Patent Application
20230148144
The present invention relates to effector immune cells which specifically bind an antigen recognition receptor of a target immune cell and in particular to approaches to control killing of such effector immune cells by the target cells.
In solid organ transplants or hematopoietic stem cell transplants (HSCT), mismatches in HLA between recipient and donor can lead to rejection of the organ or graft-vs-host disease (GVHD) respectively. Immunosuppressive drugs can mitigate these outcomes but, due to their broadly inhibitory action against immune cells, they increase the risk of opportunistic infections.
Alloreactive T-cells that recognise mismatches HLA via their T-cell receptor (TCR) are major mediators of rejection and GVHD. CD8+ T cell specificity is dictated by the clonotypic TCR which recognises short antigenic peptides presented on MHC class I molecules. MHC class I molecules are non-covalent heterodimers made up of the membrane-integral, highly polymorphic α-chain and the non-membrane attached non-polymorphic β2 microglobulin (β2m).
Margalit et al ((2002) International Immunology 15:1379-1387) describe an approach to convert TCR ligands into T-cell activation receptors. They describe T-cells expressing a β2 microglobulin polypeptide which comprises a transmembrane domain and CD3ζ-derived endodomain attached to the C-terminus and an antigenic peptide attached to the N-terminus via a linker. Such cells were found to express a high level of surface peptide-class I complexes and to respond to antibodies and target T-cells in a peptide specific manner. By expressing such a peptide-linker-β2m-TM-CD3ζ polypeptide in T-cells it is possible to specifically target pathogenic CD8=T cells recognising a particular antigenic peptide.
Traditionally, antigen-specific T-cells have been generated by selective expansion of peripheral blood T-cells natively specific for the target antigen. However, it is difficult and quite often impossible to select and expand large numbers of T-cells specific for most cancer antigens. Gene-therapy with integrating vectors affords a solution to this problem as transgenic expression of Chimeric Antigen Receptor (CAR) allows generation of large numbers of T-cells specific to any surface antigen by ex vivo viral vector transduction of a bulk population of peripheral blood T-cells.
Chimeric antigen receptors are proteins which graft the specificity of a monoclonal antibody (mAb) to the effector function of a T-cell. Their usual form is that of a type I transmembrane domain protein with an antigen recognizing amino terminus, a spacer, a transmembrane domain all connected to a compound endodomain which transmits T-cell survival and activation signals.
The most common forms of these molecules are fusions of single-chain variable fragments (scFv) derived from monoclonal antibodies which recognize a target antigen, fused via a spacer and a trans-membrane domain to a signalling endodomain. Such molecules result in activation of the T-cell in response to recognition by the scFv of its target. When T cells express such a CAR, they recognize and kill target cells that express the target antigen. Several CARs have been developed against tumour associated antigens, and adoptive transfer approaches using such CAR-expressing T cells are currently in clinical trial for the treatment of various cancers.
After infusion, CAR T-cells engraft within the recipient and proliferate after encountering target bearing cells. CAR T-cells then persist and their population slowly contracts over time. CAR T-cell persistence can be determined in clinical studies by real-time PCR for the transgene in blood samples or by flow-cytometry for the CAR in blood samples and clinical researchers have found a correlation between persistence and sustained responses. This correlation is particularly pronounced in CD19 CAR therapy of B-Acute lymphoblastic leukaemia (ALL). Often in this setting, loss of CAR T-cell engraftment heralds relapse of the leukaemia.
CAR T-cells can result in activation of a cellular mediated immune response which can trigger rejection of the CAR T-cells. This is due to immunogenicity of the components engineered into the cell either through non-self proteins or through non-self sequences formed from junctions between self-proteins used to make receptors and other engineering components.
CARs are artificial proteins which are typically composed of a targeting domain, a spacer domain, a transmembrane domain and a signaling domain. The targeting domain is typically derived from an scFv which may be murine. While this scFv can be human or humanized and other components individually are derived from self-proteins, the junctions between them can still be immunogenic. For instance, within the scFv there are junctions between the heavy chain and the linker and the linker and the light chain. There is then a junction between the scFv and the spacer domain.
If the transmembrane domain is not continuous with the spacer there is a further junction there. Similarly, if the transmembrane domain is not continuous with the amino-terminal portion of the endodomain, there is a further junction there. Finally, most endodomains have at least two components and sometimes more with junctions subsequently between each component.
In addition, CAR T-cells are often engineered with further components. These components include suicide genes (e.g. the HSV-TK enzyme). This enzyme was found to be highly immunogenic and caused a cellular immune depletion of CAR T-cells outside of the context of the profound immunosuppression of haploidentical haematopoietic stem cell transplantation. Other less immunogenic suicide genes may still provide some immunogenicity, as almost every kind of engineered component which involves a fusion between two proteins or use of a xenogeneic protein can be immunogenic.
In many settings, CAR T-cells are generated from autologous T-cells. In this setting, allo-responses do not occur. In some circumstances, T-cells from an allogeneic donor are used. This can occur if for instance the patient has had an allogeneic haematopoietic stem cell transplant. In this case, harvested T-cells will be allogeneic. Otherwise, a patient may have insufficient T-cells to generate a CAR T-cell product due to chemotherapy induced lymphopenia.
Rejection of allogeneic cells can be due to minor mismatch or major mismatch. Minor mismatch occurs in the setting where allogeneic T-cells are human leukocyte antigen (HLA)-matched to the recipient. In this case, rejection occurs due to minor histocompatibility antigens which are non-HLA differences between individuals which result in presentation of non-self (donor) epitopes/immunogenic peptides on HLA. In the case where donor and recipient are mismatched, or are only partially matched. T-cell receptors (TCR) on endogenous T-cells of a recipient can interact in a non-specific way with a mismatched HLA and cause rejection consequently. Both minor and major forms of allogeneic rejection are caused by HLA interacting with TCR.
WO2019/073248 and GB application No. 1904971.7 describe an approach which involves coupling the binding of an MHC class I or II on a CAR-expressing cell to a TCR on a T-cell to induce—directly or indirectly—signalling in the CAR-expressing cell. When the CAR-expressing cell is administered to a subject, the MHC class I or II on this cell interacts with any endogenous, reactive T-cells present in the subject through recognition of peptide/MHC complexes. Any such reactive T-cells in the subject are depleted by activation of cytotoxic-mediated cell killing by the CAR-expressing cell.
CAR-mediated approaches to treat T-cell malignancies Lymphoid malignancies can largely be divided into those which are derived from either T-cells or B-cells. T-cell malignancies are a clinically and biologically heterogeneous group of disorders, together comprising 10-20% of non-Hodgkin's lymphomas and 20% of acute leukaemias. The most commonly identified histological subtypes are peripheral T-cell lymphoma, not otherwise specified (PTCL-NOS); angio-immunoblastic T-cell lymphoma (AITL) and anaplastic large cell lymphoma (ALCL). Of all acute Lymphoblastic Leukaemias (ALL), some 20% are of a T-cell phenotype.
These conditions typically behave aggressively, compared for instance with B-cell malignancies, with estimated 5-year survival of only 30%. In the case of T-cell lymphoma, they are associated with a high proportion of patients presenting with disseminated disease, unfavourable International Prognostic Indicator (IPI) score and prevalence of extra-nodal disease. Chemotherapy alone is not usually effective and less than 30% of patients are cured with current treatments.
WO2015/132598 describes a method whereby it is possible to deplete malignant T-cells in a subject, without affecting a significant proportion of healthy T cells. In particular WO2015/132598 describes CARs which specifically bind TCR beta constant region 1 (TRBC1) or TRBC2.
All of the approaches mentioned above, involve the specific binding of a T-cell receptor on a target T-cell. In this situation the targeted T-cell can “fight back” due to ligation of its TCR, resulting in depletion of the grafted/desirable T-cells.
Major Histocompatibility Complex (MHC) Class I CAR is a heterodimer composed of two non-covalently linked polypeptide chains, α and β2-microglobulin (β2m). The α1 and α2 subunits together with a loaded peptide bind to a T-cell receptor (TCR) expressed on the surface of T cells. β2-microglobulin is connected to a transmembrane domain which anchors the molecule in the cell membrane and is further linked to an endodomain which acts to transmit intracellular signals to the cell. The endodomain can be composed of one or more signalling domains.
In the first CAR (A) β2-microglobulin is linked via a bridge to the CD3ζ transmembrane domain which is then linked to the CD3ζ; endodomain. Two other CAR designs (B and C) have added co-stimulatory domains, 41 BB or CD28 respectively.
(a) MHC class I molecules are heterodimers that consist of two polypeptide chains, a and β2-microglobulin (B2M); (b) The TCR complex which is composed of TCRalpha/beta chains surrounded by CD3 elements
(a) MHCIα-CD3z construct: The MHC class I alpha chain is fused in frame to a TM domain and CD3-zeta endodomain; (b) Ab-CD3z construct: An antibody or antibody-like binder specific to MHC class I alpha chain is fused to a TM domain and CD3-zeta endodomain; (c) Fusion between MHCIα and CD3/TCR: As an example, a fusion between MHC class I alpha chain via a flexible linker to CD3 Epsilon is shown; (d) MHCIα-TCR BiTE construct: a scFv which recognizes MHC class I alpha chain is fused with a linker to a second scFv which recognizes the CD3/TCR complex. This is then anchored to the membrane via a transmembrane domain.
(a) MHC class II molecules are heterodimers that consist an α chain and a β chain; (b) The TCR complex which is composed of TCRalpha/beta chains surrounded by CD3 elements
(a) MHCII-CD3z construct: The MHC class II α or β chain is fused to a TM domain and CD3-zeta endodomain; (b) Ab-CD3z construct: An antibody or antibody-like binder specific to MHC class II α or β chain is fused to a TM domain and CD3-zeta endodomain; (c) Fusion between MHCII and CD3/TCR: MHC class I α or β chain is fused via a flexible linker to a component of the TCR/CD3 complex. For example, CD3 Epsilon is shown; (d) MHCII-TCR BiTE construct: a scFv which recognizes MHC class II α or β chain is fused with a linker to a second scFv which recognizes the CD3/TCR complex. This is then anchored to the membrane via a transmembrane domain.
CD4 and CD8 are TCR co-receptors. The extracellular domain of CD4 binds to the β2 region of MHC class II; whereas the extracellular domain of CD8 binds the α3 portion of the Class I MHC molecule. (a) CD4-CD3z construct: the MHC class II-binding domain of CD4 is fused to a TM domain and CD3-zeta endodomain; (b) CD8-CD3z construct: the MHC class I-binding domain of CD8 is fused to a TM domain and CD3-zeta endodomain
A—Wild-type CSK having a SH3 domain, an SH2 domain and a protein tyrosine kinase domain.
B—dnCSK lacking a kinase domain
C—dnCSK lacking a kinase domain and an SH3 domain
6—dnCSK having a mutation K222R.
The present inventors have developed approaches for engineering an effector immune cell (cell A) such that, when targeting an autoreactive or pathogenic immune cell (cell B), the engineered immune cell has a selective advantage and the balance between the cell A killing cell B; and cell B killing cell A is tipped in favour of cell A killing cell B.
Thus in a first aspect, the present invention provides an effector immune cell which expresses a cell surface receptor or receptor complex which specifically binds an antigen recognition receptor of a target immune cell; which effector immune cell is engineered such that when a synapse is formed between the effector immune cell and the target immune cell, the capacity of the effector immune cell to kill the target immune cell is greater than the capacity of the target immune cell to kill the effector immune cell.
In a first embodiment of the first aspect of the invention, the effector immune cell is engineered to be resistant to an immunosuppressant.
For example, the effector immune cell may be engineered to be resistant to one or more calcineurin inhibitors.
In this respect, the effector immune cell may express:
The effector immune cell may be engineered to be resistance to rapamycin.
The effector immune cell may express a dominant negative C-terminal Src kinase (dnCSK), which confers resistance to multiple immunosuppressants.
In a second embodiment of the first aspect of the invention, the effector immune cell is engineered to express or overexpress an immunoinhibitory molecule or a fusion protein comprising the extracellular domain of an immunoinhibitory molecule.
The immunoinhibitory molecule may bind to: PD-1, LAG3, TIM-3, TIGIT, BTLA, VISTA, CEACAM1-R, KIR2DL4, B7-H3 or B7-H4.
The immunoinhibitory molecule may be selected from: PD-L1, PD-L2, HVEM, CD155, VSIG-3, Galectin-9, HLA-G, CEACAM-1, LSECTin, FGL1, B7-H3, and B7-H4.
The effector immune cell may be engineered to express a fusion protein comprising the extracellular domain of an immunoinhibitory molecule and a membrane localisation domain.
The effector immune cell may be engineered to express a fusion protein comprising the extracellular domain of an immunoinhibitory molecule and a co-stimulatory endodomain, such as one selected from CD28, ICOS, CTLA4, 41BB, CD27, CD30, OX-40, TACI, CD2, CD27 and GITR.
The antigen recognition receptor of the target immune cell may, for example, be a T-cell receptor (TCR) or an activating killer cell immunoglobulin-like receptor (KAR).
The cell surface receptor of the effector immune cell may, for example, be a chimeric antigen receptor (CAR) and the antigen recognition receptor is a T-cell receptor (TCR).
Where the effector immune cell expresses a TCR-specific CAR, the CAR may bind TCR beta constant region 1 (TRBC1) or TRBC2.
Alternatively, the cell surface receptor complex of the effector immune cell may be an engineered MHC class I or an engineered MHC class II complex.
For example, the cell surface receptor complex may comprise: an MHC class I polypeptide; an MHC class II polypeptide; or β-2 microglobulin, linked to an intracellular signalling domain.
The cell surface receptor complex may be an engineered MHC class I complex which comprises a molecule having the following structure:
peptide-L-α2M-endo
in which:
“peptide” is a peptide which binds the peptide binding groove of the MHC class I α-chain;
“L” is a linker
“B2M” is β-2 microglobulin; and
“endo” is an intracellular signalling domain.
The effector immune cell may comprise an MHC class I polypeptide: an MHC class II polypeptide; or β-2 microglobulin, linked to a component of the TCR/CD3 complex.
The effector immune cell may comprise an MHC class I polypeptide: an MHC class I polypeptide; an MHC class II polypeptide; or β-2 microglobulin, linked to CD3-zeta, CD3-epsilon, CD3-gamma or CD3-delta via a linker peptide.
The effector immune cell may express a bispecific polypeptide which comprises: (i) a first binding domain which binds an MHC class I polypeptide; an MHC class II polypeptide; or β-2 microglobulin; and (ii) a second binding domain which binds to a component of the TCR/CD3 complex.
The effector immune cell may express an engineered polypeptide which comprises a CD79 α and/or a CD79 β chain linked to an intracellular signalling domain.
The effector immune cell may express an engineered polypeptide which comprises a binding domain which binds to an MHC class I polypeptide or an MHC class II polypeptide, linked to an intracellular signalling domain. The binding domain may be an antibody-like binding domain.
The effector immune cell may express an engineered polypeptide which comprises the MHC class II-binding domain of CD4, or the MHC class I-binding domain of CD8, linked to an intracellular signalling domain.
The effector immune cell of the first aspect of the invention may be engineered to express a cell surface receptor (such as a CAR) or receptor complex (such as an engineered MHC class I or an engineered MHC class II complex) and then further engineered such that when a synapse is formed between the effector immune cell and the target immune cell, the capacity of the effector immune cell to kill the target immune cell is greater than the capacity of the target immune cell to kill the effector immune cell.
The further engineering of the effector immune cell may involve:
The synapse which is formed between the effector immune cell and the target immune cell is formed when the cell surface receptor or receptor complex of the effector immune cell specifically binds the antigen recognition receptor of the target immune cell.
In a second aspect, there is provided a nucleic acid construct which comprises:
In a third aspect, there is provided a vector comprising a nucleic acid construct according to the second aspect of the invention.
In a fourth aspect there is provided a kit of vectors comprising:
In a fifth aspect, there is provided a pharmaceutical composition comprising a plurality of effector immune cells according to the first aspect of the invention.
In a sixth aspect there is provided a pharmaceutical composition according to the fifth aspect of the invention for use in treating a disease.
In a seventh aspect, there is provided a method for treating a disease, which comprises the step of administering a pharmaceutical composition according to the fifth aspect of the invention to a subject.
The method may comprise the following steps:
In an eighth aspect, there is provided the use of a plurality of effector immune cells according to the first aspect of the invention in the manufacture of a medicament for the treatment of a disease.
The disease may be cancer.
In an ninth aspect, there is provided a method for making an effector immune cell according to the first aspect of the invention, which comprises the step of introducing: a nucleic acid construct according to the second aspect of the invention, a vector according to the third aspect of the invention or a kit of vectors according to the fourth aspect of the invention, into the cell ex vivo.
In a tenth aspect, there is provided a method for depleting alloreactive immune cells from a population of immune cells, which comprises the step of contacting the population of immune cells with a plurality of effector immune cells according to the first aspect of the invention wherein the plurality of effector immune cells express an engineered MHC class I or an MHC class II complex as defined herein.
In an eleventh aspect, there is provided a method for treating or preventing graft rejection following allotransplantation, which comprises the step of administering a plurality of effector immune cells derived from the donor subject to the recipient subject for the allotransplant, wherein the plurality of effector immune cells express an engineered MHC class I or an MHC class II complex as defined herein.
In a twelfth aspect, there is provided a method for treating or preventing graft versus host disease (GVHD) associated with allotransplantation, which comprises the step of contacting the allotransplant with administering a plurality of effector immune cells according to the first aspect of the invention, wherein the plurality of effector immune cells express an engineered MHC class I or an MHC class II complex as defined herein.
The allotransplantation may comprise adoptive transfer of allogeneic or autologous immune cells.
In a thirteenth aspect, there is provided an allotransplant which has been depleted of alloreactive immune cells by a method according to the twelfth aspect of the invention.
Some clinical applications involve generating effector immune cells which recognize and deplete a subset of normal immune cells by recognizing their antigen-recognition receptor.
In this situation the targeted, normal immune cell can “fight back”, causing depletion of the effector immune cell. The present invention is concerned with engineering the effector immune cell so that it has an immunological “advantage” over the target immune cell, so that when a synapse is formed between the effector immune cell and the targeted immune cell, the effector immune cell will prevail.
There are various situations in which this effector cell “fight-back” can occur, including:
(i) where the effector immune cell expresses a CAR which specifically binds the T-cell receptor of a T cell;
(ii) where the effector immune cell expresses an engineered MHC I or II complex so that it depletes alloreactive or autoreactive T cells.
These situations are explained in more detail below.
The effector immune cell of the present invention may express a chimeric antigen receptor (CAR). In particular, it may express a CAR which specifically binds a component of the T-cell receptor (TCR) or TCR:CD3 complex.
A classical chimeric antigen receptor (CAR) is a chimeric type I trans-membrane protein which connects an extracellular antigen-recognizing domain (binder) to an intracellular signalling domain (endodomain) (see
Early CAR designs had endodomains derived from the intracellular parts of either the γ chain of the FcεR1 or CD3ζ. Consequently, these first generation receptors transmitted immunological signal 1, which was sufficient to trigger T-cell killing of cognate target cells but failed to fully activate the T-cell to proliferate and survive. To overcome this limitation, compound endodomains have been constructed: fusion of the intracellular part of a T-cell co-stimulatory molecule to that of CD3ζ results in second generation receptors which can transmit an activating and co-stimulatory signal simultaneously after antigen recognition. The co-stimulatory domain most commonly used is that of CD28. This supplies the most potent co-stimulatory signal—namely immunological signal 2, which triggers T-cell proliferation. Some receptors have also been described which include TNF receptor family endodomains, such as the closely related OX40 and 41 BB which transmit survival signals. Even more potent third generation CARs have now been described which have endodomains capable of transmitting activation, proliferation and survival signals.
When the CAR binds the target-antigen, this results in the transmission of an activating signal to the T-cell it is expressed on. Thus the CAR directs the specificity and cytotoxicity of the T cell towards tumour cells expressing the targeted antigen.
CARs typically therefore comprise: (i) an antigen-binding domain; (ii) a spacer; (iii) a transmembrane domain; and (iii) an intracellular domain which comprises or associates with a signalling domain.
A CAR may have the general structure:
Antigen binding domain-spacer domain-transmembrane domain-intracellular signaling domain (endodomain).
The antigen binding domain is the portion of the CAR which recognizes antigen. In a classical CAR, the antigen-binding domain comprises: a single-chain variable fragment (scFv) derived from a monoclonal. CARs have also been produced with domain antibody (dAb), VHH or Fab-based antigen binding domains.
Alternatively a CAR may comprise a ligand for the target antigen. For example, B-cell maturation antigen (BCMA)-binding CARs have been described which have an antigen binding domain based on the ligand a proliferation inducing ligand (APRIL).
Classical CARs comprise a spacer sequence to connect the antigen-binding domain with the transmembrane domain and spatially separate the antigen-binding domain from the endodomain. A flexible spacer allows the antigen-binding domain to orient in different directions to facilitate binding.
A variety of sequences are commonly used as spacers for CAR, for example, an IgG1 Fc region, an IgG1 hinge, or a human CD8 stalk.
WO2016/151315 describes spacers which form coiled-coil domains and form multimeric CARs. For example, it describes a spacer based on the cartilage-oligomeric matrix protein (COMP) which forms pentamers. A COMP spacer may comprise the sequence shown as SEQ ID No. 1 or a truncated version thereof which retains the capacity to form coiled-coils and therefore multimers.
The transmembrane domain is the portion of the CAR which spans the membrane. The transmembrane domain may be any protein structure which is thermodynamically stable in a membrane. This is typically an alpha helix comprising of several hydrophobic residues. The transmembrane domain of any transmembrane protein can be used to supply the transmembrane portion of the CAR. The presence and span of a transmembrane domain of a protein can be determined by those skilled in the art using the TMHMM algorithm (http://www.cbs.dtu.dk/services/TMHMM-2.0/). Alternatively, an artificially designed TM domain may be used.
The endodomain is the signal-transmission portion of the CAR. It may be part of or associate with the intracellular domain of the CAR. After antigen recognition, receptors cluster, native CD45 and CD148 are excluded from the synapse and a signal is transmitted to the cell. The most commonly used endodomain component is that of CD3-zeta which contains 3 ITAMs. This transmits an activation signal to the T cell after antigen is bound. CD3-zeta may not provide a fully competent activation signal and additional co-stimulatory signalling may be needed. Co-stimulatory signals promote T-cell proliferation and survival. There are two main types of co-stimulatory signals: those that belong the Ig family (CD28, ICOS) and the TNF family (OX40, 41BB, CD27, GITR etc). For example, chimeric CD28 and OX40 can be used with CD3-Zeta to transmit a proliferative/survival signal, or all three can be used together.
The endodomain may comprise:
(i) an ITAM-containing endodomain, such as the endodomain from CD3 zeta; and/or
(ii) a co-stimulatory domain, such as the endodomain from CD28 or ICOS; and/or
(iii) a domain which transmits a survival signal, for example a TNF receptor family endodomain such as OX-40, 4-1BB, CD27 or GITR.
A number of systems have been described in which the antigen recognition portion is on a separate molecule from the signal transmission portion, such as those described in WO015/150771; WO2016/124930 and WO2016/030691. The CAR of the present invention may therefore comprise an antigen-binding component comprising an antigen-binding domain and a transmembrane domain; which is capable of interacting with a separate intracellular signalling component comprising a signalling domain.
The vector of the invention may express a CAR signalling system comprising such an antigen-binding component and intracellular signalling component.
The CAR may comprise a signal peptide so that when it is expressed inside a cell, the nascent protein is directed to the endoplasmic reticulum and subsequently to the cell surface, where it is expressed. The signal peptide may be at the amino terminus of the molecule.
A ‘target antigen’ is an entity which is specifically recognised and bound by the antigen-binding domain of a CAR.
The target antigen may be an antigen present on a cancer cell, for example a tumour-associated antigen.
Various tumour associated antigens (TAA) are known, as shown in the following Table 1. The CAR may be capable of binding such a TAA.
The effector immune cell of the invention may bind to the T-cell receptor (TCR) complex on a target T-cell. In particular, the effector immune cell of the invention may bind to the TCR β-constant region (TRBC) of a TCR complex on a target T-cell.
The T-cell receptor (TCR) is expressed on the surface of T lymphocytes and is responsible for recognizing antigens bound to major histocompatibility complex (MHC) molecules. When the TCR engages with antigenic peptide and MHC (peptide/MHC), the T lymphocyte is activated through a series of biochemical events mediated by associated enzymes, co-receptors, specialized adaptor molecules, and activated or released transcription factors.
The TCR is a disulfide-linked membrane-anchored heterodimer normally consisting of the highly variable alpha (a) and beta (p) chains expressed as part of a complex with the invariant CD3 chain molecules. T-cells expressing this receptor are referred to as α:β (or αβ) T-cells (˜95% total T-cells). A minority of T-cells express an alternate receptor, formed by variable gamma (γ) and delta (δ) chains, and are referred to as γδ T-cells (˜5% total T cells).
Each α and β chain is composed of two extracellular domains: Variable (V) region and a Constant (C) region, both of Immunoglobulin superfamily (IgSF) domain forming antiparallel β-sheets. The constant region is proximal to the cell membrane, followed by a transmembrane region and a short cytoplasmic tail, while the variable region binds to the peptide/MHC complex. The constant region of the TCR consists of short connecting sequences in which a cysteine residue forms disulfide bonds, which forms a link between the two chains.
The variable domains of both the TCR α-chain and β-chain have three hypervariable or complementarity determining regions (CDRs). The variable region of the β-chain also has an additional area of hypervariability (HV4), however, this does not normally contact antigen and is therefore not considered a CDR.
The TCR also comprises up to five invariant chains γ,δ,ε (collectively termed CD3) and ζ. The CD3 and ζ subunits mediate TCR signalling through specific cytoplasmic domains which interact with second-messenger and adapter molecules following the recognition of the antigen by αβ or γδ. Cell-surface expression of the TCR complex is preceded by the pair-wise assembly of subunits in which both the transmembrane and extracellular domains of TCR α and β and CD3 γ and δ play a role.
TCRs are therefore commonly composed of the CD3 complex and the TCR α and β chains, which are in turn composed of variable and constant regions.
The locus (Chr7:q34) which supplies the TCR β-constant region (TRBC) has duplicated in evolutionary history to produce two almost identical and functionally equivalent genes: TRBC1 and TRBC2, which differ by 4 amino acids in the mature protein. Each TCR will comprise, in a mutually exclusive fashion, either TRBC1 or TRBC2 and as such, each αβ T-cell will express either TRBC1 or TRBC2, in a mutually exclusive manner.
The effector immune cell may be capable of selectively binding to either TRBC1 or TRBC2 in a mutually exclusive manner.
As explained above, each αβ T-cell expresses a TCR which comprises either TRBC1 or TRBC2. In a clonal T-cell disorder, such as a T-cell lymphoma or leukaemia, malignant T-cells derived from the same clone will all express either TRBC1 or TRBC2.
When a TRBC1- or TRBC2-specific CAR-T cell is administered to patient having a T-cell lymphoma or leukaemia, the result is selective depletion of the malignant T-cells, together with normal T-cells which express the same TRBC as the malignant T-cells, but such treatment does not cause significant depletion of normal T-cells expressing the other TRBC from the malignant T-cells.
Because the TRBC selective CAR-T cell does not cause significant depletion of normal T-cells expressing the other TRBC from the malignant T-cells it does not cause depletion of the entire T-cell compartment. Retention of a proportion of the subject's T-cell compartment (i.e. T-cells which do not express the same TRBC as the malignant T-cell) results in reduced toxicity and reduced cellular and humoral immunodeficiency, thereby reducing the risk of infection.
CAR-T cells specific for TRBC1 and TRBC2 are described in International application No. WO2015/132598.
A CAR which selectively binds TRBC1 may have a variable heavy chain (VH) and a variable light chain (VL) which comprises the following complementarity determining regions (CDRs):
The one or more CDRs each independently may or may not comprise one or more amino acid mutations (eg substitutions) compared to the sequences given as SEQ ID No. 8 to 13, provided that the resultant antibody retains the ability to selectively bind to TRBC1.
The antigen-binding domain of a TRBC1 selective CAR may comprise a variable heavy chain (VH) having the amino acid sequence shown as SEQ ID No. 8 and a variable light chain (VL) having the amino acid sequence shown as SEQ ID No. 9.
The CAR may comprise an ScFv having the amino acid sequence shown as SEQ ID No. 10.
CAR-T cells specific for TRBC2 are described in International application No. PCT/GB2019/053100.
A TRBC 2-specific CAR may have an antigen-binding domain which comprises at least one mutation in the VH domain compared to a reference antibody having a VH domain with the sequence shown in SEQ ID NO: 7 and a VL domain with the sequence shown in SEQ ID NO: 8, in which at least one mutation in the VH domain is selected from T28K, Y32K and A100N. Such an antigen-binding domain should display an increased affinity for TRBC2 over the TRBC-1 binding reference antibody, JOVI-1.
The variant antigen-binding domain may comprise at least two mutations in the VH domain selected from T28K, Y32K and A100N. For example, it may comprise mutations Y32K and A100N. The variant antigen-binding domain may further comprise mutation T28R in the VH domain or, alternatively, mutation G31K in the VH domain.
The variant antigen-binding domain may comprise T28K, Y32K and A100N mutations.
The variant antigen-binding domain may further comprise at least one mutation at a position selected from the group consisting of V2, Y27, G31, R98, Y102, N103, and A107 in the VH domain, N35 in the VL domain, and R55 in the VL domain. The at least one further mutation may be selected from:
a) in the VH domain:
The variant antigen-binding domain may be selected from a variant antigen-binding domain comprising the following mutation combinations:
The variant antigen-binding domain may comprise T28K, Y32F, A100N mutations in the VH domain and N35K mutation in the VL domain,
The variant antigen-binding domain may comprise T28K, Y32F, and A100N mutations in the VH domain.
The major histocompatibility complex (MHC) is a large locus on vertebrate's DNA containing a set of closely linked polymorphic genes that code for cell surface proteins essential for the acquired immune system. MHC is the tissue-antigen that allows the immune system (more specifically T cells) to bind to, recognize, and tolerate itself (autorecognition). MHC is also the chaperone for intracellular peptides that are complexed with MHCs and presented to T cell receptors (TCRs) as potential foreign antigens. MHC interacts with TCR and its co-receptors to optimize binding conditions for the TCR-antigen interaction, in terms of antigen binding affinity and specificity, and signal transduction effectiveness.
Essentially, the MHC-peptide complex is a complex of auto-antigen/allo-antigen. Upon binding, T cells should in principle tolerate the auto-antigen, but activate when exposed to the allo-antigen.
MHC molecules bind to both T cell receptor and CD4/CD8 co-receptors on T lymphocytes, and the antigen epitope held in the peptide-binding groove of the MHC molecule interacts with the variable Ig-Like domain of the TCR to trigger T-cell activation.
MHC class I molecules are expressed in all nucleated cells and also in platelets—in essence all cells but red blood cells. MHC class I presents peptide epitopes to cytotoxic T lymphocytes (CTLs). A CTL expresses CD8 receptors, in addition to TCRs. When a CTL's CD8 receptor docks to a MHC class I molecule, if the CTL's TCR fits the epitope within the MHC class I molecule, the CTL triggers the cell to undergo programmed cell death by apoptosis. Thus, MHC class I helps mediate cellular immunity, a primary means to address intracellular pathogens, such as viruses and some bacteria. In humans, MHC class I comprises HLA-A, HLA-B, and HLA-C molecules.
MHC-I molecules are heterodimers, they have a polymorphic heavy α-subunit whose gene occurs inside the MHC locus and small invariant β2 microglobulin subunit whose gene is located usually outside of it. The polymorphic heavy chain of MHC-I molecule contains N-terminal extra-cellular region composed by three domains, α1, α2, and α3, a transmembrane helix to hold MHC-I molecule on the cell surface and a short cytoplasmic tail. Two domains, α1 and α2 form a deep peptide-binding groove between two long α-helices and the floor of the groove is formed by eight p-strands. Immunoglobulin-like domain α3 is involved in the interaction with CD8 co-receptor. β2 microglobulin provides stability of the complex and participates in the recognition of peptide-MHC class I complex by the CD8 co-receptor. The peptide is non-covalently bound to MHC-1, it is held by the several pockets on the floor of the peptide-binding groove. Amino acid side-chains that are most polymorphic in human alleles fill up the central and widest portion of the binding groove, while conserved side-chains are clustered at the narrower ends of the groove.
MHC class II can be conditionally expressed by all cell types, but normally occurs only on “professional” antigen-presenting cells (APCs): macrophages, B cells, and especially dendritic cells (DCs). An APC takes up an antigenic protein, performs antigen processing, and returns a molecular fraction of the protein—an antigenic epitope—and displays it on the APC's surface coupled within an MHC class II molecule (antigen presentation). On the cell's surface, the epitope can be recognized by immunologic structures like T cell receptors (TCRs).
On surface of helper T cells are CD4 receptors, as well as TCRs. When a naive helper T cell's CD4 molecule docks to an APC's MHC class II molecule, its TCR can meet and bind the epitope coupled within the MHC class II. This event primes the naive T cell.
Class II MHC molecules are also heterodimers, genes for both α and β subunits are polymorphic and located within MHC class II subregion. The peptide-binding groove of MHC-II molecules is forms by N-terminal domains of both subunits of the heterodimer, α1 and β1; unlike MHC-1 molecules, where two domains of the same chain are involved. In addition, both subunits of MHC-II contain transmembrane helix and immunoglobulin domains α2 or β2 that can be recognized by CD4 co-receptors. In this way MHC molecules chaperone which type of lymphocytes may bind to the given antigen with high affinity, since different lymphocytes express different T-Cell Receptor (TCR) co-receptors.
The effector immune cell of the present invention may comprise an MHC class I polypeptide; an MHC class II polypeptide; or β-2 microglobulin, linked to an intracellular signalling domain.
CD8+ T cells are key mediators of transplant rejection and graft-versus host disease and contribute to the pathogenesis of autoimmune diseases. As explained above, it is to convert TCR ligands into T-cell activation receptors by expressing a β2 microglobulin polypeptide which comprises an intracellular signalling domain attached to one end and an antigenic peptide attached to the other end via a linker. Cells engineered to express such a molecule were found to express a high level of surface peptide-class I complexes, presenting the antigenic peptide and to respond to antibodies and target T-cells in a peptide specific manner. By expressing such a peptide-linker-signalling domain polypeptide in effector immune cells such as T-cells, it is possible to specifically target pathogenic CD8-T cells recognising a particular antigenic peptide.
Thus, the effector immune cells of the present invention may comprise an engineered MHC class I complex which comprises a molecule having the following structure:
peptide-L-B2M-endo
in which:
“peptide” is a peptide which binds the peptide binding groove of the MHC class I α-chain;
“L” is a linker
“B2M” is β-2 microglobulin; and
“endo” is an intracellular signalling domain.
The peptide may be an alloantigen or an autoantigen.
Autoimmune disorders are characterized by reactivity of the immune system to an endogenous antigen, with consequent injury to tissues. More than 80 chronic autoimmune diseases have been characterized that affect virtually almost every organ system in the body. The most common autoimmune diseases are insulin dependent diabetes mellitus (IDDM), multiple sclerosis (MS), systemic lupus erythematosus (SLE), rheumatoid arthritis, several forms of anemia (pernicious, plastic, hemolytic), thyroiditis, and uveitis.
Allograft rejection typically results from an overwhelming adaptive immune response against foreign organ or tissue. It is the major risk factor in organ transplantation and is the cause of post-transplantation complications. A major complication associated with bone marrow (BM) transplantation, known as graft versus-host (GVH) reaction or graft-versus-host disease (GVHD), occurs in at least half of patients when grafted donor lymphocytes, injected into an allogeneic recipient whose immune system is compromised, begin to attack the host tissue, and the host's compromised state prevents an immune response against the graft.
The linker connects the peptide to β-2 microglobulin and provides flexibility such that the peptide can bind the peptide-binding groove of an associated MHC molecule. It may, for example, comprise between 5-20 amino acids, or 10-15 amino acids.
The molecule may also comprise a peptide bridge to bridge β-2 microglobulin to the cell membrane. The peptide bridge may comprise the 13 membrane proximal amino acids of the extracellular portion of HLA-A2 which has the sequence
The molecule may comprise a membrane-targeting domain, such as a transmembrane domain. By way of example, the transmembrane domains of CD8alpha and CD28 are shown as SEQ ID NO: 12 and SEQ ID NO: 13, respectively.
The amino acid sequence of human β-2 microglobulin is available from Uniprot Accession No. P61769 and is shown below as SEQ ID No. 14.
The engineered MHC class I complex may comprise a variant of the β-2 microglobulin sequence shown as SEQ ID No. 14, for example a variant having at least 80%, 90%, 95% or 99% amino acid identity to the sequence shown as SEQ ID 14, provided that the resultant peptide-L-B2M-endo molecule retains the capacity to associate with MHC class I α chain.
The endodomain from human CD3zeta has the sequence shown as SEQ ID No. 15.
The engineered MHC class I complex may comprise an intracellular signalling domain having the sequence shown as SEQ ID No. 15 or a variant having at least 80%, 90%, 95% or 99% amino acid identity to the sequence shown as SEQ ID 15, provided that the resultant peptide-L-B2M-endo molecule retains the capacity to trigger activation of the effector immune cell upon TCR recognition
Further intracellular signalling domains and co-stimulatory domains are described below.
It is possible to couple the binding of a MHC class I or II on an effector immune cell to a TCR on a target immune cell to induce—directly or indirectly—signalling in the effector cell. In these approached the MHC signalling systems are capable of presenting the same range of peptides as a corresponding endogenous MHC class I and II molecules. As such, any peptide which is naturally presented by MHC class I or II molecule is presented by the engineered MHC complex. This includes peptides derived from any xenogeneic or junctional sequences, for example derivable from a chimeric antigen receptor expressed by the cell, that may be immunogenic. In an allogeneic setting, this may also include minor histocompatibility antigens. Thus such an engineered MHC class complex will interact with any endogenous, reactive T-cells present in the recipient of the engineered cell through recognition of peptide/MHC complexes. The reactive T-cell can thus be depleted by activation of cytotoxic-mediated cell killing by the cell of the present invention. Hence, a cellular immune response against the cell of the present invention can be reduced.
In this respect, the effector immune cell may comprise a polypeptide capable of co-localizing: an MHC class I polypeptide; an MHC class II polypeptide; or β-2 microglobulin with an intracellular signalling domain.
The effector immune cell may comprise:
Alternatively the effector immune cell may engineered to express a bispecific polypeptide which comprises: (i) a first binding domain which binds to MHC class I polypeptide; an MHC class II polypeptide; β-2 microglobulin; and (ii) a second binding domain which binds to a component of the TCR/CD3 complex (see
MHC class I molecules are heterodimers that consist of two polypeptide chains, an α polypeptide and β2-microglobulin (b2m). The two chains are linked non-covalently via interaction of b2m and the α3 domain. The α chain is polymorphic and, in humans, encoded by a human leukocyte antigen gene complex (HLA). The b2m subunit is not polymorphic and encoded by the Beta-e macroglobulin gene. HLA gene. HLAs corresponding to MHC class I are HLA-A, HLA-B, HLA-C, HLA-E, HLA-F, HLA-G.
HLA-A, HLA-B and HLA-C are typically very polymorphic whilst HLA-E, HLA-F, HLA-G are less polymorphic.
The engineered polypeptide of the effector cell of the invention may comprise the extracellular domain of HLA-A, HLA-B, HLA-C, HLA-E, HLA-F or HLA-G.
The engineered polypeptide or bispecific polypeptide expressed by the effector cell of the invention may bind HLA-A, HLA-B, HLA-C, HLA-E, HLA-F or HLA-G
The most common haplotypes vary between populations. Accordingly, an effector immune cell according to the present invention may be designed for a certain population with specific common haplotypes. Exemplary class I haplotypes are summarised in the table below:
An amino acid sequence of HLA class I—HLA-A is HLA-A01 as shown as SEQ ID NO: 16:
YTQAASSDSAQGSDVSLTACKV
In the sequence shown as SEQ ID No. 16 to 22:
Ectodomain=unformatted text
Bold/underline=transmembrane
Italics=endodomain
An amino acid sequence of HLA class I—HLA-A is HLA-A02 as shown as SEQ ID NO: 17:
SQAASSDSAQGSDVSLTACKV
An amino acid sequence of HLA class I—HLA-A is HLA-A-A03 as shown as SEQ ID NO: 18:
TQAASSDSAQGSDVSLTACKV
An amino acid sequence of HLA class I—HLA-B is HLA-B07 as shown as SEQ ID NO: 19:
YSQAACSDSAQGSDVSLTA
An amino acid sequence of HLA class I—HLA-B is HLA-B08 as shown as SEQ ID NO: 20:
VLAVVVIGAVVAAV
MCRRKSSGGKGGSYSQAACSD
SAQGSDVSLTA
An illustrative amino acid sequence of HLA class I—HLA-B is HLA-B44 as shown as SEQ ID NO: 21:
AVLAVVVIGAVVAAV
MCRRKSSGGKGGSYSQAACS
DSAQGSDVSLTA
An amino acid sequence of HLA class I—HLA-C is HLA-C01 as shown as SEQ ID NO: 22:
AVLAVLAVLGAVVAVV
MCRRKSSGGKGGSCSQAAS
SNSAQGSDESLIACKA
The engineered polypeptide of the effector cell of the invention may comprise the extracellular domain of any of SEQ ID Nos 16 to 22, or a variant thereof having at least 80, 85, 90, 95, 98 or 99% identity, provided that the variant maintains ability to assemble with a β2-microglobulin chain and facilitate productive peptide presentation by the MHC class I complex.
The engineered polypeptide may also comprise a transmembrane domain.
The transmembrane domain may be any peptide domain that is capable of inserting into and spanning the cell membrane. A transmembrane domain may be any protein structure which is thermodynamically stable in a membrane. This is typically an alpha helix comprising of several hydrophobic residues. The transmembrane domain of any transmembrane protein can be used to supply the transmembrane portion of the invention. The presence and span of a transmembrane domain of a protein can be determined by those skilled in the art using the TMHMM algorithm (http://www.cbs.dtu.dk/services/TMHMM-2.0/). Further, given that the transmembrane domain of a protein is a relatively simple structure, i.e. a polypeptide sequence predicted to form a hydrophobic alpha helix of sufficient length to span the membrane, an artificially designed TM domain may also be used (U.S. Pat. No. 7,052,906 B1 describes synthetic transmembrane components). For example, the transmembrane domain may comprise a hydrophobic alpha helix. The transmembrane domain may, for example, be derived from CD8alpha or CD28.
In humans the MHC class II protein complex is encoded by the human leukocyte antigen gene complex (HLA). HLAs corresponding to MHC class II are HLA-DP, HLA-DM, HLA-DOA, HLA-DOB, HLA-DQ and HLA-DR.
Activated human T cells express MHC class II molecules of all isotypes (HLA-DR, HLA-DQ, and HLA-DP) on their surface. Expression of MHC class II molecules is found approximately 3 to 5 days after T-cell activation, which is a relative late event compared with the induction of a variety of other effector molecules after T-cell receptor (TCR)-triggering and co-stimulation. Since adoptively transferred immune effectors are expected to be activated at some point after infusion, expression of HLA class II can lead to allo-rejection.
HLA class II molecules are formed as two polypeptide chains: alpha and beta. These are typically highly polymorphic from one individual to another, although some haplotypes are much more common in certain populations than others.
Polypeptides for any haplotype or any combination of haplotypes may be used in the present invention including any of those recited in the table below:
HLA-DR has very little polymorphism, making it particularly suitable for use in the present invention. In one embodiment, the engineered polypeptide comprises an ectodomain from HLA-DR and an intracellular signalling domain. The ectodomain may be from HLA-DRα or HLA-DRβ.
An amino acid sequence of HLA class II histocompatibility antigen, DR α chain (which has UniProtKB accession number P01903) is shown as SEQ ID NO: 23:
EFYLNPDQSGEFMFDFDGDEIFHVDMAKKETVWRL
EEFGRFASFEAQGALANIAVDKANLEIMTKRSNYT
PITNVPPEVTVLTNSPVELREPNVLICFIDKFTPP
VVNVTWLRNGKPVTTGVSETVFLPREDHLFRKFHY
LPFLPSTEDVYDCRVEHWGLDEPLLKHWEFDAPSP
LPETTE
NVVCALGLTVGLVGIIIGTIFIIKGVRKS
Bold underlined=ecotodomain of this HLADRα sequence corresponds to amino acid positions 26-216 of the sequence.
The engineered polypeptide may comprise an ectodomain from HLA-DRα as set forth SEQ ID NO: 23 (such as from about amino acid 26 to about amino acid 216 of SEQ ID NO: 23) or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant maintains ability to assemble with a β chain and facilitate productive peptide presentation by the MHC class II complex.
An amino acid sequence of HLA class II histocompatibility antigen, DR β chain (which has UniProtKB accession number Q04826) is shown as SEQ ID NO: 24:
VSRPGRGEPRFITVGYVDDTLFVRFDSDATSPRKE
PRAPWIEQEGPEYWDRETQISKTNTQTYRESLRNL
RGYYNQSEAGSHTLQSMYGCDVGPDGRLLRGHNQY
AYDGKDYIALNEDLRSWTAADTAAQITQRKWEAAR
VAEQLRAYLEGECVEWLRRYLENGKETLQRADPPK
THVTHHPISDHEATLRCWALGFYPAEITLTWQRDG
EDQTQDTELVETRPAGDRTFQKWAAVVVPSGEEQR
YTCHVQHEGLPKPLTLRWEPSSQSTVPI
VGIVAGL
Bold underlined=the ecotodomain of this HLA-DRβ sequence and corresponds to amino acid positions 25-308 of the sequence.
The engineered polypeptide may comprise an ectodomain from HLA-DRβ as set forth SEQ ID NO: 24 (such as from about amino acid 25 to about amino acid 308 of SEQ ID NO: 24) or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant maintains ability to assemble with an α chain and facilitate productive peptide presentation by the MHC class II complex.
HLA-DP and HLA-DQ have polymorphic α and β chains. Therefore, one can select common HLA-DP or HLA-DQ α or β chain and restrict allogeneic production only from recipients with that haplotype. Suitably, the recipient may be homozygous for that haplotype. Wherein the recipient is not homozygous for the haplotype, two HLA-DP and two HLA-DQ (optionally in combination with HLA-DR e.g. HLA-DRα) may be used.
An amino acid sequence of HLA class II histocompatibility antigen, DP (which has UniProtKB accession number Q30058) is shown as SEQ ID NO: 25:
VHQLRQECYGFNGTQRFLESYIYNREEFVRFDSDV
GEFRAVTELGRPDEDYWNSQKDILEEERAVPDRVC
RRNYELDEAVTLQRRVQPKVNVSPSKKGPLQHHNL
LVCHVTDFYPSSIQVRWFLNGQEETAGWSTNLIRN
GDWTFQILVMLEMTPQQGDVYICQVEHTSLDSPVT
VEWKAQSDSAQSK
TLTGAGGFVLGLIICGVGIFMH
Italics=the transmembrane region and corresponds to amino acid positions 225 to 244
Bold underlined=the ecotodomain of this HLA-DP sequence and corresponds to amino acid positions 29-224 of the sequence
The engineered polypeptide may comprise an ectodomain from HLA-DP as set forth SEQ ID NO: 25 (such as from about amino acid 29 to about amino acid 224 of SEQ ID NO: 25) or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant maintains ability to assemble and facilitate productive peptide presentation by the MHC class II complex.
An amino acid sequence of HLA class II histocompatibility antigen, DQ (which has UniProtKB accession number 019764) is shown as SEQ ID NO: 26:
EDFVYQFKGLCYFTNGTERVRLVTRYIYNREEYAR
FDSDVGVYRAVTPQGRPVAEYWNSQKEVLERTRAE
LDTVCRHNYEVGYRGILQRRVEPTVTISPSRTEAL
NHHNLLVCSVTDFYPGQIKVQWFRNDQEETAGVVS
TPLIRNGDWTFQILMLEMTPQRGDVYTCHVEHPSL
QSPITVEWRAQSESAQSK
MLSGVGGFVLGLIFLGL
GLII
Italics=the transmembrane region and corresponds to amino acid positions 229-249
Bold underlined=the ecotodomain of this HLA-DQ sequence and corresponds to amino acid positions 32-228 of the sequence.
The engineered polypeptide may comprise an ectodomain from HLA-DQ as set forth SEQ ID NO: 26 (such as from about amino acid 32 to about amino acid 228 of SEQ ID NO: 26) or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant maintains ability to assemble and facilitate productive peptide presentation by the MHC class II complex.
The engineered polypeptide may comprise the extracellular domain from any of SEQ ID No. 23 to 26. The engineered polypeptide may also comprise a transmembrane domain, as explained above.
The sequences of MHC polypeptides are provided in the ImMunoGeneTics (IMGT) database (Lefranc, M.-P. et al., Nucleic Acids Res., 27:209-212 (1999); doi: 10.1093/nar/27.1.209).
The percentage identity between two polypeptide sequences may be readily determined by programs such as BLAST, which is freely available at http://blast.ncbi.nlm.nih.gov. Suitably, the percentage identity is determined across the entirety of the reference and/or the query sequence.
As used herein, “capable of co-localizing an MHC class I polypeptide or MHC class II polypeptide with an intracellular signalling domain within the cell” means that, when a target T-cell binds to a peptide/MHC complex on an effector immune cell of the present invention, the polypeptide co-localizes the MHC class I polypeptide or MHC class II polypeptide with the intracellular signalling domain such that the intracellular signalling domain transmits an activating signal in the effector immune cell of the present invention.
CD79 is comprised of two chains, CD79α and CD79β which form a heterodimer on the surface of B cells. CD79α a/β assemble with membrane-bound immunoglobulin forming a complex with the B-cell receptor (BCR). CD79α and CD79β are members of the immunoglobulin superfamily and contain ITAM signalling motifs which enable B-cell signalling in response to cognate antigen recognition by the BCR.
CD79α and CD79β also associate with HLA class II, which allows HLA class II to signal through CD79 in an analogous way to membrane-bound immunoglobulin (Lang, P. et al. Science 291, 1537-1540 (2001) and Jin, L. et al. Immunol. Lett. 116, 184-194 (2008).
In one aspect, the present invention provides a cell which comprises; (i) a chimeric antigen receptor (CAR) or a transgenic T-cell receptor (TCR); and (ii) at least one polypeptide capable of co-localizing an MHC class I polypeptide or an MHC class II polypeptide with an intracellular signalling domain within the cell; wherein the at least one polypeptide capable of co-localizing the MHC class I polypeptide or MHC class II polypeptide with the intracellular signalling domain is CD79 or a variant thereof.
The cell may comprise an engineered polypeptide which comprises CD79α or CD79β linked to an intracellular signalling domain. The cell may comprise two engineered polypeptides: one which comprises CD79α linked to an intracellular signalling domain; and one which comprises CD79β linked to an intracellular signalling domain.
The amino acid sequence of human CD79 α (which has UniProtKB accession number P11912) is shown as SEQ ID NO: 27:
HKVPASLMVSLGEDAHFQCPHNSSNNANVTWWRVL
HGNYTWPPEFLGPGEDPNGTLIIQNVNKSHGGIYV
CRVQEGNESYQQSCGTYLRVRQPPPRPFLDMGEGT
KNRIITAEGIILLFCAVVPGTLLLFRKRWQNEKLG
LDAGDEYEDENLYEGLNLDDCSMYEDISRGLQGTY
QDVGSLNIGDVQLEKP
Underlined=signal peptide (amino acids 1-32)
Bold=extracellular (amino acids 33-143)
No formatting=transmembrane domain (amino acids 144-165)
Italics=cytoplasmic domain (amino acids 166-226)
A CD79 α sequence for use in the present invention may comprise the sequence shown as SEQ ID NO: 27 or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant maintains ability to assemble with HLA class I and/or HLA class II and facilitate signalling.
The engineered polypeptide may comprise an ectodomain of CD79α, a transmembrane domain and an intracellular signalling domain. The engineered polypeptide may comprise an ectodomain of CD79α which corresponds to about amino acid 33 to about amino acid 143 of SEQ ID NO. 27.
The engineered polypeptide may comprise a transmembrane domain of CD79α which corresponds to about amino acid 144 to about amino acid 165 of SEQ ID NO. 27.
The engineered polypeptide may comprise an intracellular signalling domain of CD79α which corresponds to about amino acid 166 to about amino acid 226 of SEQ ID NO. 27.
The amino acid sequence of human CD79 β (which has UniProtKB accession number P40259) is shown as SEQ ID NO: 28:
RNPKGSACSRIWQSPRFIARKRGFTVKMHCYMNSA
SGNVSWLWKQEMDENPQQLKLEKGRMEESQNESLA
TLTIQGIRFEDNGIYFCQQKCNNTSEVYQGCGTEL
RVMGFSTLAQLKQRNTLKDGIIMIQTLLIILFIIV
VTLRTGEVKWSVGEHPGQE
Underlined=signal peptide (amino acids 1-28)
Bold=extracellular (amino acids 29-159)
No formatting=transmembrane domain (amino acids 160-180)
Italics=cytoplasmic (amino acids 181-229)
A CD79 β sequence for use in the present invention may comprise the sequence shown as SEQ ID NO: 8 or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant maintains ability to assemble with HLA class I and/or HLA class II and facilitate signalling.
The engineered polypeptide may comprise an ectodomain of CD79β, a transmembrane domain and an intracellular signalling domain. The engineered polypeptide may comprise an ectodomain of CD79β which corresponds to about amino acid 29 to about amino acid 159 of SEQ ID NO. 28.
The engineered polypeptide may comprise a transmembrane domain of CD79 β which corresponds to about amino acid 160 to about amino acid 180 of SEQ ID NO. 28.
The engineered polypeptide may comprise an intracellular signalling domain of CD79 β which corresponds to about amino acid 181 to about amino acid 229 of SEQ ID NO. 28.
The effector immune cell may express two engineered polypeptides: one comprising the extracellular domain of CD79α and one comprising the extracellular domain of CD79β.
The effector immune cell may comprise:
(i) a chimeric antigen receptor (CAR) or a transgenic T-cell receptor (TCR); and
(ii) an engineered polypeptide which comprises an MHC class I polypeptide or MHC class II polypeptide linked to linked to a component of the CD3/TCR complex.
CD3 is a T-cell co-receptor that is involved in the activation of both cytotoxic T-cells and T-helper cells. It is formed of a protein complex composed of four distinct chains. As used herein, the term “CD3 complex” also includes the CD3 ζ-chain. In mammals, the complex contains a CD3γ chain, a CD3δ chain, and two CD3ε chains. These chains associate with the TCR to generate a TCR complex which is capable of producing an activation signal in T lymphocytes.
The CD3ζ, CD3γ, CD3δ, and CD3ε chains are highly related cell-surface proteins of the immunoglobulin superfamily containing a single extracellular immunoglobulin domain. The transmembrane region of the CD3 chains contain a number of aspartate residues are negatively charged, a characteristic that allows these chains to associate with the positively charged TCR chains. The intracellular tails of the CD3 molecules contain a single conserved motif known as an immunoreceptor tyrosine-based activation motif (ITAM), which is involved in TCR signalling.
The polypeptide linked to a component of the TCR complex is capable of assembling and facilitating productive peptide presentation by the MHC class I or MHC class II complex at the cell surface. In addition, the TCR/CD3 component is able to assemble with the TCR/CD3 complex. Hence, binding of a TCR to the peptide/MHC complex comprising the polypeptide linked to a component of the TCR complex will trigger signalling through the CD3/TCR complex.
The polypeptide may be linked to the TCR or a component of the CD3 complex. The polypeptide may be linked to an engineered TCR polypeptide which lacks a variable domain.
The engineered polypeptide may be linked to a component of the CD3 complex, for example selected from CD3-zeta, CD3-epsilon, CD3-gamma and CD3-delta.
Examples of human CD3ζ, CD3γ, CD3δ and CD3ε amino acid sequences are shown as SEQ ID NO: 29-32, respectively.
DGILFIYGVILTALFLRVKFSRSADAPAYQQGQNQ
The MHC class I/MHC class II or B2M polypeptide may be linked to the CD3 component by any suitable means. For example, the polypeptide may be fused to the component of the CD3 complex by a linker peptide.
Suitable linker peptides are known in the art. For example, a range of suitable linker peptides are described by Chen et al. (Adv Drug Deliv Rev. 2013 Oct. 15; 65(10): 1357-1369—see Table 3 in particular).
A suitable linker is an (SGGGG)n (SEQ ID NO: 33), which comprises one or more copies of SEQ ID NO: 33. For example, a suitable linker peptide is shown as SEQ ID NO: 34.
The polypeptide may be linked to the ectodomain of the component of the CD3 complex. It may be linked to the N-terminus of the component of the CD3 complex.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 35.
This polypeptide sequence comprises an ectodomain from HLA-DRα, a transmembrane domain an intracellular CD3-ζ endodomain.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 36.
This polypeptide sequence comprises an ectodomain from HLA-DRα, a transmembrane domain, a 41BB endodomain and an intracellular CD3-ζ endodomain.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 37.
This polypeptide sequence comprises an ectodomain from HLA-DRα, a transmembrane domain, a CD28 endodomain and an intracellular CD3-ζ endodomain.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 38.
This polypeptide sequence comprises an ectodomain from CD79α, a 41BB domain and an endodomain from CD79.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 39.
This polypeptide sequence comprises an ectodomain from CD79β, a CD28 domain and an endodomain from CD79.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 40.
This polypeptide sequence comprises an ectodomain from CD79α, a CD28 domain and an endodomain from CD79.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 41.
This polypeptide sequence comprises an ectodomain from CD79β, a 41BB domain and an endodomain from CD79.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 42.
This polypeptide sequence comprises an ectodomain from CD79α, a 41BB domain and a CD3-zeta domain.
An illustrative polypeptide for use in the present invention is shown as SEQ ID NO: 43.
This polypeptide sequence comprises an ectodomain from CD79β, a 41BB domain and a CD3-zeta domain.
A polypeptide sequence for use in the present invention may comprise the sequence shown as SEQ ID NO: 35-43 or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant maintains ability to assemble and facilitate productive peptide presentation by the MHC class II complex at the surface of the cell and transmit an activating signal following binding of a TCR to the peptide/MHC complex comprising the polypeptide.
The present invention involves providing at least one polypeptide capable of co-localizing an MHC class I polypeptide or MHC class II polypeptide with an intracellular signalling domain within the cell.
The engineered polypeptide of the invention may comprise an intracellular signalling domain
An intracellular signalling domain as used herein refers to a signal-transmission portion of an endodomain.
The intracellular signalling domain may be or comprise a T cell signalling domain.
The intracellular signalling domain may comprise one or more immunoreceptor tyrosine-based activation motifs (ITAMs). An ITAM is a conserved sequence of four amino acids that is repeated twice in the cytoplasmic tails of certain cell surface proteins of the immune system. The motif contains a tyrosine separated from a leucine or isoleucine by any two other amino acids, giving the signature YxxL/I. Two of these signatures are typically separated by between 6 and 8 amino acids in the tail of the molecule (YxxL/Ix(6-8)YxxL/I).
ITAMs are important for signal transduction in immune cells. Hence, they are found in the tails of important cell signalling molecules such as the CD3 and ζ-chains of the T cell receptor complex, the CD79 alpha and beta chains of the B cell receptor complex, and certain Fc receptors. The tyrosine residues within these motifs become phosphorylated following interaction of the receptor molecules with their ligands and form docking sites for other proteins involved in the signalling pathways of the cell.
Preferably, the intracellular signalling domain component comprises, consists essentially of, or consists of the CD3-ζ endodomain, which contains three ITAMs. Classically, the CD3-ζ endodomain transmits an activation signal to the T cell after antigen is bound. However, in the context of the present invention, the CD3-ζ endodomain transmits an activation signal to the effector cell after its MHC complex interacts with a TCR on a neighbouring T cell.
The intracellular signalling domain may comprise additional co-stimulatory signalling. For example, 4-1BB (also known as CD137) can be used with CD3-ζ, or CD28 and OX40 can be used with CD3-ζ to transmit a proliferative/survival signal.
Accordingly, intracellular signalling domain may comprise the CD3-ζ endodomain alone, the CD3-ζ endodomain in combination with one or more co-stimulatory domains selected from 4-1BB, CD28 or OX40 endodomain, and/or a combination of some or all of 4-1BB, CD28 or OX40.
The endodomain may comprise one or more of the following: an ICOS endodomain, a CD2 endodomain, a CD27 endodomain, or a CD40 endodomain.
The endodomain may comprise the sequence shown as SEQ ID NO: 44-47 or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant sequence retains the capacity to transmit an activating signal to the cell.
The engineered polypeptide of the present invention may comprise a binding domain which binds to an MHC class I polypeptide; an MHC class II polypeptide or β2 microglobulin, linked to an intracellular signalling domain.
The binding domain may be or comprise and antibody or antibody-like molecule.
The term “antibody”, as used herein, refers to a polypeptide having an antigen binding site which comprises at least one complementarity determining region or CDR. The antibody may comprise 3 CDRs and have an antigen binding site which is equivalent to that of a single domain antibody (dAb), heavy chain antibody (VHH) or a nanobody. The antibody may comprise 6 CDRs and have an antigen binding site which is equivalent to that of a classical antibody molecule. The remainder of the polypeptide may be any sequence which provides a suitable scaffold for the antigen binding site and displays it in an appropriate manner for it to bind the antigen.
A full-length antibody or immunoglobulin typically consists of four polypeptides: two identical copies of a heavy (H) chain polypeptide and two identical copies of a light (L) chain polypeptide. Each of the heavy chains contains one N terminal variable (VH) region and three C-terminal constant (CH1, CH2 and CH3) regions, and each light chain contains one N-terminal variable (VL) region and one C-terminal constant (CL) region. The variable regions of each pair of light and heavy chains form the antigen binding site of an antibody. They are characterised by the same general structure constituted by relatively preserved regions called frameworks (FR) joined by three hyper-variable regions called complementarity determining regions (CDR). The term “complementarity determining region” or “CDR”, as used herein, refers to the region within an antibody that complements an antigen's shape. Thus, CDRs determine the protein's affinity and specificity for specific antigens. The CDRs of the two chains of each pair are aligned by the framework regions, acquiring the function of binding a specific epitope. Consequently, in the case of VH and VL domains both the heavy chain and the light chain are characterised by three CDRs, respectively CDRH1, CDRH2, CDRH3 and CDRL1, CDRL2, CDRL3.
The engineered polypeptide of the present invention may comprise a full-length antibody or an antigen-binding fragment thereof.
A full length antibody may, for example be an IgG, an IgM, an IgA, an IgD or an IgE.
An “antibody fragment” refers to one or more fragments or portions of an antibody that retain the ability to specifically bind to an antigen. The antibody fragment may comprise, for example, one or more CDRs, the variable region (or portions thereof), the constant region (or portions thereof), or combinations thereof. Examples of antibody fragments include, but are not limited to, a Fab fragment, a F(ab′)2 fragment, an Fv fragment, a single chain Fv (scFv), a domain antibody (dAb or VH), a single domain antibody (sdAb), a VHH, a nanobody, a diabody, a triabody, a trimerbody, and a monobody.
The engineered polypeptide of the invention may comprise an antigen-binding domain which is based on a non-immunoglobulin scaffold. These antibody-binding domains are also called antibody mimetics. Non-limiting examples of non-immunoglobulin antigen-binding domains include an affibody, a fibronectin artificial antibody scaffold, an anticalin, an affilin, a DARPin, a VNAR, an Body, an affimer, a fynomeran, abdurin/nanoantibody, a centyrin, an alphabody, a nanofitin, and a D domain.
Several antibodies have been described which specifically bind MHC class I or MHC class II.
For example, WO05/023299, which is incorporated by reference, describes antibodies which bind MHC class II antigens, in particular antibodies against the HLA-DR alpha chain. Table 1 of that document contains the sequence characteristics of clones MS-GPC-1 (scFv-17), MS-GPC-6 (scFv-8A), MS-GPC-8 (scFv-B8) and MS-GPC-10 (scFv-E6) and
The engineered polypeptide may comprise an MHC class II binding domain comprising one of these pairs of VH and VL sequences. In particular, engineered polypeptide may comprise an MHC class II binding domain based on the binder MS-GPC-8.
Andris et al (1995 Mol Immunol 32:14-15) describe six antibodies specific for human HLA class I and class II antigens including an antibody against HLA-DQ beta chain having the antibody clone name anti-HLAII/DQB1-MP1.
Watkins et al (2000 Tissue Antigens 55: 219-28) describe the isolation and characterisation of human monoclonal HLA-A2 antibodies. The antibody clones include: anti-HLA-A2/A28-3PF12, anti-HLA-A2/A28-3PC4 and anti-HLA-A2/A28-3PB2.
The engineered polypeptide of the present invention may comprise an MHC class I or MHC class II binding domain derived from any of these antibodies.
The engineered polypeptide may comprise a short flexible linker to introduce a chain-break. A chain break separate two distinct domains but allows orientation in different angles. Such sequences include the sequence SDP, and the sequence SGGGSDP (SEQ ID NO: 48).
The linker may comprise a serine-glycine linker, such as SGGGGS (SEQ ID NO: 49).
The engineered polypeptide may comprise a transmembrane domain, as defined above. The engineered polypeptide may, for example, comprise the transmembrane domains of CD8-alpha or CD28.
The engineered polypeptide comprises an intracellular signalling domain, as defined above. The engineered polypeptide may, for example, comprise the CD3ζ endodomain.
The engineered polypeptide may have the general structure:
MHC class I or II binding domain-transmembrane domain-intracellular signalling domain, or
MHC class I or II binding domain-linker-transmembrane domain-intracellular signalling domain
The engineered polypeptide of the present invention may comprise the MHC class II-binding domain of CD4 linked to an intracellular signalling domain, or MHC class I-binding domain of CD8 linked to an intracellular signalling domain.
CD4 and CD8 are co-receptors of the T cell receptor (TCR) and assists T cells in communicating with antigen-presenting cells.
CD4 (cluster of differentiation 4) is a glycoprotein found on the surface of immune cells such as T helper cells, monocytes, macrophages, and dendritic cells. CD4 is a member of the immunoglobulin superfamily, having four immunoglobulin domains (D1 to D4) that are exposed on the extracellular surface of the cell:
The immunoglobulin variable (IgV) domain of D1 adopts an immunoglobulin-like β-sandwich fold with seven p-strands in 2 β-sheets. CD4 interacts with the β2-domain of MHC class II molecules through its D1 domain. T cells displaying CD4 molecules on their surface, therefore, are specific for antigens presented by MHC II, i.e. they are MHC class II-restricted.
The short cytoplasmic/intracellular tail (C) of CD4 contains a sequence of amino acids that allow it to recruit and interact with the tyrosine kinase Lck. When the extracellular D1 domain of CD4 binds to the β2 region of MHC class II, the resulting close proximity between the TCR complex and CD4 allows the tyrosine kinase Lck bound to the cytoplasmic tail of CD4 to phosphorylate tyrosine residues of immunoreceptor tyrosine activation motifs (ITAMs) on the cytoplasmic domains of CD3 to amplify the signal generated by the TCR. Phosphorylated ITAMs on CD3 recruit and activate SH2 domain-containing protein tyrosine kinases (PTK), such as ZAP70, to further mediate downstream signalling through tyrosine phosphorylation. These signals lead to the activation of transcription factors, including NF-κB, NFAT, AP-1, to promote T cell activation.
The amino acid sequence for human CD4 is available from UniProt, Accession No. P01730. The engineered polypeptide of the present invention may comprise the D1 domain of CD4, which has the sequence shown as SEQ ID No. 50. The positions of Gln40 and Thr45 are shown in bold and underlined.
The engineered polypeptide may comprise a variant D1 domain of CD4 comprising one or more amino acid mutations which increase the its binding affinity for the β2 region of MHC class II compared to the wild-type D1 domain.
For example, Wang et al (2011, PNAS 108:15960-15965) describe the affinity maturation of human CD4 by yeast surface display to increase the affinity of CD4 for HLA-DR1. It was found that a CD4 variant bearing the substitution mutations Gln40Tyr and Thr45Trp bound to HLA-DR1 with KD=8.8 μM compares with >400 μM for wild-type CD4.
The engineered polypeptide may comprise a variant D1 domain of CD4 comprising amino acid mutation(s) at position Gln40 and/or Thr45 with reference to the sequence shown as SEQ ID No. 50.
The engineered polypeptide may comprise a variant D1 domain of CD4 comprising amino acid substitution(s) Gln40Tyr and/or Thr45Trp with reference to the sequence shown as SEQ ID No. 50.
CD8 (cluster of differentiation 8) co-receptor is predominantly expressed on the surface of cytotoxic T cells, but can also be found on natural killer cells, cortical thymocytes, and dendritic cells. There are two isoforms CD8, alpha and beta, each encoded by a different gene.
To function, CD8 forms a dimer, consisting of a pair of CD8 chains. The most common form of CD8 is composed of a CD8-α and CD8-β chain, but homodimers of the CD8-α chain are also expressed on some cells. CD8-α and CD8-β are both members of the immunoglobulin superfamily having an immunoglobulin variable (IgV)-like extracellular domain connected to the membrane by a thin stalk, and an intracellular tail.
The extracellular IgV-like domain of CD8-α interacts with the α3 portion of the Class I MHC molecule. The main recognition site is a flexible loop at the α3 domain of an MHC molecule located between residues 223 and 229. Binding of CD8-α to MHC class I keeps the T cell receptor of the cytotoxic T cell and the target cell bound closely together during antigen-specific activation. The cytoplasmic tails of the CD8 co-receptor interact with Lck (lymphocyte-specific protein tyrosine kinase). Once the T cell receptor binds its specific antigen, Lck phosphorylates the cytoplasmic CD3 and ζ-chains of the TCR complex which initiates a cascade of phosphorylation eventually leading to activation of transcription factors like NFAT, NF-κB, and AP-1.
The engineered polypeptide of the present invention may comprise the IgV-like domain from CD8-α.
The amino acid sequence for human CD8α is available from UniProt, Accession No. P01732. The engineered polypeptide of the present invention may comprise the Ig-like V-type domain of CD8, which comprises amino acid residues 22-135 of this sequence and has the sequence shown as SEQ ID No. 51.
The engineered polypeptide may comprise a variant CD8α Ig-like V-type domain comprising one or more amino acid mutations which increase the its binding affinity for the α3 portion of a Class I MHC molecule compared to the wild-type CD8α domain.
For example, high affinity mutants of CD8α may be generated and characterised using the in vitor evolution method described by Wang et al (2011, PNAS 108:15960-15965).
The engineered polypeptide may comprise a dimeric form of CD8. Devine et al (1999, J. Immunol. 162:846-851) describe a molecule which comprises two CD8α Ig domains linked via the carboxyl terminal of one to the amino terminal of the other by means of a peptide spacer. A peptide spacer of 20 amino acids of 4 repeating units of GGGGS (SEQ ID No. 52) was used to allow the 2 IG-like domains to adopt the correct confirmation.
The engineered polypeptide may comprise a CD8αα homodimer, as described in Devine et al 1999. The CD8αα homodimer may have the sequence shown as SEQ ID No. 53.
The engineered polypeptide may comprise a CD8αβ heterodimer. For example, the engineered polypeptide may comprise an CD8α Ig-like V-type domain having the sequence shown as SEQ ID No. 51 joined to a an CD8P Ig-like V-type domain by a peptide spacer. The peptide spacer may be from 10 to 20, for example between 15 and 25 amino acids in length. The peptide spacer may be approximately 20 amino acids in length. The peptide spacer may comprise 4 repeating units of GGGGS (SEQ ID No. 52), as for the CD8αα homodimer described by Devine et al 1999.
The amino acid sequence for the CD8P Ig-like V-type domain is shown below as SEQ ID No. 54.
The engineered polypeptide may comprise a CD8αβ heterodimer in which the CD8α and CD8β domains are in either order in the construct, i.e. CD8αβ or CD8βα.
The engineered polypeptide may comprise a short flexible linker between the CD8α monomer, the CD8αα homodimer or the CD8αβ heterodimer and the stalk and/or transmembrane domain to introduce a chain-break. A chain break separate two distinct domains but allows orientation in different angles. Such sequences include the sequence SDP, and the sequence SGGGSDP (SEQ ID NO: 48).
The linker may comprise a serine-glycine linker, such as SGGGGS (SEQ ID NO: 49).
The engineered polypeptide may comprise a transmembrane domain, as defined above. For example, the engineered polypeptide may comprise the transmembrane domains of CD8-alpha or CD28.
The engineered polypeptide comprises an intracellular signalling domain, as defined above. The engineered polypeptide may, for example, comprise the CD3ζ endodomain.
The engineered polypeptide may have the general structure:
CD4 D1 domain-linker-transmembrane domain-intracellular signalling domain;
CD8α Ig-like V-type domain-linker-transmembrane domain-intracellular signalling domain;
CD8αα homodimer-linker-transmembrane domain-intracellular signalling domain; or
CD8αβ homodimer-linker-transmembrane domain-intracellular signalling domain
In a further embodiment of the present invention, the polypeptide capable of co-localizing the MHC class I polypeptide or an MHC class II polypeptide with an intracellular signalling domain may be a bispecific polypeptide which comprises:
(a) a first binding domain which is binds to an MHC class I polypeptide or an MHC class II polypeptide
(b) a second binding domain which is capable of binding to a polypeptide comprising an intracellular signalling domain or a component of the CD3 complex.
The bispecific polypeptide may be membrane-tethered.
When expressed by the cell or on the cell surface, the present bispecific molecule co-localises MHC class I or II and the TCR, and facilitates TCR signalling in a cell of the invention following binding of a TCR on a different T cell to the peptide/MHC complex bound by the bispecific molecule.
Bispecific molecules have been developed in a number of different formats. One of the most common is a fusion consisting of two single-chain variable fragments (scFvs) of different antibodies.
The first and/or second binding domains of the bispecific molecule may be antibody or immunoglobulin based binding domains.
As used herein, “antibody” means a polypeptide having an antigen binding site which comprises at least one complementarity determining region CDR. The antibody may comprise 3 CDRs and have an antigen binding site which is equivalent to that of a domain antibody (dAb). The antibody may comprise 6 CDRs and have an antigen binding site which is equivalent to that of a classical antibody molecule. The remainder of the polypeptide may be any sequence which provides a suitable scaffold for the antigen binding site and displays it in an appropriate manner for it to bind the antigen. The antibody may be a whole immunoglobulin molecule or a part thereof such as a Fab, F(ab)′2, Fv, single chain Fv (ScFv) fragment, Nanobody or single chain variable domain (which may be a VH or VL chain, having 3 CDRs). The antibody may be a bifunctional antibody. The antibody may be non-human, chimeric, humanised or fully human.
Alternatively, the first and/or second binding domains of the present bispecific molecule may comprise domains which are not derived from or based on an immunoglobulin. A number of “antibody mimetic” designed repeat proteins (DRPs) have been developed to exploit the binding abilities of non-antibody polypeptides. Such molecules include ankyrin or leucine-rich repeat proteins e.g. DARPins (Designed Ankyrin Repeat Proteins), Anticalins, Avimers and Versabodies.
The first binding domain of the present bispecific molecule is capable of binding to a MCH class I or MHC class II polypeptide.
As mentioned above several antibodies have been described which specifically bind MHC class I or MHC class II.
For example, WO05/023299, which is incorporated by reference, describes antibodies which bind MHC class II antigens, in particular antibodies against the HLA-DR alpha chain. Table 1 of that document contains the sequence characteristics of clones MS-GPC-1 (scFv-17), MS-GPC-6 (scFv-8A), MS-GPC-8 (scFv-B8) and MS-GPC-10 (scFv-E6) and
The bispecific polypeptide may comprise an MHC class II binding domain comprising one of these pairs of VH and VL sequences. In particular, bispecific polypeptide may comprise an MHC class II binding domain based on the binder MS-GPC-8.
Andris et al (1995 Mol Immunol 32:14-15) describe six antibodies specific for human HLA class I and class II antigens including an antibody against HLA-DQ beta chain having the antibody clone name anti-HLAII/DQB1-MP1.
Watkins et al (2000 Tissue Antigens 55: 219-28) describe the isolation and characterisation of human monoclonal HLA-A2 antibodies. The antibody clones include: anti-HLA-A2/A28-3PF12, anti-HLA-A2/A28-3PC4 and anti-HLA-A2/A28-3PB2.
The bispecific polypeptide of the present invention may comprise an MHC class I or MHC class II binding domain derived from any of these antibodies.
The second domain of the present bispecific molecule is capable of binding to a polypeptide comprising an intracellular signalling domain or a component of the CD3 complex. In particular, the second domain may be capable of binding CD3 on the T-cell surface. In this respect, the second domain may comprise a CD3 or TCR-specific antibody or part thereof.
The second domain may comprise the complementarity determining regions (CDRs) from the scFv sequence shown as SEQ ID NO: 55.
The second domain may comprise a scFv sequence, such as the one shown as SEQ ID NO: 55. The second domain may comprise a variant of such a sequence which has at least 80% sequence identity and binds CD3.
The second domain may comprise an antibody or part thereof which specifically binds CD3, such as OKT3, WT32, anti-leu-4, UCHT-1, SPV-3TA, TR66, SPV-T3B or affinity tuned variants thereof.
The second domain of the bispecific molecule of the invention may comprise all or part of the monoclonal antibody OKT3, which was the first monoclonal antibody approved by the FDA. OKT3 is available from ATCC CRL 8001. The antibody sequences are published in U.S. Pat. No. 7,381,803.
The second domain may comprise one or more CDRs from OKT3. The second binding domain may comprise CDR3 from the heavy-chain of OKT3 and/or CDR3 from the light chain of OKT3. The second binding domain may comprise all 6 CDRs from OKT3, as shown below.
The second binding domain may comprise a scFv which comprises the CDR sequences from OKT3. The second binding domain may comprise the scFv sequence shown below as SEQ ID NO: 55 or 62 or a variant thereof having at least 80% sequence identity, which retains the capacity to bind CD3.
SEQ ID NO: 55 and 62 provide alternative architectures of an scFV suitable for use in the present invention. SEQ ID NO: 55 is provided as a VL-VH arrangement. SEQ ID NO: 55 is provided as a VH-VL arrangement.
A variant sequence from SEQ ID NO: 55 or 62 may have at least 80, 85, 90, 95, 98 or 99% sequence identity and have equivalent or improved CD3 binding capabilities as the sequence shown as SEQ ID NO: 55 or 62.
The bispecific molecule of the present invention may comprise a spacer sequence to connect the first domain with the second domain and spatially separate the two domains.
For example, the first and second binding domains may be connected via a short five residue peptide linker (GGGGS).
The spacer sequence may, for example, comprise an IgG1 hinge or a CD8 stalk. The linker may alternatively comprise an alternative linker sequence which has similar length and/or domain spacing properties as an IgG1 hinge or a CD8 stalk.
The spacer may be a short spacer, for example a spacer which comprises less than 100, less than 80, less than 60 or less than 45 amino acids. The spacer may be or comprise an IgG1 hinge or a CD8 stalk or a modified version thereof.
Examples of amino acid sequences for these linkers are given below:
The CD8 stalk has a sequence such that it may induce the formation of homodimers. If this is not desired, one or more cysteine residues may be substituted or removed from the CD8 stalk sequence. The bispecific molecule of the invention may include a spacer which comprises or consists of the sequence shown as SEQ ID NO: 64 or a variant thereof having at least 80, 85, 90, 95, 98 or 99% sequence identity, provided that the variant sequence is a molecule which causes approximately equivalent spacing of the first and second domains and/or that the variant sequence causes homodimerisation of the bispecific molecule.
The bispecific molecule of the invention may have the general formula:
First domain−spacer−second domain.
The spacer may also comprise one or more linker motifs to introduce a chain-break. A chain break separate two distinct domains but allows orientation in different angles. Such sequences include the sequence SDP, and the sequence SGGGSDP (SEQ ID NO: 48).
The linker may comprise a serine-glycine linker, such as SGGGGS (SEQ ID NO: 49).
The spacer may cause the bispecific molecule to form a homodimer, for example due to the presence of one or more cysteine residues in the spacer, which can for a di-sulphide bond with another molecule comprising the same spacer.
The bispecific molecule may be membrane-tethered. In other words, the bispecific molecule may comprise a transmembrane domain such that it is localised to the cell membrane following expression in the cell of the present invention.
By way of example, the transmembrane domain may a transmembrane domain as described herein. For example, the transmembrane domain may comprise a hydrophobic alpha helix. The transmembrane domain may be derived from CD8alpha or CD28.
The bispecific molecule of the invention may have the general formula:
First domain−spacer−second domain−transmembrane domain; or
Transmembrane domain−first domain−spacer−second domain.
Transgenic T-Cell Receptor The engineered immune cell of the present invention may express a transgenic T-cell receptor (TCR).
The T-cell receptor (TCR) is a molecule found on the surface of T cells which is responsible for recognizing fragments of antigen as peptides bound to major histocompatibility complex (MHC) molecules.
The TCR is a heterodimer composed of two different protein chains. In humans, in 95% of T cells the TCR consists of an alpha (α) chain and a beta (β) chain (encoded by TRA and TRB, respectively), whereas in 5% of T cells the TCR consists of gamma and delta (γ/δ) chains (encoded by TRG and TRD, respectively).
When the TCR engages with antigenic peptide and MHC (peptide/MHC), the T lymphocyte is activated through signal transduction.
In contrast to conventional antibody-directed target antigens, antigens recognized by the TCR can include the entire array of potential intracellular proteins, which are processed and delivered to the cell surface as a peptide/MHC complex.
It is possible to engineer cells to express heterologous (i.e. non-native) TCR molecules by artificially introducing the TRA and TRB genes; or TRG and TRD genes into the cell using vector. For example the genes for engineered TCRs may be reintroduced into autologous T cells and transferred back into patients for T cell adoptive therapies. Such ‘heterologous’ TCRs may also be referred to herein as ‘transgenic TCRs’.
The effector immune cell of the present invention may be a cytolytic immune cell such as a T-cell, a natural killer (NK) cell or a cytokine induced killer cell.
The T cell may be an alpha-beta T cell or a gamma-delta T cell.
The cell may be derived from a patient's own peripheral blood (1st party), or in the setting of a haematopoietic stem cell transplant from donor peripheral blood (2nd party), or peripheral blood from an unconnected donor (3rd party). T or NK cells, for example, may be activated and/or expanded prior to being transduced with nucleic acid molecule(s) encoding the polypeptides of the invention, for example by treatment with an anti-CD3 monoclonal antibody.
Alternatively, the cell may be derived from ex vivo differentiation of inducible progenitor cells or embryonic progenitor cells to T cells. Alternatively, an immortalized T-cell line which retains its lytic function may be used.
The cell may be a haematopoietic stem cell (HSC). HSCs can be obtained for transplant from the bone marrow of a suitably matched donor, by leukopheresis of peripheral blood after mobilization by administration of pharmacological doses of cytokines such as G-CSF [peripheral blood stem cells (PBSCs)], or from the umbilical cord blood (UCB) collected from the placenta after delivery. The marrow, PBSCs, or UCB may be transplanted without processing, or the HSCs may be enriched by immune selection with a monoclonal antibody to the CD34 surface antigen.
The cell surface receptor or receptor complex binds an antigen recognition receptor of a target immune cell may be an MHC class I receptor or complex; an MHC class II receptor or complex; or a TCR or TCR/CD3 complex.
The target immune cell of the present invention may be a cytolytic immune cell such as a T-cell, a natural killer (NK) cell or a cytokine induced killer cell.
The target immune cell may be present in a population of immune cells in vitro, ex vivo, or in vivo. The target immune cell may, for example, be in a patient or in a transplant, prior to administration to a patient.
The target immune cells may specifically recognise an autoantigen or an alloantigen.
The antigen recognition receptor of the target immune cell may be a T-cell receptor, such as an αβ-TCR or γδ-TCR which are described in more detail above.
Alternatively the antigen recognition receptor may be an NK cell activating receptor. There are two different kinds of surface receptors which are responsible for triggering NK-mediated natural cytotoxicity: the NK KARs (Killer Activation Receptors) and the NK KIRs (Killer Inhibitory Receptors) which produce opposite signals. It is the balance between these competing signals that determines whether or not the cytotoxic activity of the NK cell should be triggered.
KARs typically have noncovalently linked subunits that contain immunoreceptor tyrosine-based activation motifs (ITAMs) in their cytoplasmic tails such as CD3ζ, the γc chain, or one of two adaptor proteins DAP10 and DAP12. In an analogous fashion to the TCR on a T-cell, the ITAMs associated with KARs are involved in the facilitation of signal transduction in NK cells. When the binding of an activation ligand to an KAR complex occurs, the tyrosine residues in the ITAMs in the associated chain are phosphorylated by kinases, and a signal that promotes natural cytotoxicity is conveyed to the interior of the NK cell.
The effector immune cell of the present invention is engineered such that, when the cell surface receptor or receptor complex of the effector immune cell specifically binds an antigen recognition receptor of a target immune cell, the effector immune cell wins the battle between the two immune cells, such that the target immune cell is killed by the effector immune cell, rather than the effector immune cell being killed by the target immune cell.
There are various ways in which the effector immune cell can be engineered to have a selective advantage over the target immune cell at the time and place where the two cells encounter each other.
For example:
1) the effector immune cell may be engineered such that it is resistant to one or more immunosuppressive drugs
2) the effector immune cell may be engineered such that it is capable of transmitting one or more inhibitory immune signals
The effector immune cell may be engineered such that it is resistant to one or more immunosuppressive drugs. This means that in the presence of the immunosuppressive drug, the target immune cell will be suppressed and the effector cell will be resistant to suppression, giving the effector immune cell a selective advantage.
The immunosuppressive drug may be administered to population of immune cells in vivo or in vitro. For example, the immunosuppressive drug may be administered to a patient prior to or at the same time as administration of a composition comprising the effector immune cells. Alternatively the immunosuppressive drug may be administered to a transplant prior to or at the same time as administration of a composition comprising the effector immune cells to the transplant and before the transplant is introduced into a patient.
Immunosuppressive drugs, also known as immunosuppressive agents, immunosuppressants and antirejection medications are drugs that inhibit or prevent activity of the immune system. Immunosuppressive drugs are commonly used in immunosuppressive therapy, for example to:
(i) prevent the rejection of transplanted organs and tissues (e.g., bone marrow, heart, kidney, liver) and cells (e.g. during hematopoietic stem cell transplantation and allogeneic immunotherapy approaches);
(ii) treat autoimmune diseases or diseases that are most likely of autoimmune origin (e.g., rheumatoid arthritis, multiple sclerosis, myasthenia gravis, psoriasis, vitiligo, granulomatosis with polyangiitis, systemic lupus erythematosus, systemic sclerosis/scleroderma, sarcoidosis, focal segmental glomerulosclerosis, Crohn's disease, Behcet's Disease, pemphigus, and ulcerative colitis); and
(iii) treat some other non-autoimmune inflammatory diseases (e.g., long term allergic asthma control), ankylosing spondylitis.
A large number of immunosuppressive drugs are known and routinely used during transplants and immunotherapy approaches. The immunosuppressive drug may be, for example, a small molecule or an antibody or other biologic. The immunosuppressive drug may be a glucocorticoid, cytostatic, a polyclonal or monoclonal antibody or a drug which acts on immunophilins. These are described in more detail below.
Glucocorticoids are a class of corticosteroids, which are a class of steroid hormones. Glucocorticoids are corticosteroids that bind to the glucocorticoid receptor. Examples include: cortisol (hydrocortisone), cortisone, prednisone, prednisolone, methylprednisolone, dexamethasone, betamethasone, triamcinolone, fludrocortisone acetate and deoxycorticosterone acetate.
In pharmacologic (i.e. supraphysiologic) doses, glucocorticoids are used to suppress various allergic, inflammatory, and autoimmune disorders. They are also administered as post-transplantory immunosuppressants to prevent the acute transplant rejection and graft-versus-host disease.
Glucocorticoids suppress the cell-mediated immunity. They act by inhibiting genes that code for the cytokines Interleukin 1 (IL-1), IL-2, IL-3, IL-4, IL-5, IL-6, IL-8, and TNF-alpha, the most important of which is IL-2. A lower level of cytokine production reduces T cell proliferation. Glucocorticoids also suppress the humoral immunity, causing B cells to express smaller amounts of IL-2 and IL-2 receptors. This diminishes both B cell clone expansion and antibody synthesis.
Glucocorticoids influence all types of inflammatory events, no matter their cause. They induce the lipocortin-1 (annexin-1) synthesis, which then binds to cell membranes preventing the phospholipase A2 from coming into contact with its substrate arachidonic acid. This leads to diminished eicosanoid production. The cyclooxygenase (both COX-1 and COX-2) expression is also suppressed, potentiating the effect.
Glucocorticoids also stimulate the lipocortin-1 escaping to the extracellular space, where it binds to the leukocyte membrane receptors and inhibits various inflammatory events: epithelial adhesion, emigration, chemotaxis, phagocytosis, respiratory burst, and the release of various inflammatory mediators (lysosomal enzymes, cytokines, tissue plasminogen activator, chemokines, etc.) from neutrophils, macrophages, and mastocytes.
Cytostatics inhibit cell division. In immunotherapy, they are used in smaller doses than in the treatment of malignant diseases. They affect the proliferation of both T cells and B cells. Due to their highest effectiveness, purine analogs are most frequently administered. Cytostatics include alkylating agents, antimetabolites, methotrexate, azathioprine and mercaptopurine, and cytotoxic antibiotics.
The alkylating agents used in immunotherapy are nitrogen mustards (cyclophosphamide), nitrosoureas, platinum compounds, and others. Cyclophosphamide (Baxter's Cytoxan) is probably the most potent immunosuppressive compound. In small doses, it is very efficient in the therapy of systemic lupus erythematosus, autoimmune hemolytic anemias, granulomatosis with polyangiitis, and other immune diseases. High doses cause pancytopenia and hemorrhagic cystitis.
Antimetabolites interfere with the synthesis of nucleic acids. These include: folic acid analogues, such as methotrexate; purine analogues, such as azathioprine and mercaptopurine; pyrimidine analogues, such as fluorouracil; and protein synthesis inhibitors.
Methotrexate is a folic acid analogue. It binds dihydrofolate reductase and prevents synthesis of tetrahydrofolate. It is used in the treatment of autoimmune diseases (for example rheumatoid arthritis or Behcet's Disease) and in transplantations.
Azathioprine (Prometheus' Imuran), is the main immunosuppressive cytotoxic substance. It is extensively used to control transplant rejection reactions. It is nonenzymatically cleaved to mercaptopurine, that acts as a purine analogue and an inhibitor of DNA synthesis. Mercaptopurine itself can also be administered directly.
By preventing the clonal expansion of lymphocytes in the induction phase of the immune response, it affects both the cell and the humoral immunity. It is also efficient in the treatment of autoimmune diseases.
Among the cytotoxic antibiotics, dactinomycin is the most important. It is used in kidney transplantations. Other cytotoxic antibiotics are anthracyclines, mitomycin C, bleomycin, mithramycin.
Antibodies are sometimes used as a quick and potent immunosuppressive therapy to prevent the acute rejection reactions as well as a targeted treatment of lymphoproliferative or autoimmune disorders (e.g., anti-CD20 monoclonals). They may be polyclonal or monoclonal.
Heterologous polyclonal antibodies are obtained from the serum of animals (e.g., rabbit, horse), and injected with the patient's thymocytes or lymphocytes. The antilymphocyte (ALG) and antithymocyte antigens (ATG) are being used. They are part of the steroid-resistant acute rejection reaction and grave aplastic anemia treatment. However, they are added primarily to other immunosuppressives to diminish their dosage and toxicity. They also allow transition to cyclosporin therapy.
Polyclonal antibodies inhibit T lymphocytes and cause their lysis, which is both complement-mediated cytolysis and cell-mediated opsonization followed by removal of reticuloendothelial cells from the circulation in the spleen and liver. In this way, polyclonal antibodies inhibit cell-mediated immune reactions, including graft rejection, delayed hypersensitivity (i.e., tuberculin skin reaction), and the graft-versus-host disease (GVHD), but influence thymus-dependent antibody production.
Two preparations available to the market are: Atgam, obtained from horse serum, and Thymoglobuline, obtained from rabbit serum. Polyclonal antibodies affect all lymphocytes and cause general immunosuppression, possibly leading to post-transplant lymphoproliferative disorders (PTLD) or serious infections, especially by cytomegalovirus. To reduce these risks, treatment is provided in a hospital, where adequate isolation from infection is available.
Monoclonal antibodies cause fewer side-effects. Especially significant are the IL-2 receptor- (CD25-) and CD3-directed antibodies. They are used to prevent the rejection of transplanted organs, but also to track changes in the lymphocyte subpopulations. It is reasonable to expect similar new drugs in the future.
Muromonab-CD3 is a murine anti-CD3 monoclonal antibody of the IgG2a type that prevents T-cell activation and proliferation by binding the T-cell receptor complex present on all differentiated T cells. As such it is one of the most potent immunosuppressive substances and is administered to control the steroid- and/or polyclonal antibodies-resistant acute rejection episodes. As it acts more specifically than polyclonal antibodies it is also used prophylactically in transplantations.
Interleukin-2 is an important immune system regulator necessary for the clone expansion and survival of activated lymphocytes T. Its effects are mediated by the trimer cell surface receptor IL-2a, consisting of the α, β, and γ chains. The IL-2a (CD25, T-cell activation antigen, TAC) is expressed only by the already-activated T lymphocytes. Therefore, it is of special significance to the selective immunosuppressive treatment, and research has been focused on the development of effective and safe anti-IL-2 antibodies. Basiliximab (Simulect) and daclizumab (Zenapax) are chimeric mouse/human anti-Tac antibodies. These drugs act by binding the IL-2a receptor's α chain, preventing the IL-2 induced clonal expansion of activated lymphocytes and shortening their survival. They are used, for example in the prophylaxis of the acute organ rejection after bilateral kidney transplantation.
Tacrolimus and cyclosporin are a calcineurin inhibitor (CNI). Calcineurin has been in use since 1983 and is one of the most widely used immunosuppressive drugs. It is a cyclic fungal peptide, composed of 11 amino acids.
Cyclosporin is thought to bind to the cytosolic protein cyclophilin (an immunophilin) of immunocompetent lymphocytes, especially T-lymphocytes. This complex of cyclosporin and cyclophilin inhibits the phosphatase calcineurin, which under normal circumstances induces the transcription of interleukin-2. The drug also inhibits lymphokine production and interleukin release, leading to a reduced function of effector T-cells.
Tacrolimus is a product of the bacterium Streptomyces tsukubaensis. It is a macrolide lactone and acts by inhibiting calcineurin.
The drug is used primarily in liver and kidney transplantations, although in some clinics it is used in heart, lung, and heart/lung transplantations. It binds to the immunophilin FKBP1A, followed by the binding of the complex to calcineurin and the inhibition of its phosphatase activity. In this way, it prevents the cell from transitioning from the G0 into G1 phase of the cell cycle. Tacrolimus is more potent than cyclosporin and has less pronounced side-effects.
Sirolimus (rapamycin) is a macrolide lactone, produced by the actinomycete bacterium Streptomyces hygroscopicus. It is used to prevent rejection reactions.
Although it is a structural analogue of tacrolimus, it acts somewhat differently and has different side-effects.
Contrary to cyclosporin and tacrolimus which affect the first phase of T lymphocyte activation, sirolimus affects the second phase, namely signal transduction and lymphocyte clonal proliferation. It binds to FKBP1A like tacrolimus, however the complex does not inhibit calcineurin but another protein, mTOR. Therefore, sirolimus acts synergistically with cyclosporin and, in combination with other immunosuppressants, has few side effects. Also, it indirectly inhibits several T lymphocyte-specific kinases and phosphatases, hence preventing their transition from G1 to S phase of the cell cycle. In a similar manner, Sirolimus prevents B cell differentiation into plasma cells, reducing production of IgM, IgG, and IgA antibodies. It is also active against tumors that are PI3K/AKT/mTOR-dependent.
Everolimus is an analog of sirolimus and also is an mTOR inhibitor.
Other immunosuppressive drugs include interferons, opioids, TNF binding proteins, mycophenolate and small biological agents.
IFN-β suppresses the production of Th1 cytokines and the activation of monocytes. It is used to slow down the progression of multiple sclerosis. IFN-γ is able to trigger lymphocytic apoptosis.
Opioids are substances that act on opioid receptors to produce morphine-like effects. Prolonged use of opioids may cause immunosuppression of both innate and adaptive immunity. Decrease in proliferation as well as immune function has been observed in macrophages, as well as lymphocytes. It is thought that these effects are mediated by opioid receptors expressed on the surface of these immune cells.
A TNF-α (tumor necrosis factor-alpha) binding protein is a monoclonal antibody or a circulating receptor such as infliximab (Remicade), etanercept (Enbrel), or adalimumab (Humira) that binds to TNF-α, preventing it from inducing the synthesis of IL-1 and IL-6 and the adhesion of lymphocyte-activating molecules. They are used in the treatment of rheumatoid arthritis, ankylosing spondylitis, Crohn's disease, and psoriasis.
TNF or the effects of TNF are also suppressed by various natural compounds, including curcumin (an ingredient in turmeric) and catechins (in green tea).
Mycophenolic acid acts as a non-competitive, selective, and reversible inhibitor of Inosine-5′-monophosphate dehydrogenase (IMPDH), which is a key enzyme in the de novo guanosine nucleotide synthesis. In contrast to other human cell types, lymphocytes B and T are very dependent on this process. Mycophenolate mofetil is used in combination with cyclosporin or tacrolimus in transplant patients.
Small biological agents include fingolimod which is a synthetic immunosuppressant. It increases the expression or changes the function of certain adhesion molecules (α4/β7 integrin) in lymphocytes, so they accumulate in the lymphatic tissue (lymphatic nodes) and their number in the circulation is diminished. In this respect, it differs from all other known immunosuppressants.
Myriocin is an atypical amino acid and an antibiotic derived from certain thermophilic fungi. It has been shown to inhibit the proliferation of cytotoxic T-cells.
The effector cell of the present invention may comprise one or more mutations which increases its resistance to one or more immune suppressive drugs. For example, effector cell may comprise one or more mutations which renders the cell resistant to tacrolimus and/or cyclosporin.
The effector cell may comprise a nucleic acid sequence encoding calcineurin (CN) with one or more mutations. Calcineurin (CaN) is a calcium and calmodulin dependent serine/threonine protein phosphatase which activates the T cells of the immune system. Calcineurin activates nuclear factor of activated T cell cytoplasmic (NFATc), a transcription factor, by dephosphorylating it. The activated NFATc is then translocated into the nucleus, where it upregulates the expression of interleukin 2 (IL-2), stimulating the T cell response. Calcineurin is the target of a class of drugs called calcineurin inhibitors, which include cyclosporin, voclosporin, pimecrolimus and tacrolimus. Brewin et al (2009; Blood 114: 4792-4803) describe various calcineurin mutants which render cytotoxic T lymphocytes resistant to tacrolimus and/or cyclosporin.
Calcineurin is a heterodimer of a 61-kD calmodulin-binding catalytic subunit, calcineurin A and a 19-kD Ca2+-binding regulatory subunit, calcineurin B. There are three isozymes of the catalytic subunit, each encoded by a separate gene (PPP3CA, PPP3CB, and PPP3CC) and two isoforms of the regulatory, also encoded by separate genes (PPP3R1, PPP3R2). The amino acid sequences for all of the polypeptides encoded by these genes are available from Uniprot, with the following accession numbers: PPP3CA: Q08209; PPP3CB: P16298; PPP3CC: P48454; PPP3R1: P63098; and PPP3R2: Q96LZ3.
The amino acid sequence for calcineurin A, alpha isoform is shown below as SEQ ID No. 65
Mutant calcineurin A may comprise a mutation at one or more of the following positions with reference to SEQ ID No. 65: V314; Y341; M347; T351; W352; S353; L354; F356; and K360.
Mutant calcineurin A may comprise one or more of the following substitution mutations with reference to SEQ ID No. 65:
Mutant calcineurin A may comprise one or more of the following mutation combinations with reference to SEQ ID No. 65:
The amino acid sequence for calcineurin B, type 1 is shown below as SEQ ID No. 66
Mutant calcineurin B may comprise a mutation at one or more of the following positions with reference to SEQ ID No. 66: Q51; L116; M119; V120; G121; N122; N123; L124; K125; and K165.
Mutant calcineurin B may comprise one or more of the following substitution and optionally insertion mutations with reference to SEQ ID No. 66:
Mutant calcineurin B may comprise one or more of the following mutation combinations with reference to SEQ ID No. 66:
In particular, mutant calcineurin B may comprise the following mutation combination with reference to SEQ ID No. 66: L124T and K125-LA-Ins. This is the module known as “CnB30” described in the Examples section. The CnB30 has the amino acid shown as SEQ ID No. 131.
In the study described in Brewin et al 2009 (as above), the following CNa mutants showed resistance to FK506:
The following CNa mutants showed resistance to cyclosporin A:
The following CNb mutants showed resistance to FK506:
The following CNb mutants showed resistance to cyclosporin A:
In particular, it is reported in Brewin et al 2009 (as above) that:
The effector immune cell of the present invention may express a variant calcineurin A comprising one or more mutations in the CNa amino acid sequence and/or a variant calcineurin B comprising one or more mutations in the CNb amino acid sequence, which increases resistance of the effector immune cell to one or more calcineurin inhibitors.
In particular, the effector immune cell may express a variant calcineurin A and/or a variant calcineurin B as listed above which confers resistance to cyclosporin A and/or tacrolimus (FK506).
The effector immune cell may be engineered to express a dominant negative C-terminal Src kinase (dnCSK). It has previously been shown that the function of CAR-expressing cells, such as CAR-T cells, can be enhanced by co-expression of a dnCSK (United Kingdom patent application No. 1919017.2). Expression of dominant negative CSK in a CAR-T cell appears to increase the sensitivity of the CAR-T cell, improving cytotoxicity and cytokine release especially in response to low-density target antigens.
The present inventors have now found that expression of dnCSK also confers on the cell general resistance to immunosuppression. The expression of dnCSK provides a “blanket” resistance to immunosuppression, making the cell less sensitive to immunosuppressive drugs in general.
C-terminal Src kinase (CSK), also known as Tyrosine-protein kinase, is an enzyme which phosphorylates tyrosine residues located in the C-terminal end of Src-family kinases (SFKs) including SRC, HCK, FYN, LCK, LYN and YES1, thus suppressing their activity.
Src Family Kinases (SFKs), such as Lck, are made up of a N-terminal myristoyl group, that permits membrane localisation, attached to an SH4 domain, an SH3 domain, an SH2 domain and a protein tyrosine kinase domain (SH1 domain).
There is a conserved tyrosine residue in the activation loop and one in the C-terminal tail, phosphorylation of the activation loop tyrosine by trans-autophosphorylation increases SFK activity, whereas phosphorylation of the C-terminal tyrosine by C-terminal Src kinase (CSK) inhibits SFK activity
Csk phosphorylates the negative regulatory C-terminal tyrosine residue Y505 of Lck to maintain Lck in an inactive state. In resting T cells, Csk is targeted to lipid rafts through engagement of its SH2 domain with phosphotyrosine residue pY317 of PAG. PAG is expressed as a tyrosine phosphorylated protein in nonstimulated T-cells. This interaction of Csk and PAG allows activation of Csk and inhibition of Lck.
Upon TCR activation, CD45 is excluded from membrane microdomains and dephosphorylates PAG, leading to Csk detaching from the plasma membrane.
The amino acid sequence of human CSK is available from Uniprot Accession No 41240 and is shown below as SEQ ID No. 67. In this sequence, residues 9-70 correspond to the SH3 domain, residues 82-171 correspond to the SH2 domain; and residues 195-449 correspond to the protein kinase domain.
The cells of the present invention may express a dominant negative C-terminal Src kinase (dnCSK).
The dominant negative CSK may lack a functional protein kinase domain. The dnCSK may not comprise a kinase domain or it may comprise a partially or completely inactive kinase domain. The kinase domain may be inactivated by, for example, truncation or mutation of one or more amino acids.
The dnCSK may, for example, be:
The effector immune cell may express a dnCSK which completely lacks a kinase domain. For example, the dnCSK may comprise the SH2 domain and optionally the SH3 domain, but be truncated to remove the kinase domain.
Alternatively, the effector immune cell may express a dnCSK which comprises a partially truncated kinase domain having part of a phosphatase, for example a portion of the sequence from residues 195-449 of SEQ ID No. 67, provided that the truncated kinase has reduced capacity to phosphorylate the C-terminal tyrosine residue Y505 of Lck compared to wild-type CSK. The truncated kinase may have effectively no residual kinase activity.
The dnCSK may be a truncated CSK which retains the capacity to bind a transmembrane adaptor protein such as PAG, Lime and/or Dok1/2 which recruits wild-type CSK to the cell membrane but lacks a functional kinase domain.
The dnCSK may have the sequence shown as SEQ ID No. 68, which corresponds to the wild-type CSK sequence (SEQ ID No. 67) minus the kinase domain.
Alternatively the dnCSK may have the sequence shown as SEQ ID No. 69, which corresponds to the wild-type CSK sequence (SEQ ID No. 67) minus the kinase and SH3 domains.
The effector immune cells of the present invention may express a dnCSK which comprises a kinase domain which is inactivated so that it has reduced or no capacity to phosphorylate proteins such as Lck.
The kinase domain may, for example, comprise one or more amino acid mutations such that it has reduced kinase activity compared to the wild-type sequence.
The mutation may, for example, be an addition, deletion or substitution.
The mutation may comprise the deletion or substitution of one or more lysine residues.
The variant kinase sequence may have a mutation to lysine at position 222 with reference to the sequence shown as SEQ ID No. 67.
The dnCSK of the invention may have the sequence shown as SEQ ID No 70, which corresponds to the full length CSK sequence with a K222R substitution. This mutation is shown in bold and underlined in SEQ ID No. 70. Alternatively, the dnCSK of the invention may have a sequence equivalent to SEQ ID No. 70 in which the SH3 domain has been deleted.
The dnCSK may comprise a mutated CSK whose catalytic activity is inhibited by an agent. For example, the dnCSK may have the sequence shown as SEQ ID No. 71, which comprises the mutation T266G compared to the wildtype sequence shown as SEQ ID No. 67 and is known as “CSKas”. The substitution is in bold and underlined in SEQ ID No. 71. Alternatively, the dnCSK of the invention may have a sequence equivalent to SEQ ID No. 71 in which the SH3 domain has been deleted.
The catalytic activity of CSKas is inhibited by 3-iodo-benzyl-PP1. In the presence of this molecule, therefore CSKas acts as a dominant negative version of CSK, competing with the wild-type enzyme for binding to membrane proteins such as PAG, Lime and/or Dok1/2 which recruit wild-type CSK to the cell membrane.
The effector immune cell of the present invention may express or overexpress an immunoinhibitory molecule or a fusion protein comprising the extracellular domain of an immunoinhibitory molecule.
In vivo, membrane-bound immunoinhibitory receptors such as PD-1, LAG-3, 2B4 or BTLA 1 inhibit T cell activation. During T cell activation (illustrated schematically in
The target immune cell will naturally express a variety of such ITIM containing immunoinhibitory receptors, such as PD-1, LAG3, TIM-3, TIGIT, BTLA, VISTA, CEACAM1-R, KIR2DL4, B7-H3 and B7-H4.
By engineering the effector immune cell of the invention to express a ligand for one or more immunoinhibitory receptors or the extracellular domain of such a ligand, when a synapse forms between the two cells the effector immune cell will inhibit T cell activation in the target immune cell. This “one-way” inhibition gives the effector immune cell an advantage over the target immune cell in terms of activation meaning that the effector immune cell will prevail, killing the target immune cell.
The effector immune cell may express or overexpress a ligand for an immunoinhibitory receptor on the target immune cell. The immunoinhibitory receptor expressed by the target cell may, for example, be selected from: PD-1, LAG3, TIM-3, TIGIT, BTLA, VISTA, CEACAM1-R, KIR2DL4, B7-H3 and B7-H4.
The immunoinhibitory molecule, or extracellular domain thereof, expressed by the effector immune cell may be, for example, selected from: PD-L1, PD-L2, HVEM, CD155, VSIG-3, Galectin-9, HLA-G, CEACAM-1, LSECTin, FGL1, B7-H3 and B7-H4.
Programmed death-ligand 1 (PD-L1), also known as cluster of differentiation 274 (CD274) or B7 homolog 1 (B7-H1), is a 40 kDa type 1 transmembrane protein expressed by cancer cells helping them evade anti-tumour immunity. Engagement of PD-L1 with its receptor PD-1 on T cells delivers a signal that inhibits TCR-mediated activation of IL-2 production and T cell proliferation.
The amino acid sequence of human PD-L1 is available from Uniprot, accession No. Q9NZQ7 and shown below as SEQ ID No. 72.
The signal peptide, extracellular domain and transmembrane domain of PD-L1 are shown below as SEQ ID No. 73, 74 and 75 respectively.
The effector immune cell of the present invention may comprise the PD-L1 extracellular domain and optionally the PD-L1 signal peptide and/or PD-L1 transmembrane domain.
Programmed cell death 1 ligand 2 (also known as PD-L2, B7-DC) is an immune checkpoint receptor ligand which plays a role in negative regulation of the adaptive immune response. PD-L2 is one of two known ligands for Programmed cell death protein 1 (PD-1), the other being PD-1.
PD-L2 is primarily expressed on professional antigen presenting cells including dendritic cells (DCs) and macrophages. PD-L2 binding to PD-1 can activate pathways inhibiting TCR/BCR-mediated immune cell activation and PD-L2, PD-1, and PD-1 expressions are important in the immune response to certain cancers.
The amino acid sequence of human PD-L2 is available from Uniprot, accession No. Q9BQ51 and shown below as SEQ ID No. 76.
The signal peptide, extracellular domain and transmembrane domain of PD-L2 are shown below as SEQ ID No. 77, 78 and 79 respectively.
The effector immune cell of the present invention may comprise the PD-L2 extracellular domain and optionally the PD-L2 signal peptide and/or PD-L2 transmembrane domain.
Herpesvirus entry mediator (HVEM), also known as tumour necrosis factor receptor superfamily member 14 (TNFRSF14), is a human cell surface receptor of the TNF-receptor superfamily. The cytoplasmic region of this receptor binds to several TNF receptor associated factor (TRAF) family members, which mediate the signal transduction pathways that activate the immune response. TNFRSF14 has been shown to interact with TRAF2, TNFSF14 and TRAF5.
The amino acid sequence of HVEM is available from Uniprot, accession No. Q92956 and shown below as SEQ ID No. 80.
The signal peptide, extracellular domain and transmembrane domain of HVEM are shown below as SEQ ID No. 81, 82 and 83 respectively.
The effector immune cell of the present invention may comprise the HVEM extracellular domain and optionally the HVEM signal peptide and/or HVEM transmembrane domain.
CD155 (cluster of differentiation 155) also known as the poliovirus receptors is a Type I transmembrane glycoprotein in the immunoglobulin superfamily. CD155 is involved in intestinal humoral immune responses and positive selection of select MHC-independent T cells in the thymus.
The amino acid sequence of CD155 is available from Uniprot, accession No. P15151 and shown below as SEQ ID No. 84.
The signal peptide, extracellular domain and transmembrane domain of CD155 are shown below as SEQ ID No. 85, 86 and 87 respectively.
The effector immune cell of the present invention may comprise the CD155 extracellular domain and optionally the CD155 signal peptide and/or CD155 transmembrane domain.
VSIG-3, also known as IGSF11, is a ligand of B7 family member VISTA. VSIG-3 inhibits human T-cell proliferation in the presence of T-cell receptor signalling and significantly reduces cytokine and chemokine production by human T cells including IFN-γ, IL-2, IL-17, CCL5/Rantes, CCL3/MIP-1a, and CXCL11/I-TAC.
The amino acid sequence of VSIG-3 is available from Uniprot, accession No. Q5DX21 and shown below as SEQ ID No. 88.
The signal peptide, extracellular domain and transmembrane domain of VSIG-3 are shown below as SEQ ID No. 89, 90 and 91 respectively.
The effector immune cell of the present invention may comprise the VSIG-3 extracellular domain and optionally the VSIG-3 signal peptide and/or VSIG-3 transmembrane domain.
Galectin-9 is a ligand for HAVCR2 (TIM-3) and is expressed on various tumour cells. The interaction between galectin-9 and HANCR2 attenuates T-cell expansion and effector function in the tumor microenvironment. Binding to HAVCR2 induces T-helper type 1 lymphocyte (Th1) death. Galectin-9 has N- and C-terminal carbohydrate-binding domains connected by a link peptide.
The amino acid sequence of Galectin-9 is available from Uniprot, accession No. O00182 and shown below as SEQ ID No. 92.
The signal peptide, Galectin 1 domain and Galectin 2 domain of Galectin-9 are shown below as SEQ ID No. 93, 94 and 95 respectively.
The effector immune cell of the present invention may comprise the full length Galectin-9 sequence, with or without the signal peptide. Alternatively the effector immune cell may just comprise the Galectin 1 domain or the Galectin 2 domain or the HAVCR2-binding domain from Galectin-9, -1 or -2.
The effector immune cell of the present invention may comprise a membrane-tethered version of galectin-9 or a portion thereof. Galectin-9 may be tethered to the membrane using a transmembrane domain and optionally a spacer sequence and/or endodomain. For example, galectin-9 or a portion thereof could be tethered to the membrane using the CD8 stalk spacer, transmembrane domain and truncated endodomain which has been previously described in WO2013/153391 for the sort-suicide gene RQR8
HLA-G histocompatibility antigen, class I, G, also known as human leukocyte antigen G (HLA-G) belongs to the HLA nonclassical class I heavy chain paralogues. This class I molecule is a heterodimer consisting of a heavy chain and a light chain (beta-2 microglobulin). HLA-G is a ligand for NK cell inhibitory receptor KIR2DL4, and, during pregnancy, expression of this HLA by the trophoblast defends it against NK cell-mediated death.
The amino acid sequence of HLA-G is available from Uniprot, accession No. P17693 and shown below as SEQ ID No. 96.
The signal peptide, extracellular domain and transmembrane domain of HLA-G are shown below as SEQ ID No. 97, 98 and 99 respectively.
The effector immune cell of the present invention may comprise the HLA-G extracellular domain and optionally the HLA-G signal peptide and/or HLA-G transmembrane domain.
Carcinoembryonic antigen-related cell adhesion molecule 1 (biliary glycoprotein) (CEACAM1) also known as CD66a (Cluster of Differentiation 66a), is a human glycoprotein, and a member of the carcinoembryonic antigen (CEA) gene family.
CEACAM-1 plays a role as coinhibitory receptor in the immune response of T cells, natural killer (NK) and neutrophils. Upon TCR/CD3 complex stimulation, CEACAM-1 inhibits TCR-mediated cytotoxicity by blocking granule exocytosis by mediating homophilic binding to adjacent cells, allowing interaction with and phosphorylation by LCK and interaction with the TCR/CD3 complex which recruits PTPN6 resulting in dephosphorylation of CD247 and ZAP70. CEACAM-1 also inhibits T cell proliferation and cytokine production through inhibition of the JNK cascade and plays a crucial role in regulating autoimmunity and anti-tumor immunity by inhibiting T cell through its interaction with HAVCR2. Upon natural killer (NK) cells activation, CEACAM-1 inhibits KLRK1-mediated cytolysis of CEACAM1-bearing tumor cells by trans-homophilic interactions with CEACAM1 on the target cell and lead to cis-interaction between CEACAM1 and KLRK1, allowing PTPN6 recruitment and then VAV1 dephosphorylation.
The amino acid sequence of CEACAM-1 is available from Uniprot, accession No. P13688 and shown below as SEQ ID No. 100.
The signal peptide, extracellular domain and transmembrane domain of CEACAM-1 are shown below as SEQ ID No. 101, 102 and 103 respectively.
The effector immune cell of the present invention may comprise the CEACAM-1 extracellular domain and optionally the CEACAM-1 signal peptide and/or CEACAM-1 transmembrane domain.
LSECTin, or Liver sinusoidal endothelial cell lectin, is a ligand for LAG-3 and negative regulator of T-cell proliferation and T-cell mediated immunity
The amino acid sequence of LSECTin is available from Uniprot, accession No. Q6UXB4 and shown below as SEQ ID No. 104.
The cytoplasmic domain, transmembrane domain and extracellular domain of LSECTin are shown below as SEQ ID No. 105, 106 and 107 respectively.
The effector immune cell of the present invention may comprise the LSECTin extracellular domain and optionally the LSECTin signal peptide and/or LSECTin transmembrane domain.
Fibrinogen-like protein 1 (FGL-1) is a protein that is structurally related to fibrinogen. It is an immune suppressive molecule that inhibits antigen-specific T-cell activation by acting as a major ligand of LAG3. FGL-1 is responsible for LAG3 T-cell inhibitory function and binds LAG3 independently from MHC class II (MHC-II).
The amino acid sequence of FGL1 is available from Uniprot, accession No. Q08830 and shown below as SEQ ID No. 108.
The signal peptide of FGL1 is shown below as SEQ ID No. 109.
The effector immune cell of the present invention may comprise FGL1 or the LAG-3 binding domain from FGL1 and optionally the FGL1 signal peptide.
The effector immune cell of the present invention may comprise a membrane-tethered version of FGL1 or a portion thereof. FGL1 may be tethered to the membrane using a transmembrane domain and optionally a spacer sequence and/or endodomain. For example, FGL1 or a portion thereof could be tethered to the membrane using the CD8 stalk spacer, transmembrane domain and truncated endodomain which has been previously described in WO2013/153391 for the sort-suicide gene RQR8.
B7-H3, also known as CD276, is an immune checkpoint molecule expressed by some solid tumours and is involved in the regulation of T-cell-mediated immune response.
The amino acid sequence of B7-H3 is available from Uniprot, accession No. Q5ZPR3 and shown below as SEQ ID No. 110.
The signal peptide, extracellular domain and transmembrane domain of B7-H3 are shown below as SEQ ID No. 111, 112 and 113 respectively.
The effector immune cell of the present invention may comprise the B7-H3 extracellular domain and optionally the B7-H3 signal peptide and/or B7-H3 transmembrane domain.
B7-H4, also known as V-set domain-containing T-cell activation inhibitor 1, is another member of the B7 family of co-stimulatory proteins which acts as an immune checkpoint molecule. B7-H4 negatively regulates T-cell-mediated immune response by inhibiting T-cell activation, proliferation, cytokine production and development of cytotoxicity. When expressed on the cell surface of tumour macrophages, B7-H4 plays an important role, together with regulatory T-cells (Treg), in the suppression of tumour-associated antigen-specific T-cell immunity.
The amino acid sequence of B7-H4 is available from Uniprot, accession No. Q7Z7D3 and shown below as SEQ ID No. 114.
The signal peptide, extracellular domain and transmembrane domain of B7-H4 are shown below as SEQ ID No. 115, 116 and 117 respectively.
The effector immune cell of the present invention may comprise the B7-H4 extracellular domain and optionally the B7-H4 signal peptide and/or B7-H4 transmembrane domain.
The effector immune cell may express a protein comprising the extracellular domain of PD-L1, PD-L2, HVEM, CD155, VSIG-3, Galectin-9, HLA-G, CEACAM-1, LSECTin, FGL1, B7-H3 B7-H4 with the sequences shown above or a variant thereof, for example a variant having at least 80%, 90%, 95% or 99% amino acid identity, provided that the resultant protein molecule retains the capacity to bind an inhibitory immunoreceptor on the target immune cell and inhibit activation of the target immune cell.
The effector immune may express a fusion protein comprising the extracellular domain of an immunoinhibitory molecule and a membrane localisation domain.
The membrane localisation domain may be any sequence which causes the fusion protein to be attached to or held in a position proximal to the plasma membrane.
The membrane localisation domain may be or comprise a sequence which causes the nascent polypeptide to be attached initially to the ER membrane. As membrane material “flows” from the ER to the Golgi and finally to the plasma membrane, the protein remain associated with the membrane at the end of the synthesis/translocation process.
The membrane localisation domain may, for example, comprise a transmembrane sequence, a stop transfer sequence, a GPI anchor or a myristoylation/prenylation/palmitoylation site.
Myristoylation is a lipidation modification where a myristoyl group, derived from myristic acid, is covalently attached by an amide bond to the alpha-amino group of an N-terminal glycine residue. Myristic acid is a 14-carbon saturated fatty acid also known as n-Tetradecanoic acid. The modification can be added either co-translationally or post-translationally. N-myristoyltransferase (NMT) catalyzes the myristic acid addition reaction in the cytoplasm of cells. Myristoylation causes membrane targeting of the protein to which it is attached, as the hydrophobic myristoyl group interacts with the phospholipids in the cell membrane.
The fusion protein may comprise a sequence capable of being myristoylated by a NMT enzyme. The fusion protein may comprise a myristoyl group when expressed in a cell.
The fusion protein may comprise a consensus sequence such as: NH2-G1-X2-X3-X4-S5-X6-X7-X8 which is recognised by NMT enzymes.
Palmitoylation is the covalent attachment of fatty acids, such as palmitic acid, to cysteine and less frequently to serine and threonine residues of proteins. Palmitoylation enhances the hydrophobicity of proteins and can be used to induce membrane association. In contrast to prenylation and myristoylation, palmitoylation is usually reversible (because the bond between palmitic acid and protein is often a thioester bond). The reverse reaction is catalysed by palmitoyl protein thioesterases.
In signal transduction via G protein, palmitoylation of the a subunit, prenylation of the γ subunit, and myristoylation is involved in tethering the G protein to the inner surface of the plasma membrane so that the G protein can interact with its receptor.
The fusion protein may comprise a sequence capable of being palmitoylated. The fusion protein may comprise additional fatty acids when expressed in a cell which causes membrane localisation.
Prenylation (also known as isoprenylation or lipidation) is the addition of hydrophobic molecules to a protein or chemical compound. Prenyl groups (3-methyl-but-2-en-1-yl) facilitate attachment to cell membranes, similar to lipid anchors like the GPI anchor.
Protein prenylation involves the transfer of either a farnesyl or a geranyl-geranyl moiety to C-terminal cysteine(s) of the target protein. There are three enzymes that carry out prenylation in the cell, farnesyl transferase, Caax protease and geranylgeranyl transferase I.
The fusion protein may comprise a sequence capable of being prenylated. The fusion protein may comprise one or more prenyl groups when expressed in a cell which causes membrane localisation.
The fusion protein may comprise a cytoplasmic domain from a protein other than the immunoinhibitory molecule from which the extracellular domain was derived.
The cytoplasmic domain may stabilise the fusion protein. The cytoplasmic domain may, for example, be derived from CD19. the complete cytoplasmic domain of CD19 is shown below as SEQ ID No. 118. The fusion protein may comprise all, or a portion of this sequence. For example, the fusion protein may comprise the first 10, 15, 20 or 25 amino acids of the cytoplasmic portion of CD19. The fusion protein may comprise the first 19 amino acids of the cytoplasmic portion of CD19 and have the sequence shown as SEQ ID No. 119.
The effector immune cell may express a fusion protein comprising the extracellular domain of an immunoinhibitory molecule and a co-stimulatory endodomain.
The co-stimulatory endodomain may be or comprise an endodomain selected from one of the following proteins: 0028, ICOS, CTLA4, 41BB, 0027, 0030, OX-40, TACI, GITR, 002 and 0040. The amino acid sequences for these endodomains are shown below as SEQ ID No. 120-130 respectively.
The fusion protein may comprise a combination of endodomains, such as CD28 and OX-40 or CD28 and 4-1BB.
The fusion protein may comprise a variant of one of the sequences shown as SEQ ID No. 120-130, for example a variant having at least 80%, 90%, 95% or 99% amino acid identity, provided that the resultant sequence retains the capacity to provide a proliferation and/or survival signal to the effector immune cell.
The present invention also provides a nucleic acid sequence encoding a fusion protein which comprises the extracellular domain of an immunoinhibitory molecule, together with:
The endodomain may comprise one or more co-stimulatory domains as defined above.
As used herein, the terms “polynucleotide”, “nucleotide”, and “nucleic acid” are intended to be synonymous with each other.
It will be understood by a skilled person that numerous different polynucleotides and nucleic acids can encode the same polypeptide as a result of the degeneracy of the genetic code. In addition, it is to be understood that skilled persons may, using routine techniques, make nucleotide substitutions that do not affect the polypeptide sequence encoded by the polynucleotides described here to reflect the codon usage of any particular host organism in which the polypeptides are to be expressed.
Nucleic acids according to the invention may comprise DNA or RNA. They may be single-stranded or double-stranded. They may also be polynucleotides which include within them synthetic or modified nucleotides. A number of different types of modification to oligonucleotides are known in the art. These include methylphosphonate and phosphorothioate backbones, addition of acridine or polylysine chains at the 3′ and/or 5′ ends of the molecule. For the purposes of the use as described herein, it is to be understood that the polynucleotides may be modified by any method available in the art. Such modifications may be carried out in order to enhance the in vivo activity or life span of polynucleotides of interest.
The terms “variant”, “homologue” or “derivative” in relation to a nucleotide sequence include any substitution of, variation of, modification of, replacement of, deletion of or addition of one (or more) nucleic acid from or to the sequence.
The present invention also provides a nucleic acid construct which comprises: (i) a first nucleic acid sequence which encodes a cell surface receptor or part of a cell surface receptor complex as defined above; and
The first nucleic acid sequence may encode:
The second nucleic acid sequence may encode:
The third nucleic acid sequence may encode:
In a first embodiment, the present invention provides a nucleic acid construct which comprises:
In a second embodiment, the present invention provides a nucleic acid construct which comprises:
The nucleic acid construct of the second embodiment may also comprise a nucleic acid sequence encoding a CAR.
The nucleic acids may be in any order in the construct. Nucleic acids encoding discrete polypeptides may be separated by a co-expression site enabling co-expression of two polypeptides as separate entities. It may be a sequence encoding a cleavage site, such that the nucleic acid construct produces both polypeptides, joined by a cleavage site(s). The cleavage site may be self-cleaving, such that when the polypeptide is produced, it is immediately cleaved into individual peptides without the need for any external cleavage activity.
The cleavage site may be any sequence which enables the two polypeptides to become separated.
The term “cleavage” is used herein for convenience, but the cleavage site may cause the peptides to separate into individual entities by a mechanism other than classical cleavage. For example, for the Foot-and-Mouth disease virus (FMDV) 2A self-cleaving peptide (see below), various models have been proposed for to account for the “cleavage” activity: proteolysis by a host-cell proteinase, autoproteolysis or a translational effect (Donnelly et al (2001) J. Gen. Virol. 82:1027-1041). The exact mechanism of such “cleavage” is not important for the purposes of the present invention, as long as the cleavage site, when positioned between nucleic acid sequences which encode proteins, causes the proteins to be expressed as separate entities.
The cleavage site may, for example be a furin cleavage site, a Tobacco Etch Virus (TEV) cleavage site or encode a self-cleaving peptide.
A ‘self-cleaving peptide’ refers to a peptide which functions such that when the polypeptide comprising the proteins and the self-cleaving peptide is produced, it is immediately “cleaved” or separated into distinct and discrete first and second polypeptides without the need for any external cleavage activity.
The self-cleaving peptide may be a 2A self-cleaving peptide from an aphtho- or a cardiovirus. The primary 2A/2B cleavage of the aptho- and cardioviruses is mediated by 2A “cleaving” at its own C-terminus. In apthoviruses, such as foot-and-mouth disease viruses (FMDV) and equine rhinitis A virus, the 2A region is a short section of about 18 amino acids, which, together with the N-terminal residue of protein 2B (a conserved proline residue) represents an autonomous element capable of mediating “cleavage” at its own C-terminus (Donelly et al (2001) as above).
“2A-like” sequences have been found in picornaviruses other than aptho- or cardioviruses, ‘picornavirus-like’ insect viruses, type C rotaviruses and repeated sequences within Trypanosoma spp and a bacterial sequence (Donnelly et al (2001) as above).
The cleavage site may comprise the 2A-like sequence shown as SEQ ID No.132 (RAEGRGSLLTCGDVEENPGP).
The present invention also provides a vector, or kit of vectors, which comprises one or more nucleic acid sequence(s) or nucleic acid construct(s) according to the invention. Such a vector may be used to introduce the nucleic acid sequence(s) into a host cell so that it expresses a cell surface receptor or receptor complex, together with one or more proteins which confer a selective advantage of the host cell (i.e. effector immune cell) than a target immune cell.
A kit of vectors may comprise:
In a first embodiment, the present invention provides a kit of vectors which comprises:
In a second embodiment, the present invention provides a kit of vectors which comprises:
The kit of vectors of the second embodiment may also comprise vector comprising a nucleic acid sequence encoding a CAR.
The vector may, for example, be a plasmid or a viral vector, such as a retroviral vector or a lentiviral vector, or a transposon based vector or synthetic mRNA.
The vector may be capable of transfecting or transducing a cell, such as a T cell or a NK cell.
The present invention provides an effector immune cell.
The cell may comprise a nucleic acid sequence, a nucleic acid construct or a vector of the present invention.
The cell may be a cytolytic immune cell such as a T cell or an NK cell.
T cells or T lymphocytes are a type of lymphocyte that play a central role in cell-mediated immunity. They can be distinguished from other lymphocytes, such as B cells and natural killer cells (NK cells), by the presence of a T-cell receptor (TCR) on the cell surface. There are various types of T cell, as summarised below.
Helper T helper cells (TH cells) assist other white blood cells in immunologic processes, including maturation of B cells into plasma cells and memory B cells, and activation of cytotoxic T cells and macrophages. TH cells express CD4 on their surface. TH cells become activated when they are presented with peptide antigens by MHC class II molecules on the surface of antigen presenting cells (APCs). These cells can differentiate into one of several subtypes, including TH1, TH2, TH3, TH17, Th9, or TFH, which secrete different cytokines to facilitate different types of immune responses.
Cytolytic T cells (TC cells, or CTLs) destroy virally infected cells and tumor cells, and are also implicated in transplant rejection. CTLs express the CD8 at their surface. These cells recognize their targets by binding to antigen associated with MHC class I, which is present on the surface of all nucleated cells. Through IL-10, adenosine and other molecules secreted by regulatory T cells, the CD8+ cells can be inactivated to an anergic state, which prevent autoimmune diseases such as experimental autoimmune encephalomyelitis.
Memory T cells are a subset of antigen-specific T cells that persist long-term after an infection has resolved. They quickly expand to large numbers of effector T cells upon re-exposure to their cognate antigen, thus providing the immune system with “memory” against past infections. Memory T cells comprise three subtypes: central memory T cells (TCM cells) and two types of effector memory T cells (TEM cells and TEMRA cells). Memory cells may be either CD4+ or CD8+. Memory T cells typically express the cell surface protein CD45RO.
Regulatory T cells (Treg cells), formerly known as suppressor T cells, are crucial for the maintenance of immunological tolerance. Their major role is to shut down T cell-mediated immunity toward the end of an immune reaction and to suppress autoreactive T cells that escaped the process of negative selection in the thymus.
Two major classes of CD4+ Treg cells have been described—naturally occurring Treg cells and adaptive Treg cells.
Naturally occurring Treg cells (also known as CD4+CD25+FoxP3+ Treg cells) arise in the thymus and have been linked to interactions between developing T cells with both myeloid (CD11c+) and plasmacytoid (CD123+) dendritic cells that have been activated with TSLP. Naturally occurring Treg cells can be distinguished from other T cells by the presence of an intracellular molecule called FoxP3. Mutations of the FOXP3 gene can prevent regulatory T cell development, causing the fatal autoimmune disease IPEX.
Adaptive Treg cells (also known as Tr cells or Th3 cells) may originate during a normal immune response.
The cell may be a Natural Killer cell (or NK cell). NK cells form part of the innate immune system. NK cells provide rapid responses to innate signals from virally infected cells in an MHC independent manner
NK cells (belonging to the group of innate lymphoid cells) are defined as large granular lymphocytes (LGL) and constitute the third kind of cells differentiated from the common lymphoid progenitor generating B and T lymphocytes. NK cells are known to differentiate and mature in the bone marrow, lymph node, spleen, tonsils and thymus where they then enter into the circulation.
The cells of the invention may be any of the cell types mentioned above.
Cells according to the invention may either be created ex vivo either from a patient's own peripheral blood (1st party), or in the setting of a haematopoietic stem cell transplant from donor peripheral blood (2nd party), or peripheral blood from an unconnected donor (3rd party).
Alternatively, cells may be derived from ex vivo differentiation of inducible progenitor cells or embryonic progenitor cells to, for example, T or NK cells. Alternatively, an immortalized T-cell line which retains its lytic function and could act as a therapeutic may be used.
In all these embodiments, chimeric polypeptide-expressing cells are generated by introducing DNA or RNA coding for the chimeric polypeptide by one of many means including transduction with a viral vector, transfection with DNA or RNA.
The cell of the invention may be an ex vivo cell from a subject. The cell may be from a peripheral blood mononuclear cell (PBMC) sample. The cells may be activated and/or expanded prior to being transduced with nucleic acid encoding the molecules providing the chimeric polypeptide according to the first aspect of the invention, for example by treatment with an anti-CD3 monoclonal antibody.
The cell of the invention may be made by:
The cells may then by purified, for example, selected on the basis of expression of one or more heterologous nucleic acid sequences.
The effector immune cell is capable of recognising and killing a target immune cell. The target immune cell may be a cytolytic immune cell such as a T-cell or NK cell as defined above.
The present invention also relates to a pharmaceutical composition containing a plurality of cells according to the invention.
The pharmaceutical composition may additionally comprise a pharmaceutically acceptable carrier, diluent or excipient. The pharmaceutical composition may optionally comprise one or more further pharmaceutically active polypeptides and/or compounds. Such a formulation may, for example, be in a form suitable for intravenous infusion.
The present invention provides a method for treating a disease which comprises the step of administering the cells of the present invention (for example in a pharmaceutical composition as described above) to a subject.
A method for treating a disease relates to the therapeutic use of the cells of the present invention. Herein the cells may be administered to a subject having an existing disease or condition in order to lessen, reduce or improve at least one symptom associated with the disease and/or to slow down, reduce or block the progression of the disease.
The method for preventing a disease relates to the prophylactic use of the cells of the present invention. Herein such cells may be administered to a subject who has not yet contracted the disease and/or who is not showing any symptoms of the disease to prevent or impair the cause of the disease or to reduce or prevent development of at least one symptom associated with the disease. The subject may have a predisposition for, or be thought to be at risk of developing, the disease.
The method may involve the steps of:
The cell-containing sample may be isolated from a subject or from other sources, as described above.
The present invention also provides a method for treating a disease in a subject, which comprises the following steps:
The effector immune cells may express variant calcineurin engineered to be resistant to one or more calcineurin inhibitors, for example:
Step (ii) may involve administering cyclosporin and/or tacrolimus to the cells or to the patient.
The effector cells may express dnCSK and step (ii) may involve administering any immunosuppressant to the subject, for example rapamycin.
The present invention provides a cell of the present invention for use in treating and/or preventing a disease.
The invention also relates to the use of a cell of the present invention in the manufacture of a medicament for the treatment of a disease.
The disease to be treated by the methods of the present invention may be a cancerous disease, such as bladder cancer, breast cancer, colon cancer, endometrial cancer, kidney cancer (renal cell), leukaemia, lung cancer, melanoma, non-Hodgkin lymphoma, pancreatic cancer, prostate cancer and thyroid cancer.
The disease may be Multiple Myeloma (MM), B-cell Acute Lymphoblastic Leukaemia (B-ALL), Chronic Lymphocytic Leukaemia (CLL), Neuroblastoma, T-cell acute Lymphoblastic Leukaema (T-ALL) or diffuse large B-cell lymphoma (DLBCL).
The disease may be a plasma cell disorder such as plasmacytoma, plasma cell leukemia, multiple myeloma, macroglobulinemia, amyloidosis, Waldenstrom's macroglobulinemia, solitary bone plasmacytoma, extramedullary plasmacytoma, osteosclerotic myeloma, heavy chain diseases, monoclonal gammopathy of undetermined significance or smoldering multiple myeloma.
The effector immune cells of the present invention are capable of killing target immune cells, which may be cancer cells or normal immune cells which are reactive against the effector immune cell.
The present invention also provides a method for depleting alloreactive immune cells from a population of immune cells, which comprises the step of contacting the population of immune cells with a plurality of effector immune cells having an engineered MHC class I or an MHC class II complex as defined above.
The present invention also provides a method for treating or preventing graft rejection following allotransplantation, which comprises the step of administering a plurality of effector immune cells derived from the donor subject to the recipient subject for the allotransplant, the plurality of effector immune cells expressing an engineered MHC class I or an MHC class II complex as defined above.
The effector immune cells could be administered to the patient before, after or at the same time as the transplant. For example, for an organ transplant, effector T cells from the organ donor expressing an engineered MHC class I or an MHC class II complex as defined above could be infused into a recipient prior to transplant to eliminate alloreactive T-cells that could mediate graft rejection. Alternatively, in the case of HSCT, recipient T-cells expressing an engineered MHC class I or an MHC class II complex as defined above can be cultured with the stem cell graft prior to infusion to eliminate donor alloreactive T-cells that could attack host tissues.
There is also provided a method for treating or preventing graft versus host disease (GVHD) associated with allotransplantation, which comprises the step of contacting the allotransplant with administering a plurality of effector immune cells having an engineered MHC class I or an MHC class II complex as defined above.
The allotransplantation may involve adoptive transfer of allogeneic immune cells.
There is also provided an allotransplant which has been depleted of alloreactive immune cells by a method of the invention. There is also provided an allotransplant which comprises effector immune cells of the invention.
There is also provided effector immune cells of the invention for use in:
There is also provided the use of effector immune cells of the invention in the manufacture of a pharmaceutical composition for:
The invention will now be further described by way of Examples, which are meant to serve to assist one of ordinary skill in the art in carrying out the invention and are not intended in any way to limit the scope of the invention.
WO2015/132598 describes a CAR which specifically bind TCR beta constant region 1 (TRBC1) which comprises the VH and VL domains shown as SEQ ID No. 7 and 8 respectively.
A truncated version of this CAR was created which lacks the signalling domain, named dJOVI; dJOVI binds TRBC1 on target cells but is unable to trigger T cell activation and killing. PBMCs were transduced with a vector expressing dJOVI or the full length CAR (JOVI) together with the sort-suicide gene RQR8 which is described in WO2013/153391. JOVI- or dJOVI-transduced PBMCs were co-cultured with TRBC1+ target PBMCs at a 1:2 effector:target ratio and live transduced (RQR8+) T cells were enumerated after 24 h of co-culture. The results are shown in
In order to investigate the effect of engineering the CAR-T cell to transmit inhibitory immune signals on reverse killing by target T cells, PBMCs were transduced to express JOVI− or dJOVI− together with a truncated version of PD-L1 or PDL2 which lacks the cytoplasmic domain (dPDL1 and dPDL2). For this assay, TRBC1+ target PBMCs were transduced to express full length PD1.
A co-culture with JOVI- or dJOVI-transduced PBMCs expressing dPDL1 or dPDL2 together with RQR8; and TRBC1+ target PBMCs expressing the PD1, was setup at a 1:1 effector:target ratio. Live transduced (RQR8+) T cells were enumerated after 72 h of co-culture and each condition normalized to its respective JOVI (or dJOVI) co-culture. The results are shown in
A co-culture of JOVI-RQR8 transduced PBMCs expressing calcineurin mutants with TRBC1+ target PBMCs is setup at a 1:1 and 1:4 effector:target ratio. Different concentrations of calcineurin inhibitors are added to the co-culture. Live transduced (RQR8+) T cells are enumerated after 72 h of co-culture by flow cytometry and each condition normalized to the co-culture where no inhibitor is added.
A co-culture of JOVI-RQR8 transduced PBMCs expressing dnCSK with TRBC1+ target PBMCs is setup at a 1:1 and 1:4 effector:target ratio. Different concentrations of an immunosuppressant were added to the co-culture. Live transduced (RQR8+) T cells are enumerated after 72 h of co-culture by flow cytometry and each condition normalized to the co-culture where no immunosuppressant is added.
In order to investigate the effect of engineering the CAR-T cell to transmit inhibitory immune signals on reverse killing by target T cells with the addition of an antirejection kill response; PBMCs are transduced to express JOVI-, dJOVI- or an irrelevant CAR together with a truncated version of PD-L1 or PDL2 which lacks the cytoplasmic domain (dPDL1 and dPDL2) and a fusion protein consisting of B2M tethered to CD3zeta (β2m-CD3ζ). For this assay, TRBC1+ target PBMCs are transduced to express full length PD1 in the presence or absence of superantigens (SAgs) to ligate the armed MHC to the TCR. Superantigens are not processed intracellularly. Instead, they bind class II MHC molecules as intact macromolecules and bind outside of the peptide-antigen binding groove. SAgs are molecules that indiscriminately stimulate up to 20% of all T cells (normal response to antigen stimulates only 0.01% of T cells).
A co-culture with JOVI- or dJOVI- or an irrelevant CAR transduced PBMCs expressing dPDL1 or dPDL2 together with β2m-CD3ζ; and TRBC1+ target PBMCs expressing the PD1 plus a SAg, is setup at a 1:1 effector:target ratio. Live transduced T cells are enumerated after 72 h of co-culture and each condition normalized to its respective JOVI (or dJOVI) co-culture.
A co-culture of transduced PBMCs with a vector encoding a CAR (JOVI, dJOVI or an irrelevant CAR), β2m-CD3ζ and calcineurin mutants with TRBC1+ target PBMCs is setup at a 1:1 and 1:4 effector:target ratio. Different concentrations of calcineurin inhibitors and SAgs are added to the co-culture. Live transduced T cells were enumerated after 72 h of co-culture by flow cytometry and each condition normalized to the co-culture where no inhibitor or SAgs are added.
A co-culture of transduced PBMCs with a vector encoding a CAR (JOVI, dJOVI or an irrelevant CAR), β2m-CD3ζ and dnCSK with TRBC1+ target PBMCs is setup at a 1:1 and 1:4 effector:target ratio. Different concentrations of immunosuppressants and SAgs are added to the co-culture. Live transduced T cells are enumerated after 72 h of co-culture by flow cytometry and each condition normalized to the co-culture where no immunosuppressants or SAgs are added.
PBMCs were transduced with a vector expressing a CAR together with the sort-suicide gene RQR8 which is described in WO2013/153391. The CARs tested are summarised below:
CD19 CAR: A second generation CAR having an antigen binding domain derived from Fmc63, a hinge spacer and a 41BB/CD3z endodomain
TRBC1 CAR: A second generation CAR having an antigen binding domain as described in WO2018/224844, a hinge spacer and a 41BB/CD3z endodomain
TRBC2 CAR: A second generation CAR having an antigen binding domain as described in WO2020/089644, a CD8 stalk spacer and a CD28/CD3z endodomain
One population of cells were transduced with a tricistronic vector expressing RQR8, the TRBC2 CAR and the CnB30 calcineurin mutant module described above having SEQ ID No. 131.
Transduced cells were co-cultured with one of the following target cell types:
Jurkat TRBC1: wild-type Jurkat cells which express TRBC1
Jurkat KO: Jurkat cells engineered to lack TRBC1 expression
Jurkat TRBC2: Jurkat cells in which the TRBC1 gene is replaced by the TRBC2 gene using CRISPR-Cas9 technology so that the expression of TRBC2 is the same as that of TRBC1 on the wild-type cell.
Cells were co-cultures for 96 hours at a 1:4 E:T ratio in the presence or absence of 20 ng/ml of Tacrolimus. Transduced effector cells were identified based on their expression of RQR8 and their proliferation analysed using cell-trace violet (CTV) dilution. The results are shown in
Proliferation analysis was also calculated on single/live/CellTrace Violet-positive cells using the FlowJo proliferation tool using CD19 CAR as the negative control. The cell number in each division was plotted for each CAR+target combination described above and the results are shown in
In a similar study, cells transduced to express either TRBC2 CAR alone or TRBC2 CAR in combination with a calcineurin mutant (CnB30) were co-cultured for 4 days with TRBC2+ positive targets in the presence or absence of 20 ng/ml of Tacrolimus. The number CAR-expressing cells after 4 days' co-culture is shown in
PBMCs from healthy donors were magnetically sorted into TRBC1+ and TRBC2+ fractions. After 2 days of activation, the TRBC1+ fractions were transduced with retroviral vectors expressing RQR8 and either CD19 or TRBC2 CAR as described above. One population of cells were transduced with a tricistronic vector expressing RQR8, the TRBC2 CAR and the CnB30 calcineurin mutant module described above having SEQ ID No. 131.
Cells were left untreated or treated with 20 ng/ml Tacrolimus at day 3 post-transduction and expanded for further 4 days under these conditions. Seven days post-transduction, killing assays were setup at effector:target ratios of 1:1 and 1:4 and the non-transduced TRBC2+ fraction was labelled with Cell Trace Violet and used as an autologous target.
Killing was assessed by flow cytometry 72 h later and supernatant from the co-cultures collected and analysed for IFNγ and IL-2 production. Transduced effector cells were identified based on their expression of RQR8. The results are shown in
Following expansion and co-culture in the presence of tacrolimus, improved target cell killing was observed with the effector cell population which co-expressed the TRBC2 CAR with the CnB30 calcineurin mutant compared with the effector cell population expressing the TRBC2 CAR alone (
Following 72-hour co-culture with TRBC2-expressing PBMC in the absence of tacrolimus at a 1:1 ratio, some anti-TRBC2 CAR-expressing cells were detectable (
Following expansion and co-culture in the presence of tacrolimus, however, the effector cell population which co-expressed the TRBC2 CAR with the CnB30 calcineurin mutant showed some survival/proliferation even following co-culture at a 1:4 ratio. At a 1:1 co-culture ratio, the effector cell population which co-expressed the TRBC2 CAR with the CnB30 calcineurin mutant showed much greater survival/proliferation than the effector cell population expressing the TRBC2 CAR alone (
The cell population which co-expressed the TRBC2 CAR with the CnB30 calcineurin mutant also showed increased T-cell activation in terms of cytokine release following expansion and co-culture in the presence of tacrolimus than the cell population expressing the TRBC2 CAR alone. This is true for both IFNγ (
Taken together, these data indicate that expression of a calcineurin mutant by CAR-expressing cells gives the effector cells an advantage over the target T cells and prevents reverse killing by the target cells.
All publications mentioned in the above specification are herein incorporated by reference. Various modifications and variations of the described methods and system of the invention will be apparent to those skilled in the art without departing from the scope and spirit of the invention. Although the invention has been described in connection with specific preferred embodiments, it should be understood that the invention as claimed should not be unduly limited to such specific embodiments. Indeed, various modifications of the described modes for carrying out the invention which are obvious to those skilled in molecular biology or related fields are intended to be within the scope of the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2005216.3 | Apr 2020 | GB | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/GB2021/050862 | 4/8/2021 | WO |
