, DcR3, FasL, TIM-1 (CD365), PD-1, or active fragment thereof.

29. A method of producing the engineered extracellular vesicle or the composition of any one of paragraphs 1-30, comprising:

- (a) providing a population of cells expressing a vector construct encoding one or more sticky binder and one or more signaling domains; and
- (b) isolating a plurality of artificial synapses from the population of cells.

30. A method of producing the engineered extracellular vesicle or the composition of any one of paragraphs 1-30, comprising:

- (a) providing a population of cells expressing a vector construct encoding one or more sticky binder and one or more signaling domains; and
- (b) isolating a plurality of artificial synapses from the population of cells; and
- (c) purifying the plurality of artificial synapses from the population of cells.

33. The method of paragraph 31 or paragraph 32, the isolating is via size exclusion chromatography.

34. The method of paragraph 32, wherein the purifying is via multimodal chromatography.

35. The method of any of paragraphs 31-34, further comprising performing an assay for POI binding to a target polypeptide.

36. The method of paragraph 35, wherein the vector construct further encodes a promoter.

37. The method of paragraph 36, wherein the promoter is a tissue-specific promoter or an inducible promotor.

38. A method of modulating inflammation in a subject, the method comprising: administering a composition comprising a plurality of engineered extracellular vesicles to a subject in need thereof,

wherein the engineered extracellular vesicles comprise at least one fusion polypeptide comprising:

- (i) at least one protein of interest (POI) domain or a fragment thereof; and
- (ii) at least one vesicle targeting domain.

39. The method of paragraph 38, wherein the extracellular vesicle comprises an exosome.

40. The method of any one of paragraphs 38-39, further comprising selecting a subject that has or is suspected of having an autoimmune disease or an inflammatory disease or condition.

41. The method of any one of paragraphs 38-40, wherein the vesicle targeting domain is selected from the group consisting of: a Glycosylphosphatidylinositol (GPI) anchor, a fatty acetylation site, and a prenylation site.

42. The method of any one of paragraphs 38-41, wherein the vesicle targeting domain is a GPI anchor.

43. The method of any one of paragraphs 38-41, wherein the vesicle targeting domain is C1C2.

44. The method of any one of paragraphs 38-43, wherein the protein of interest (POI) domain comprises one or more of: PD-L1, PD-L2, CTLA-4 (CD152), 4-1BBL (CD137L), HVEM (CD270), FGL1, OX-2 (CD200), Galectin-9, PVR (CD155), Nectin-2 (CD112) isoform alpha, Nectin-2 (CD112) isoform beta, Nectin-2 (CD112) isoform delta, IL-10, TSG-6, B7-H3 (CD276), B7-H4 (VTCN1), B7-H5 (VISTA), B7-H7 (HHLA2), BTNL1, VSIG8, VSIG3 (IGSF11), VSIG4, TIM-3 (HAVCR2), TIM-4 (TIMD4), CEACAM1, BTN3A1, BTN3A2, BTN2A1, BTNL8, BTN2A2, BTN1A1, TIGIT, CD27L (CD70), CD30L (CD153), GITRL, CD40L (CD154), LIGHT (CD258), TL1, CD80, CD86, LFA-3 (CD58), SLAM (CD150), CD40, CD28, CD28H, CD2, LFA-3 (CD58), CD48, CD226, DR3, DcR3, FasL, TIM-1 (CD365), PD-1, or active fragment thereof.

45. The method of any one of paragraphs 38-44, wherein the protein of interest (POI) domain is PD-L1 or a fragment thereof.

46. The method of any one of paragraphs 38-44, wherein the protein of interest (POI) domain is PD-L2 or a fragment thereof.

47. The method of any one of paragraphs 38-44, wherein the protein of interest (POI) domain is CTLA-4 or a fragment thereof.

48. The method of any one of paragraphs 38-44, wherein the protein of interest (POI) domain is HVEM or a fragment thereof.

49. The method of paragraph 40, wherein the inflammatory disease and/or condition is acute.

50. The method of paragraph 40, wherein the inflammatory related disease and/or condition is chronic.

51. The method of paragraph 38, wherein administering the composition comprises injection, topical administration, or inhalation.

52. Use of a composition comprising a plurality of engineered extracellular vesicles, the engineered extracellular vesicles each comprising:

at least one fusion polypeptide comprising:

- (i) at least one protein of interest (POI) domain or a fragment thereof; and
- (ii) at least one vesicle targeting domain for the treatment of an inflammatory disease or condition.

53. Use of a composition comprising a plurality of engineered extracellular vesicles, the engineered extracellular vesicles each comprising:

at least one fusion polypeptide comprising:

- (i) at least one protein of interest (POI) domain or a fragment thereof; and
- (ii) at least one vesicle targeting domain for the treatment of an autoimmune disease or condition.

54. Use of a composition comprising a plurality of engineered extracellular vesicles, the engineered extracellular vesicles each comprising:

at least one fusion polypeptide comprising:

- (i) at least one protein of interest (POI) domain or a fragment thereof; and
- (ii) at least one vesicle targeting domain for the treatment of cancer.

EXAMPLES

The following examples are provided by way of illustration, not limitation.

Example 1
Design of an Artificial Synapse

As described, artificial synapses are engineered to induce and propagate biological signaling, including for example, antagonist and agonist signaling. Artificial synapses are designed to include hallmark biophysical and biochemical features of extracellular vesicles, further including vesicle targeting domains and signaling domains. Vesicle targeting domains capable of attaching to extracellular vesicles such as exosomes, signaling domains, optionally including a linker (e.g., Fc linker), can be organized in genetic vector constructs. Designs are shown in FIG. 1.

Sticky binders are extracellular vesicle targeting sequences. Preliminary extracellular vesicle targeting sequences of interest are from, but not limited to, 4F2 (CD98), ADAM10, CD298, TFR2, transmembrane domains of CD9, MARCKS, KRAS, etc. or the like as appreciate by one of ordinary skill in the art. The Inventors discovered high efficiency when proteins are engineered with a GPI domain. Optionally, linker regions such as an Fc linker between the vesicle targeting domains and signaling domains can be added.

A variety of signaling domains are of interest with proof-of-concept examples including PD-L1, PD-L2 and CTLA-4 (CD152). Artificial synapses including these three signaling domains are shown in FIGS. 2-5.

Each of these elements are described in the following non-limiting examples.

Example 2
Genetic Constructs

Examples of constructs including these variable elements (e.g., sticky binders GPI or C1C2, or signaling domains including PD-L1, PD-L2 and CTLA-4 (CD152) were engineered into vectors shown in FIGS. 2-5.

Example 3

Purification of hPD-L1 Tagged Artificial Synapses by a Multimodal Resin Marketed for Exosome Purification

Upon expression of hPD-L1-Fc-GPI in mammalian cells, artificial synapses were further purified using a size exclusion resin marketed for exosome purification. Large MW artificial synapses elute in the first fraction as shown by the high hPD-L1 concentration and exosome quantity (2.26E9 artificial synapses/ml) in elution 1. Clean in place (CIP) fractions show bound and eliminated proteins from the Inventors' exosome elution. Results are shown in FIG. 6.

Example 4

hPDL1-Fc-GPI Exosome Purification—Size Exclusion Chromatography Column

Artificial synapses engineered from exosomes such as hPDL1-Fc-GPI after elution from size exclusion resin marketed for exosome purification can be further purified via a size exclusion column as shown here. Using a size exclusion chromatography (SEC), artificial synapses elute in fractions 7-9. Total protein (determined by qBit) and hPD-L1 ng/ml (determined by ELISA) of each fraction is shown in the graph. Bars show exosome number per ml (i.e., 1E10 artificial synapses/ml etc.). Fractions 7-9 contain >99% purified artificial synapses. Fractions 7-9 are pooled and may be concentrated using a filtration device, for example a 10K MWCO Amicon Centrifugal Filter. Final purified product is filtered through a low protein binding 0.2 μm or 0.45 μm filter, for example a PES filter. Results are shown in FIG. 7.

Example 5

hPD-L1 Expression on Artificial Synapses

Exosome quantity and hPD-L1 concentration was determined in SEC fractions 7-9. Knowing the molecular weight of engineered hPD-L1, the Inventors can determine the number of hPD-L1 molecules per exosome to be approximately between 12 to 40 PD-L1/exosome. This value is consistent between different purification runs and constructs. Results are shown in FIG. 8.

Example 6

Purification of hPD-L2-Fc-GPI Artificial Synapses Via Multimodal Resin Chromatography Marketed for Exosome Purification

This graph shows Abs 280 of multimodal resin chromatography fractions and quantity of hPDL2 in indicated fractions. Artificial synapses eluted in Elution 1.

Clean in place (CIP) fractions show bound and eliminated proteins from the Inventors' exosome elution. Results are shown in FIG. 9.

Example 7
PD-L2 Purification Via Size Exclusion Chromatography

Artificial synapses engineered from artificial synapses such as hPDL2-GPI after elution from size exclusion resin size exclusion resin marketed for exosome purification are further purified via size exclusion chromatography as shown. Results are shown in FIG. 10.

Example 8

hCTLA4-Fc-GPI Exosome Purification Via Size Exclusion Chromatography

Using size exclusion chromatography marketed for exosome purification, artificial synapses elute in fractions 7-9. Total protein (determined by qBit) and hPD-L1 ng/ml (determined by ELISA) of each fraction is shown in the graph. Fractions 7-9 are pooled and contain >99% purified artificial synapses. Pooled artificial synapses engineered from artificial synapses fractions may then be concentrated using a filtration device, for example a 10K MWCO Amicon. Final purified product is filtered through a low protein binding filter, for example a 0.2 μm or 0.45 um PES filter. Results are shown in FIG. 11.

Example 9

PD-L1 and PD-L2 In Vitro Assay from DiscoverX

To perform this validation method, the Inventors modified the PathHunter PD-1 Signaling Bioassay from DiscoverX Briefly, the PathHunter PD-1 Signaling Bioassay relies on the well-established PathHunter Enzyme Fragment Complementation (EFC) technology to interrogate receptor activity. EFC consists of a split β-galactosidase (β-gal) enzyme: the Enzyme Donor (ED) and Enzyme Acceptor (EA) fragments which independently have no β-gal activity. However, when forced to complement they form an active β-gal enzyme that will hydrolyze substrate to produce a chemiluminescent signal. The PathHunter PD-1 Signaling Bioassay consists of human cells engineered to stably express an ED-tagged PD-1 receptor, while EA is fused to the phosphotyrosine-binding SH2 domain of the intracellular signaling protein, SHP1. Ligand or antibody-induced activation of the receptor results in phosphorylation of the receptor's cytosolic tail. The SH2-domain fused to EA binds the phosphorylated receptor, forcing complementation of ED and EA, resulting in formation of an active β-gal enzyme, which hydrolyzes the substrate to produce a chemiluminescent signal. Full-length PD-1 receptor was engineered with a small β-gal fragment (ED in red) fused to its C-terminus, and the SH2-domain of SHP1 was engineered with the complementing β-gal fragment (EA). These constructs were stably expressed in Jurkat cells (produced by DiscoverX), while PD-L1 and PD-L2 was stably expressed on artificial synapses produced by Diadem Biotherapeutics. Artificial synapses were engineered to have surface expressed human PD-L1 or PD-L2. Briefly, the gene sequence coding for the extracellular domain of human PD-L1 or PD-L2 was linked to the exosome via a glycosylphosphatidylinositol (GPI) linker with an Fc domain between the linker and PD-L1 or PD-L2 (PD-L1-Fc-GPI and PD-L2-Fc-GPI). Additional variations of the Inventors' PD-L1 and PD-L2 artificial synapses include cloning a C1C2 linker (from MFGE8) in place of the GPI linker, and with or without the Fc domain. The Inventors also cloned murine versions of PD-L1 and PD-L2 extracellular domains in place of the human PD-L1 and PD-L2 all variations. Ligand engagement, through addition of ligand-presenting artificial synapses, results in phosphorylation of PD-1, leading to the recruitment of SHP1-EA

The Inventors obtained approximately 1000×higher increase in Relative Light Units (RLU) in Jurkat signaling cells treated with PD-L1 or PD-L2 labeled artificial synapses when compared to soluble PD-L1-Fc or PD-L2-Fc ligand, respectively. Meaning, it took 1000× less ug/ml of PD-L1 or PD-L2 on artificial synapses than solubilized PD-L1-Fc or PD-L2 ligand to achieve the same RLU signaling. Results are shown in FIG. 12.

Example 10
PD-L1 In Vivo Assay—Experimental Autoimmune Uveoretinitis (EAU) in Lewis Rats Bioassay

Experimental autoimmune uveoretinitis (EAU) is an organ-specific, T lymphocyte-mediated autoimmune disease, which serves as a model for several human ocular inflammations of an apparently autoimmune nature. There is a statistically significant initial reduction in EAU in mPDL1 artificial synapse treated rats via either the intravitreal and intravenous delivery modes. 2nd intravitreal and 3rd intravenous injections are performed on Day 12. There appears to be a more rapid rate of resolution in the 1× intravitreal and intravenous groups. (C) Simplified view of aforementioned results. (D) Weight of rats was monitored throughout the study. 3rd intravitreal and 4th intravenous injections are performed on Day 16. There does not appear to be any significant change in EAU in any of the test groups. The aforementioned results provide proof of principle of successfully immunizing the rats with human cell derived artificial synapses with mouse PDL1 injected into rats. Results are shown in FIG. 13.

Example 11
Engineered Exosome Multivalent Display

The inventors have developed the following 3 types of protein display on or within exosomes:

- Type I membrane proteins wherein the N-Terminus is on the luminal (interior) side of the exosome membrane and the C-Terminus is on the exterior of the exosome.
- Type II membrane proteins wherein the N-Terminus is on the exterior while the C-Terminus is on the interior.
- Luminal internally loaded proteins which are linked to the exosome by a Myristoylation/Palmitoylation site which attaches proteins to the interior of the exosome membrane.

FIGS. 14-21 demonstrate the various embodiments of the engineered extracellular vesicles.

Additional embodiments or ligands displayed on the exosome surface (Type I and Type II membrane proteins) and internal luminal display can include the following:

- Type I: PD-L1, PD-L2, FGL1, OX40L
- Type II: 4-1BBL, GITRL, CD27L, CD30L
- Luminal: NanoLuc® luciferase; Green fluorescent protein (GFP) (e.g., eGFP, etc.); Red fluorescent protein (RFP) (e.g., mScarlet, mCherry, mRuby, tdTomato, etc.); Cyan fluorescent protein (CFP); Yellow fluorescent protein (YFP); A therapeutic protein; and CRISPR/CAS-9

FIG. 20 shows an exemplary multiple protein display construct. Sequences such as P2A, E2A, F2A, and T2A induce ribosomal slippage which prevent peptide bond formation, meaning that a single mRNA transcript with a 2A sequence will result in two separate peptides after translation. This allows the expression of two separate proteins from one promoter region and thus loading of two proteins on an exosome. Any combination of the proteins of interest domains provided herein can be engineered. Furthermore, a cell line with multiple transgene inserts under separate promoter control. Either method can be used to label Type I, Type II, and luminal display proteins.

Example 12a
Designed and Engineered Human Fusion Polypeptide Constructs

The inventors have designed, engineered, and purified the following human fusion polypeptide constructs for therapeutic use (FIG. 5A-FIG. 5WW):

- pEF5-FRT-hPDL1-C1C2 (FIG. 5I)
- pEF5-FRT-hPDL2-C1C2 (FIG. 5J)
- pEF5-FRT-hPDL1-GPI-P2A-hFGL1-GPI (FIG. 5E)
- pEF5-FRT-hCTLA4-Fc-GPI (FIG. 5C)
- pEF5-FRT-hPDL2-Fc-GPI (FIG. 5H)
- pEF5-FRT-hPD-L1-GPI-P2A-hHVEM-GPI (FIG. 5D)
- pEF5-FRT-hPDL1-GPI (FIG. 5F)
- pcDNA5-FRT-hSecPDL1-GPI (FIG. 5O)
- pcDNA5-FRT-hPDL1-GPI (FIG. 5F)
- pcDNA5-FRT-hPDL1-Link-GPI (FIG. 5T)
- pcDNA5-FRT-4F2-h41BBL (FIG. 5K)
- pcDNA5-FRT-Tfr2-h41BBL (FIG. 5P)
- pEF5-FRT-hPDL1-Fc-GPI (FIG. 5G)
- pcDNA5-FRT-CD9tm3-h41BBL (FIG. 5Q)
- pcDNA5-FRT-hPDL1-Fc-GPI (FIG. 5G)
- pcDNA5-FRT-hPDL1-4Fc-CD9tm2 (FIG. 5RR)
- pcDNA5-FRT-hPDL1-Fc-CD9tm2KRAS (FIG. 5UU)
- pcDNA5-FRT-hPDL1-4Fc-CD9tm2KRAS (FIG. 5SS)
- pcDNA5-FRT-hPDL1-4Fc-GPI (FIG. 5L)
- pcDNA5-FRT-hPDL1-ADAM10 (FIG. 5QQ)
- pcDNA5-FRT-MyrPalm-4F2-h41BBL (FIG. 5R)
- pcDNA5-FRT-MyrPalm-h41BBL (FIG. 5S)
- pcDNA5-FRT-hPDL1-Fc-CD9tm2 (FIG. 5TT)
- pcDNA5-FRT-hSecPDL1-CD9tm4 (FIG. 5W)
- pcDNA5-FRT-hSecPDL1-CD9tm2KRas (FIG. 5V)
- pcDNA5-FRT-hSecPDL1-CD9tm2 (FIG. 5U)
- pcDNA5-FRT-hSecPDL1-CD81 (FIG. 5X)
- pEF5-FRT-hCD200-Fc-GPI (FIG. 5Y)
- pEF5-FRT-hCD200-GPI (FIG. 5BB)
- pEF5-FRT-hTSG6-GPI (FIG. 5FF)
- pEF5-FRT-hPDL2-GPI (FIG. 5EE)
- pEF5-FRT-hFGL-1-GPI (FIG. 5Z)
- pEF5-FRT-hHVEM-GPI (FIG. 5DD)
- pEF5-FRT-hGal9-GPI (FIG. 5CC)
- pEF5-FRT-hHVEM-Fc-GPI (FIG. 5GG); and
- pEF5-FRT-hGal9-Fc-GPI (FIG. 5AA)

Example 12b
Designed and Engineered Fusion Polypeptide Constructs

The inventors have designed, engineered, and purified the following mouse fusion polypeptide constructs for therapeutic use (FIG. 5A-FIG. 5WW):

- pcDNA5-FRT-mPDL1-mFc-CD9tm2KRAS (FIG. 5WW)
- pcDNA5-FRT-mPDL1-mFc-CD9tm2 (FIG. 5VV)
- pcDNA5-FRT-mPDL1-mFc-GPI (FIG. 5NN)
- pcDNA5-FRT-mPDL1-GPI (FIG. 5KK)
- pEF5-FRT-mPDL2-GPI (FIG. 5. OO)
- pEF5-FRT-mPDL1-GPI-P2A-mHVEM-GPI (FIG. 5PP)
- pEF5-FRT-mPDL1-GPI (FIG. 5KK)
- pEF5-FRT-mPDL2-Fc-GPI (FIG. 5MM)
- pEF5-FRT-mPDL1-Fc-GPI (FIG. 5JJ)
- pEF5-FRT-mCTLA4-Fc-GPI (FIG. 5HH)
- pEF5-FRT-mPDL1-C1C2 (FIG. 5II); and
- pEF5-FRT-mPDL2-C1C2 (FIG. 5LL).

Example 12c
Designed and Engineered Luminal Loaded Fusion Polypeptide Constructs

The inventors have designed, engineered, and purified the following fusion polypeptide constructs for internal luminal loading of the fusion polypeptide:

- pcDNA5-FRT-Myr-NanoLuc (FIG. 5M)
- pcDNA5-FRT-Myr-mScarlet (FIG. 5N)

Example 13

Purification of Exosomes Labeled with Type I Membrane Fusion Polypeptides

The inventors have purified engineered EVs, including hPD-L1-GPI; hPDL1-Fc-GPI; hPDL2-Fc-GPI; hCTLA4-Fc-GPI; mPDL1-GPI; and mPD-L1-Fc-GPI. The process for purification and analytical processing of the engineered EVs are shown in the flow chart provided in FIG. 21. In particular, the embodiments of hPD-L1 labeled exosome constructs are shown in FIGS. 69 and 70.

Size exclusion chromatography was performed to purify hPD-L1-GPI (no Fc) exosomes (FIG. 24). Protein, RNA and DNA measurements in SEC fractions. Invitrogen Qubit fluorometric assays were used to measure biomolecules from unmodified concentrated cell media SEC fractions or hPD-L1-Exo-Tag concentrated cell media SEC fractions. PD-L1 was measured using an R&D systems PD-L1 ELISA kit. Dot-blot immunoblot analysis of SEC fractions. A 96-well dot blot apparatus was used to immobilize 50 ul of each SEC fraction onto PVDF. Exosome size and concentration was measured in fraction 7 by tunable resistive pulse sensing (TRPS). It was confirmed that GPI anchors the hPD-L1 fusion protein onto the exosomes (FIG. 25).

Furthermore, a commercially available multimodal exosome purification resin was also used to purify and isolate PD-L1-GPI exosomes and PD-L1-Fc-GPI exosomes (FIGS. 73-74). Fraction 7 was further analyzed by dot blots (FIG. 28A-8B). In particular, FIG. 28B shows SEC purification results of various embodiments of human PD-L1 displayed on the surface of extracellular vesicles. One embodiment is the hPD-L1-4Fc-GPI (CMV) construct as seen in the top dot blot (stained with rabbit monoclonal anti-PD-L1 antibody). Another embodiment is the hPD-L1-4Fc-GPI (EF1a) as seen in the top dot blot (stained with rabbit monoclonal anti-PD-L1 antibody).

Large MW exosomes elute in the first fraction as shown by the high hPD-L1 concentration and exosome quantity (2.26E9 exosomes/ml) in elution 1. Clean in place (CIP) fractions show bound and eliminated proteins from our exosome elution (FIGS. 76-77). Exosome quantity and hPD-L1 concentration was determined in SEC fractions 7-9. Knowing the molecular weight of engineered hPD-L1, we can determine the number of hPD-L1 molecules per exosome to be approximately 12 PD-L1/exosome. This value is consistent between different purification runs and constructs (FIG. 8).

FIGS. 79-80 show the purification of hPD-L2 via size exclusion chromatography. FIG. 81 shows the purification of hCTLA-4-Fc-GPI SEC fractions. Purification of the mouse PD-L1-FcGPI exosomes was also performed (FIG. 29). The mouse Fc-PD-L1 expressing exosomes have a higher valency than those that do not comprise the Fc linker.

Example 14
Comparative Proteomics Analysis of the Engineered EVs

Fc-GPI enables high density display and has a higher abundance than endogenous PTGFRN or CD81. Therefore, comparison proteomics of transprotein expression and surface labeling on the engineered exosomes, hPD-L1-Fc-GPI; hPD-L2-Fc-GPI; and hCTLA-Fc-GPI, was performed to determine the effects on endogenous protein expression in engineered exosomes. It was confirmed that the fusion polypeptide expression does not affect the relative expression of native and associated exosome proteins (FIGS. 83A-83C). However, the trans protein may crowd out abundant proteins like CD81 (data not shown).

Example 15

Scale-Up Production and Purification of mPD-L1-Fc-GPI Exosomes Using Microcarriers in a Stirred Tank Single-Use Bioreactor (STR)

1E7 HEK 293 cells were utilized for the production of mPDL1-Fc-GPI exosomes. Cells were passaged on SoloHill® Microcarriers up to Passage 4, at which point cells were expanded in a 2.5 L Stirred Tank Single-Use Bioreactor. Passage 4 cells were cultured for an additional 5 days and media was harvested on Day 5 and used for exosome purification. The general aim and process is provided below

AIM: Utilize SoloHill's Xeno-free microcarrier technology to scale up cells for engineering EVs and evaluate Microcarrier-stir tank bioreactor technology for production of therapeutic exosomes in the Xeno-free medium conditions.

Passage 1:

- Thaw vial (1.00E+07) of cells and seed Corning T-150 & CellSTACK2 tissue culture treated flask at 1.00E+04 cells per cm2 seed density.
- Perform 100% medium exchange from both flasks on day 3.
- Harvest Corning T-150 & CellSTACK2 flasks on day 4 post seeding and seed spinner microcarrier culture.

Passage 2:

- Expand cells in 2×200 mL spinner flasks at 10 cm2/mL microcarrier density using SoloHill's Xeno-free prototype microcarrier.
- Seed microcarrier cultures at 1.00E+04 cells per cm2 seed density and T-25 as flatware control flask.
- Perform 80% batch volume medium exchange from spinners and T-25 flasks on day 3.
- Harvest both microcarrier and T-25 flasks on day 4 post seeding and seed spinner microcarrier culture.

Passage 3:

- Expand cells in 3×300 mL spinner flasks at 10 cm2/mL microcarrier density using SoloHill's Xeno-free prototype microcarrier.
- Seed microcarrier cultures at 1.00E+04 cells per cm2 seed density and T-25 as flatware control flask.
- Perform 80% batch volume medium exchange from spinners and T-25 flasks on day 3.
- Harvest both microcarrier and T-25 flasks on day 4 post seeding.
- Seed microcarrier-stir tank bioreactor for exosome production.

Passage 4:

- Expand cells into a 2.5 L microcarrier-stir tank at 10 cm2/mL surface area to medium ratio.
- Seed cultures at 1.00E+04 cells per cm2 seed density and T-25 as flatware control flask.
- Perform 80% batch volume medium exchange on day 2.
- On day 3 rinse all cultures with 2×cell culture volumes of DPBS containing Ca and Mg.
- Add exosome production medium (DMEM-1% Glutamax) to all cultures at 10 cm2/mL surface area to medium volume ratio.
- On day 5 collect harvest spent medium from all cultures, filter using 0.45 μm Nalgene rapid flow system and freeze at −20° C.

Procedures:

- Medium Composition
- DMEM 1× (Corning ref #10-013-CV)
- 1% Glutamax (Thermo ref #35050061)
- 3% Human platelet lysate (Stemulate from Cook Reagentec PG-NH-500)

Cell Harvest Protocol for Planar Culture

- Settle microcarriers and remove maximum volume of spent medium without removing microcarriers.
- Wash microcarrier culture with DPBS 2× time at 0.1 mL/cm2 volume to surface area ratio.
- Add 37° C. warmed TrypLE 5× enzyme at 0.012 mL/cm2 and incubate flask at room temperature for ˜15 minutes.
- Add complete medium at 0.024 mL/cm2 to quench TrypLE 5× activity.
- Perform viable cell count using NC200 cell count instrument.

Nuclei Count Protocol for Microcarrier Culture

- Obtain 4-5 mL of microcarrier culture from bioreactor or spinner flask
- Settle microcarriers and remove maximum volume of spent medium without removing microcarriers.
- Add 1.5 mL Nucleocounter Reagent A to macrocarrier sample tube and vortex at high speed for a minute.
- Add 1.5 mL Nucleocounter Reagent B to macrocarrier sample tube and vortex at high speed for a minute.
- Perform nuclei count using NC200 nuclei count instrument.
  
  Medium Collection from STR Bioreactor
- Stop all controls and settle microcarriers in the bioreactor vessel.
- Pump out medium through screen bag into collection bottle at 200 mL/minute flowrate using peristaltic pump.
- Inside BSC pour medium into 0.45 μm Nalgene rapid flow filter system and remove free floating cells.
- Freeze medium bottles in minus 20° C. freezer.
  
  Medium Collection from Spinner Flasks
- Inside BSC pour microcarrier culture into 0.45 μm Nalgene rapid flow filter system and remove free floating cells as well as microcarriers.
- Freeze medium bottles in minus 20° C. freezer.

TABLE 6

Cell culture set points

Temper-

Dissolved

ature
Agitation
Oxygen

Incubator %

° C.
rpm
(DO) %
pH
CO₂setting

T - Flask
37
n/a
n/a
n/a
5 ± 1

CellSTACK 2
37
n/a
n/a
n/a
5 ± 1

Spinner flask
37
35
n/a
n/a
5 ± 1

STR bioreactor
37
35
50
7.35
n/a

FIG. 31 shows mPDL1-Fc-GPI production, growth parameters, and analyte concentrations from a 2.6 L culture in a Stirred Tank Single-Use (STR) bioreactor. Day 2: 80% batch volume medium was exchanged (1^stincrease in glucose and decreased in lactate) Day 3: rinse culture with 2×cell culture volumes of DPBS containing Ca and Mg. (2^ndincrease in glucose and decreased in lactate). Add exosome production medium (DMEM-1% Glutamax) to culture at 10 cm²/mL surface area to medium volume ratio.

mPDL1 was purified using the purification process outlined above (FIGS. 32-33).

Example 16
PD-L1-Fc-GPI and PDL2-Fc-GPI Exosomes Increase PD-1 Signaling

The purified exosomes were tested using the modified DiscoverX Assay in FIG. 12A. Approximately a 1000× increase in Relative Light Units (RLU) was achieved for Jurkat signaling cells treated with PD-L1 or PD-L2 labeled exosomes when compared to soluble PD-L1-Fc or PD-L2-Fc ligands alone, respectively. Therefore, it takes 1000× less μg/ml of PD-L1 or PD-L2 on the engineered exosomes to activate PD-1 over solubilized ligands, PD-L1-Fc or PD-L2, achieve the same RLU signaling. FIG. 12B show a dose-response curves for the PD-L1 and PD-L2 exosomes vs soluble PD-L1 and PD-L2 signaling bioassay. FIG. 12B shows dose-response curves for the PD-L1 and PD-L2 exosomes comprising an Fc linker and GPI sticky binder vs. soluble ligands with an Fc domain linker. These results show that the PD-L1 and PD-L2 polypeptides fused with the Fc and GPI domains on EVs have a more potent effect on PD-1 signaling than the soluble ligands alone.

Example 17

In Vivo Assay—Therapeutic Effect of mPD-L1 Exosomes in an Experimental Autoimmune Uveoretinitis (EAU) Model in Lewis Rats

Lewis rats were challenged with retinal antigen interphotoreceptor retinoid-binding protein (IRBP) peptide. This model can be used to study anterior and posterior chamber dependent EAU. Rats were immunized on Day 1 with EAU presenting typically at Day 6. Clinical scores in the rat were determined. The EAU dosing schedule is shown in FIG. 13A. EAU dosing test article are shown in the following table (Table 7).

TABLE 7

EAU dosing test articles

Unmodified
mPD-L1-Fc-GPI
mPD-L1-Fc-GPI
mPD-L1

Exosomes
Exosomes 1X
Exosomes 10X
Exosomes

(IVT)
(IVT)
(IVT)
(IV)

Dose
2
ul
2
ul
2
ul
5
ml/kg

Total protein
40
ug/ml
40
ug/ml
400
ug/ml
40
ug/ml

concentration

Total protein
80
ng/eye
80
ng/eye
800
ng/eye
50 ug/animal

administered

(~200 ug/kg)

Exosome
5.7 × 10¹⁰/ml
2.34 × 10¹⁰/ml
2.34 × 10¹¹/ml
2.34 × 10¹⁰/ml

concentration

Total exosomes
4.7 × 10⁷
4.7 × 10⁷
4.7 × 10⁸
2.93 × 10¹⁰

administered

*IVT—intravitreal,

IV—intravenous

The study design is outlined below (Table 8):

TABLE 8

Study design

Group
Test Article
N
Route
Concentration
Dosage
Regimen

1
Cyclosporine
8
p.o.
1 mg/mL
10
mg/kg
BID from day 0

to Day 20

2
Negative control
8
Intravitreal
1X
2-3
μL
Day 6, Day 12,

(PBS vehicle)

both eyes

and Day16

3
Unmodified exosomes
8
Intravitreal
1X (~40
ug/ml)
2-3
μL
Day 6 and

(Control exosomes)

both eyes

Day 12

4
mPD-L1-Fc-GPI
8
Intravitreal
1X (~40
ug/ml)
2-3
μL
Day 6, Day 12,

(40 ug/ml)

both eyes

and Day16

5
mPD-L1-Fc-GPI
4
Intravenous
1X (~40
ug/ml)
5
mL/kg
Day 1, Day 6,

(40 ug/ml)

Injection

Day 12, and

Day 16

6
No IRBP peptide
4
Intravitreal
1X (~40
ug/ml)
2-3
μL
Day 6, Day 12,

but treated with

both eyes

and Day 16

Test Agent B

(for tolerability)

7
mPD-L1-Fc-GPI
8
Intravitreal
1X (400
ug/ml)
2-3
μL
Day 6, Day 12,

(400 ug/ml)

both eyes

and Day 16

Clinical Scores were determined as follows:

TABLE 9

EAU Clinical Scores in Rats

Score
Clinical Criteria

0
No disease; eye is translucent and reflects light(red reflex)

0.5
Dilated blood vessels in the iris

(trace)

1
Engorged blood vessels in the iris; abnormal pupil contraction

2
Hazy anterior chamber; decreased red reflex

3
Moderately opaque anterior chamber, but pupil still visible;

dull red reflex

4
Opaque anterior chamber and obscured pupil; red reflex absent;

proptosis

Each higher grade includes the criteria of the preceding one.

It was discovered that there is a statistically significant initial reduction in EAU in mPDL1 exosome treated rats via either the intravitreal and intravenous delivery modes as compared with untreated animals (FIG. 13A). Rat weight did not change post immunization (FIG. 13C).

Example 18

Purification of Exosomes Labeled with Type II Membrane Proteins

The inventors designed, engineered, and purified pcDNA5-FRT-4F2-4-1BBL exosomes by the methods provided herein (FIG. 34). Several embodiments of the 4-1BBL labeled exosomes are shown in FIG. 35. Cell expression of the 4F2-4-1BBL was confirmed (data not shown). FIGS. 92A-92B shows the purification of 4F2-4-1BBL exosomes.

Example 19
Purification of Luminal Labeled Exosomes (Internal Loading)

In addition to Type I and Type II display fusion proteins on the surface of an EV, exosomes can be loaded with fusion proteins that are localized to the lumen of the phopholipid bilayer of the exosome (FIG. 37). The Myr/Palm sequence used herein when fused to mScarlet the fusion protein into the luminal interior of extracellular vesicles. Fluorescence at an excitation wavelength 470 nm and emission wavelength of 665-720 nm peaks in SEC fractions 7, 8, and 9. SEC fractions 7, 8, and 9 contain exosomes as demonstrated by the dot blot. Fraction 8 was further analyzed for exosome quantification using an ExoView system (FIG. 38). Unmodified exosomes do not show fluorescence. Exosomes show near 80% loading with Myr/Palm-mScarlet. The remaining 20% were out of the detection limit. Thus, nearly 100% internal loading was achieved using the specific Myr/Palm sequence.

NanoLuc luciferase expressing exosomes were also purified with the Myr/Palm sequence incorporated into the vector encoding the fusion polypeptide. A Qubit fluorometer was used to measure total protein and Promega Nano-Glo substrate and plate luminometer to measure luminescence (FIG. 39A). Tetraspanin characterization of exosomes was performed and determined that the NanoLuc luciferase exosomes were internally loaded and purified in fraction 8 (FIG. 39B).

	Number	Date	Country
Parent	17396947	Aug 2021	US
Child	18942113		US
Parent	PCT/US2021/016949	Feb 2021	WO
Child	17396947		US

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