The present invention relates to the field of cell immunotherapy and more particularly to engineered immune cells expressing new mesothelin (MLSN) specific chimeric antigen receptors (anti-mesothelin CAR) useful in the treatment of solid tumors.
Chimeric antigen receptors (CAR) are synthetic receptors that target T cells to cell-surface antigens and augment T-cell function and persistence. Mesothelin is a cell-surface antigen implicated in tumor invasion, which is highly expressed in mesothelioma and lung, pancreas, breast, ovarian, and other cancers. Encouragingly, recent clinical trials evaluating active immunization or immunoconjugates in patients with pancreatic adenocarcinoma or mesothelioma have shown responses without toxicity. Altogether, these findings and preclinical CAR therapy models using either systemic or regional T-cell delivery argue favorably for mesothelin CAR therapy in multiple solid tumors.
Given the potential high efficiency of CAR therapy, it is critical to identify appropriate antigens to tackle solid tumors, in order to achieve tumor eradication with minimal or tolerable on-target/off-tumor toxicity to healthy tissues.
Solid tumor CAR targets under investigation are altered gene products mostly arising from genetic mutations or altered splicing (EGFRvIII), altered glycosylation patterns (MUC1), cancer-testis antigen-derived peptides (MAGE), overexpressed differentiation antigens CEA, PSMA, GD2, MUC16, HER2/ERBB2, and mesothelin (MSLN), or tumor-associated stroma (FAP and VEGFR).
Although overexpressed antigens are numerous and relatively frequent, they raise concerns about “on-target/off-tumor” side effects due to the high sensitivity of T cells for low-level antigen expression, which can be greater than that of monoclonal antibodies. For instance, the use of ERBB2 CAR T cells, administered at a high cell dose, has resulted in a fatal adverse event, attributed in part to low-level ERBB2 expression in healthy lung epithelial and cardiovascular cells [Morgan, R. A. et al. (2010) Case report of a serious adverse event following the administration of T cells transduced with a chimeric antigen receptor recognizing ERBB2. Mol Ther. 18:843-51]. Thus, an optimal solid-tumor antigen target is one whose expression either is restricted to tumor cells or occurs only at very low levels in expendable normal tissues.
MSLN has emerged as an attractive target for cancer immunotherapy, considering its low expression on normal mesothelial cells and high expression in a broad spectrum of solid tumors. The MSLN-targeted immunotherapies reported to date support a favorable safety profile. MSLN is a potential CAR target in a number of common solid tumors, such as at least oesophageal cancer, breast cancer, gastric cancer, cholangiocarcinoma, pancreatic cancer, colon cancer, Lung cancer, Thymic carcinoma, mesothelioma, ovarian cancer, and endometrial cancer [Morello, A. et al. (2016) Mesothelin-Targeted CARs: Driving T Cells to Solid Tumors. Cancer Discov. 6(2); 133-46].
MSLN is a glycoprotein anchored to the plasma membrane by a glycophosphatidyl inositol (GPI) domain. It is initially synthesized as a 69 kDa cell-surface protein. After cleavage of the amino terminus by the furin protease, a 40-kDa C-terminal fragment remains attached to the membrane and a soluble 32-kDa N-terminal fragment, named megakaryotic-potentiating factor (MPF), is released [Pastan, I., Hassan, R. (2014) Discovery of mesothelin and exploiting it as a target for immunotherapy. Cancer. Res. 74:2907-12]. A soluble form of MSLN has also been detected in the sera of patients with solid tumors, which is referred to as soluble MSLN-related protein (SMRP). SMRP is generated either by alternative splicing or by proteolytic cleavage of the MSLN mature form, induced by the TNFα-converting enzyme ADAM17.
The biologic function of MSLN seems to be nonessential in normal tissues, given that MSLN knockout mice exhibit normal development, reproduction, and blood cell count. In contrast, preclinical and clinical studies increasingly show that aberrant MSLN expression plays an active role in both malignant transformation of tumors and tumor aggressiveness by promoting cancer cell proliferation, contributing to local invasion and metastasis, and conferring resistance to apoptosis induced by cytotoxic agents. MSLN can act bidirectionally, either by directly activating intracellular pathways via its GPI domain or by interacting with its receptor, CA125/MUC16. Overexpression of MSLN alone is sufficient to constitutively activate the NFκB, MAPK, and PI3K intracellular pathways promoting cell proliferation and resistance to apoptosis.
Physiologically, MSLN is expressed on mesothelial cells of the peritoneal and pleural cavities and pericardium; it is expressed minimally on the epithelial cell surface of the trachea, ovaries, rete testis, tonsils, and fallopian tubes. Overexpression of MSLN was initially observed in mesothelioma and ovarian cancer, and subsequently in lung, esophageal, pancreatic, gastric, biliary, endometrial, thymic, colon, and breast cancers. MSLN overexpression thus has an estimated incidence of 340,000 patients and prevalence of 2 million patients a year in the United States alone.
CARs consist of an ectodomain commonly derived from a single-chain variable fragment (scFv), a hinge, a transmembrane domain, and an endodomain (typically comprising signaling domains derived from CD3ζ and costimulatory receptors). Second-generation CARs further enhance T-cell function and persistence through the incorporation of signalling domains that rescue and amplify the activation signal provided by the CD3ζ cytoplasmic domain. Dual signalling prevents T-cell anergy and increases persistence and function by augmenting T-cell proliferation and cytokine production (IFNγ and IL2) and reducing activation-induced cell death through the recruitment of the PI3K, TRAF, and/or other pathways. Third-generation CARs comprise three signalling domains, typically encompassing those of CD3ζ and two co-stimulatory domains, for example CD28 and 4-1BB or CD28 and OX40. Compared with second-generation CARs, third-generation CARs have shown inconsistent antitumor activity in vivo. Choosing an appropriate co-stimulation domain is essential to sustain CAR T-cell activity and calibrate T-cell persistence. However, the ideal co-stimulation domain may depend on context, as CAR function depends on multiple extraneous factors, such as antigen density, CAR stoichiometry, CAR affinity and the immunologic features of the tumor microenvironment.
The spatial distance between CARs and their target antigens may be equally important for effective initiation of T cell signalling, but depends on an entirely different set of structural elements related to the location of the epitope on the target molecule and the spacer domain between the scFv and the T cell membrane. Several studies have demonstrated that the same epitope can activate CAR-T cells with greater efficiency when expressed in a more membrane-proximal position than a membrane-distal position. For example, Hombach et al. demonstrated that CAR T cells recognizing the membrane-distal “N” epitope of the carcinoembryonic antigen (CEA) were only modestly activated; however, when they engineered recombinant CEA protein to express the N epitope in a membrane-proximal position, the same CAR T cells were activated more efficiently [Hombach A A, et al. (2007) T cell activation by antibody-like immunoreceptors: the position of the binding epitope within the target molecule determines the efficiency of activation of redirected T cells. J Immunol. 178:4650-4657]. This suggests that targeting some membrane distal epitopes on tumor cells may permit large phosphatases like CD45 and CD148 to enter the synapse and inhibit phosphorylation events initiated by CAR engagement. Tailoring the extracellular spacer sequence between the T cell membrane and the ligand-binding scFv to promote synapse formation can assist in overcoming steric constraints imposed by the location of the target epitope.
A particular concern regarding MSLN CARs is interference from soluble MSLN, which in principle could occupy and block the scFv portion. However, MSLN CAR T-cell activation (cytokine secretion and cytotoxic activity) seems to remain dependent on MSLN expression on the cell surface [Carpenito C., et al. (2009) Control of large, established tumor xenografts with genetically retargeted human T cells containing CD28 and CD137 domains. PNAS. 106:3360-5].
The principle that T cells that are genetically modified to express novel synthetic CARs can effectively treat advanced refractory cancers has been established but many questions remain to realize the full potential of this new therapeutic modality. Engineering safer, more effective CARs for solid tumor cancer therapy requires moving beyond the traditional empiric approach to receptor design and cell engineering, ideally guided by our knowledge of TCR signaling, T cell biology, and manipulation of the tumor microenvironment. It is now apparent that binding affinity, Kon/Koff rates, and spatial constraints between CARs and target cells can influence the ability of CARs to optimally activate T cells for tumor recognition, particularly against solid tumors [D'Aloia, M. M., Zizzari, I. G., Sacchetti, B. et al. (2018) CAR-T cells: the long and winding road to solid tumors. Cell Death Dis 9:282].
In view of the above, screening scFv only for their affinity to MSLN antigens or their ability in-vitro to induce T cell activation and proliferation does not appear sufficient to engineer most appropriate CAR T-cells. Current data suggests that optimal CAR affinity cannot be determined a priori for individual target molecules as at this date there is no unbiased approach to identify the ideal affinity range permitting to obtain the best results in vivo [Srivastava, S. and Ridell, R. S. (2015) Engineering CAR-T Cells: Design Concepts. Trends Immunol. 36(8): 494-502].
In addition, solid-tumor microenvironment poses several obstacles for MSLN CAR-T cells that may limit their antitumor efficacy. To optimize the efficiency of CAR T cells, numerous approaches are under evaluation to tame the host tumor microenvironment or generate “armored” CAR T cells that can overcome immune barriers. Such strategies include (i) promoting CAR T-cell infiltration, (ii) augmenting the functional persistence of CAR T cells, (iii) enhancing CAR T cells to overcome inhibitory signals encountered in the tumor microenvironment, and (iv) improving safety by preventing on-target/off-tumor toxicity. Among these approaches, combining specific CAR structures with gene edited cells appear to be most promising. Riese et al. [Riese M. J., et al. Enhanced effector responses in activated CD8+ T cells deficient in diacylglycerol kinases. Cancer Res. 73:3566-77] demonstrated for instance that genetic deletion of DGKζ significantly increased the antitumor activity of MSLN CAR T cells, as shown by the enhancement of effector cytokine secretion, FASL, and TRAIL expression, and the cytotoxic functions in vitro.
On another hand, different strategies to address the risk of on-target/off-tumor toxicity and improve the safety of CAR T-cells have been developed.
One such approach has been to transfect mRNA that encodes MSLN CAR, resulting in transient CAR expression for only a few days. In preclinical models, this approach has shown promise; multiple infusions of mRNA CAR T cells have produced a robust antitumor effect in vivo [Zhao Y, et al. (2010) Multiple injections of electroporated autologous T cells expressing a chimeric antigen receptor mediate regression of human disseminated tumor. Cancer Res. 2070:9053-61]. However, transient expression of the CAR may limit the long-term efficacy of the therapy. A clinical trial conducted at the University of Pennsylvania using autologous T cells electroporated with the mRNA encoding for a second-generation MSLN CAR (SS1-4-1BB CAR) has resulted into moderate clinical responses and transient elevation of inflammatory cytokines in the sera, including IL12, IL6, G-CSF, MIP1β, MCP1, IL1RA, and RANTES.
Another approach to increase T-cell safety has been to utilize a suicide gene to eliminate T cells in the event of an emerging adverse event. In such a situation, CAR T cells can be eliminated by drug-induced activation of a suicide gene, such as the herpes simplex thymidine kinase (HSV-TK), gene inducible caspase-9, or EGFRΔ gene.
In a previous patent application WO2016120216, the applicant has developed an alternative system to suicide genes, which consists of inserting an exogenous epitope into the CAR structure to be recognized by a clinically approved antibody, such as Rituximab, which allows to partially or completely deplete CAR positive immune cells infused to patients on demand. One benefit of this approach is that no suicide gene has to be co-expressed into the cell in addition to the CAR. However, the insertion of such epitope can have an influence on the CAR overall structure and can modify the way the scFv interacts with its cognate antigen.
The present invention aims to address all or part of the above limitations by providing safer engineered immune CAR positive cells to target MSLN expressing cells in-vivo, such as solid tumors, with the perspective of being used in allogeneic treatment strategies.
The present invention primarily concerns mesothelin specific chimeric antigen receptors (CAR) for their expression into immune cells, preferably T-cells, for their therapeutic use against malignant mesothelin expressing cells or tissues.
Such CARs present a structure comprising typically:
The extracellular ligand binding domain of the CARs according to the present invention preferably comprises one or several scFv segment from the antibody referred to as meso1, and more particularly the CDRs therefrom including SEQ ID NO:3, 4, 5, 6, 7 and/or 8.
According to a preferred aspect, said extracellular ligand binding domain of said CARs comprise:
The anti-mesothelin CARs of the invention form exogenous polypeptide sequences, which are expressed by the immune cells for their exposition at the surface of the cells. These are encoded by polynucleotide sequences exogenous (with respect to the immune cell's original genome), preferably inserted at specific genomic loci, such as at the TCR, B2m or PD1 gene loci by using rare-cutting endonucleases.
According to some embodiments, said CARs further comprise additional exogenous polypeptide sequence including epitopes, which can be targeted by clinically approved antibodies for in-vivo depletion or by other ligands for their in-vivo or in-vitro detection or purification. Such additional exogenous polypeptide segment may be specifically recognized by Rituximab, such as that referred to as “R2” in the present specification.
The invention is more particularly drawn to immune cells or populations of immune cells transformed with the anti-mesothelin CARs polynucleotide sequences comprising said polynucleotide sequences and/or expressing polypeptide anti-mesothelin CARs sequences.
Such engineered immune cells, or populations of cells, according to the invention may be further genetically engineered, mutated or gene-edited to improve their therapeutic suitability or potency, such as to improve their persistence or lifespan. According to preferred aspects, the engineered immune cells according to the invention combine the expression of anti-mesothelin CARs sequences with other genetic modifications reducing the expression of their endogenous genes, such as TCR, HLA, and/or B2m genes. TGFbeta receptor
According to further preferred aspects, the engineered immune cells can be mutated to improve their CAR-dependent immune activation, in particular by reducing or suppressing the expression of immune checkpoint proteins and/or receptors thereof, such as PD1/PDL1.
According to further preferred aspects, the engineered immune cells can be mutated to improve their CAR-dependent immune activation, in particular by reducing or suppressing TGFbeta signalling pathway.
According to other preferred aspects, further exogenous genetic sequences can also be inserted, co-transfected or co-expressed with the anti-mesothelin CARs of the present invention, in particular inhibitors or decoy of TGFbeta receptor, such as a dominant negative TGFbeta receptor (dnTGFβRII).
Further examples of exogenous genetic sequences are provided, which expression can be combined with that of the anti-mesothelin CARs to improve therapeutic potency of immune cells, in particular the following ones:
The engineered immune cells according to the present invention are particularly suited for treating a condition characterized by mesothelin expressing cells, in particular solid tumors, such as typically: oesophageal cancer, breast cancer, gastric cancer, cholangiocarcinoma, pancreatic cancer, colon cancer, lung cancer, thymic carcinoma, mesothelioma, ovarian cancer and/or endometrial cancer.
The invention thus encompasses methods for producing engineered cells, the resulting therapeutic cells, populations of cells comprising such cells and therapeutic compositions comprising same, as well as the methods of treatment allowing to address pathologies induced by mesothelin expressing cells.
Table 1: Amino acid sequence of the different domains constituting the P4, Meso1 and MESO2 scFvs of the CAR illustrated in the examples.
Table 2: Amino acid sequence of the different domains, others than the scFv, constituting the MSLN CARs according to the invention.
Table 3: Examples of mAb-specific epitopes (and their corresponding mAbs) which can be used in the extracellular binding domain of the CAR of the invention for engineered cells sorting and depletion.
Table 4: Amino acid sequences of P4-R2, Meso1-R2, Meso1 and MESO2-R2 CARs.
Table 5: Examples of mAb-specific epitopes (and their corresponding mAbs), which can be inserted in the extracellular binding domain of the CAR of the invention.
Table 6: TALE-nuclease target sequences for TGFβRII gene.
Table 7: CRISPR target sequences for TGFβRII gene
Table 8: Genomic sequences targeted by the TALE-nucleases (TALEN) to inactivate TCR and CD52.
Table 9: Characteristics of the population of engineered T-cells used in the examples.
Table 10: Description of the six types of genetically modified T cells generated for the study provided in example 5.
Unless specifically defined herein, all technical and scientific terms used herein have the same meaning as commonly understood by a skilled artisan in the fields of gene therapy, biochemistry, genetics, and molecular biology.
All methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, with suitable methods and materials being described herein. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety. In case of conflict, the present specification, including definitions, will prevail. Further, the materials, methods, and examples are illustrative only and are not intended to be limiting, unless otherwise specified.
The practice of the present invention will employ, unless otherwise indicated, conventional techniques of cell biology, cell culture, molecular biology, transgenic biology, microbiology, recombinant DNA, and immunology, which are within the skill of the art. Such techniques are explained fully in the literature. See, for example, Current Protocols in Molecular Biology (Frederick M. AUSUBEL, 2000, Wiley and son Inc, Library of Congress, USA); Molecular Cloning: A Laboratory Manual, Third Edition, (Sambrook et al, 2001, Cold Spring Harbor, New York: Cold Spring Harbor Laboratory Press); Oligonucleotide Synthesis (M. J. Gait ed., 1984); Mullis et al. U.S. Pat. No. 4,683,195; Nucleic Acid Hybridization (B. D. Harries & S. J. Higgins eds. 1984); Transcription And Translation (B. D. Hames & S. J. Higgins eds. 1984); Culture Of Animal Cells (R. I. Freshney, Alan R. Liss, Inc., 1987); Immobilized Cells And Enzymes (IRL Press, 1986); B. Perbal, A Practical Guide To Molecular Cloning (1984); the series, Methods In ENZYMOLOGY (J. Abelson and M. Simon, eds.-in-chief, Academic Press, Inc., New York), specifically, Vols. 154 and 155 (Wu et al. eds.) and Vol. 185, “Gene Expression Technology” (D. Goeddel, ed.); Gene Transfer Vectors For Mammalian Cells (J. H. Miller and M. P. Calos eds., 1987, Cold Spring Harbor Laboratory); Immunochemical Methods In Cell And Molecular Biology (Mayer and Walker, eds., Academic Press, London, 1987); Handbook Of Experimental Immunology, Volumes I-IV (D. M. Weir and C. C. Blackwell, eds., 1986); and Manipulating the Mouse Embryo, (Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y., 1986).
The present invention is drawn to a general method of treating solid tumors by adoptive immune cells directed against the transmembrane protein MSLN, in particular the mesothelin's specific epitope region spanning the polypeptide sequence SEQ ID NO:25 in this protein, and more particularly by using allogeneic CAR-T cells directed against this epitope, which have proven particular efficiency.
Herein is described a method for producing engineered immune cells directed against human mesothelin (MSLN_human referred to as Q13421 in the Uniprot database), and more particularly specific mesothelin's polypeptide region represented by SEQ ID NO:25, which is presented at the surface of malignant cells. As shown in the experimental section of the present specification, efficient CAR T-cells have been produced by directing CARs against this antigen region comprising or consisting of SEQ ID NO:25, in particular by using the scFvs of antibody Meso1 comprising SEQ ID NO:9 and SEQ ID NO:10.
The resulting engineered immune cells according to the invention, in general NK or T-cells armed with a CAR comprising SEQ ID NO:9 and/or SEQ ID NO:10 have shown higher activation, potency, killing activity, cytokine release, and in-vivo persistence than their counterparts endowed with other prior anti-mesothelin CARs.
The present invention thus is drawn to CAR immune cells targeting specific epitope(s) comprised in the sequence SEQ ID NO.25 of MSLN protein, which is present at the surface of malignant cells, especially engineered for treating solid tumors.
By “Chimeric Antigen Receptor (CAR)” is meant recombinant receptors comprising a targeting moiety that is associated with one or more signaling domains in a single fusion molecule. In general, the binding moiety of a CAR consists of an antigen-binding domain of a single-chain antibody (scFv), comprising the light and heavy variable fragments of a monoclonal antibody joined by a flexible linker. Binding moieties based on receptor or ligand domains have also been used successfully. The signaling domains of CARs are generally derived from the cytoplasmic region of the CD3zeta or the Fc receptor gamma chains, which are generally combined with signaling domains from co-stimulatory molecules including CD28, OX-40 (CD134), ICOS and 4-1BB (CD137) to enhance survival and increase proliferation of the cells. CARs are generally expressed in effector immune cells to redirect their immune activity against antigens expressed at the surface of tumor cells from various malignancies including lymphomas and solid tumors. A component of a CAR is any functional subunit of a CAR that is encoded by an exogenous polynucleotide sequence introduced into the cell. For instance, this component can help to interact with the target antigen, the stability or the localization of the CAR into the cell.
In general, such CAR comprises:
The present invention is drawn more particularly to CARs, which are expressed in immune cells, such as NK or T-cells, said CAR comprising an antigen binding domain specifically binding SEQ ID NO:25.
According to a preferred aspect, the mesothelin specific chimeric antigen receptor (CAR) of the present invention has an extra cellular ligand binding-domain comprising at least one CDR region from the variable heavy VH chain of the antibody Meso1, selected from CDRH1-Meso1 (having identity with SEQ ID NO:3), CDRH2-Meso1 (having identity with SEQ ID NO:4) and CDRH3-Meso1 (having identity with SEQ ID NO:5, and/or from the variable heavy VL chain of said antibody selected from CDRL1-Meso1 (having identity with SEQ ID NO:6), CDRL2-Meso1 (having identity with SEQ ID NO:7), and CDRL3-Meso1 (having identity with SEQ ID NO:8).
In general, said extra cellular ligand binding-domain comprises:
According to preferred embodiments of the invention, the mesothelin specific chimeric antigen receptor has an extra cellular ligand binding-domain, which comprises VH and VL chains having at least 80%, preferably at least 90%, more preferably at least 95%, and even more preferably at least 99% sequence identity respectively with SEQ ID NO:9 (Meso1-VH) and SEQ ID NO:10 (Meso1-VL). In general, framework residues in the framework regions can be substituted with the corresponding residue from the CDR donor antibody to alter, for example improve, antigen binding. These framework substitutions are identified by methods well-known in the art, e.g., by modeling of the interactions of the CDR and framework residues to identify framework residues important for antigen binding and sequence comparison to identify unusual framework residues at particular positions [See, e.g., Queen et al., U.S. Pat. No. 5,585,089; and Riechmann et al., (1988) Nature, 332:323, which are incorporated herein by reference in their entireties].
Various embodiments of the invention are provided through the features provided in the claims in view of the common practice and knowledge of one skilled in the art. Detailed sequences comprised into the CAR according to the present invention are detailed in Tables 1, 2, 3 and 4, where each lines or columns should be regarded as independent embodiments of the present invention.
The signal transducing domain or intracellular signaling domain of a CAR according to the present invention is responsible for intracellular signaling following the binding of extracellular ligand binding domain to the target resulting in the activation of the immune cell and immune response. In other words, the signal transducing domain is responsible for the activation of at least one of the normal effector functions of the immune cell in which the CAR is expressed. For example, the effector function of a T cell can be a cytolytic activity or helper activity including the secretion of cytokines. Thus, the term “signal transducing domain” refers to the portion of a protein which transduces the effector signal function signal and directs the cell to perform a specialized function.
Preferred examples of signal transducing domain for use in a CAR can be the cytoplasmic sequences of the T cell receptor and co-receptors that act in concert to initiate signal transduction following antigen receptor engagement, as well as any derivate or variant of these sequences and any synthetic sequence that has the same functional capability. Signal transduction domain comprises two distinct classes of cytoplasmic signaling sequence, those that initiate antigen-dependent primary activation, and those that act in an antigen-independent manner to provide a secondary or co-stimulatory signal. Primary cytoplasmic signaling sequence can comprise signaling motifs which are known as immunoreceptor tyrosine-based activation motifs of ITAMs. ITAMs are well defined signaling motifs found in the intracytoplasmic tail of a variety of receptors that serve as binding sites for syk/zap70 class tyrosine kinases. Examples of ITAM used in the invention can include as non-limiting examples those derived from TCRzeta, FcRgamma, FcRbeta, FcRepsilon, CD3gamma, CD3delta, CD3epsilon, CD5, CD22, CD79a, CD79b and CD66d. In a preferred embodiment, the signaling transducing domain of the CAR can comprise the CD3zeta signaling domain which has amino acid sequence with at least 70%, preferably at least 80%, more preferably at least 90%, 95% 97% or 99% sequence identity with amino acid sequence selected from the group consisting of (SEQ ID NO: 9).
In particular embodiment the signal transduction domain of the CAR of the present invention comprises a co-stimulatory signal molecule. A co-stimulatory molecule is a cell surface molecule other than an antigen receptor or their ligands that is required for an efficient immune response. “Co-stimulatory ligand” refers to a molecule on an antigen presenting cell that specifically binds a cognate co-stimulatory molecule on a T-cell, thereby providing a signal which, in addition to the primary signal provided by, for instance, binding of a TCR/CD3 complex with an MHC molecule loaded with peptide, mediates a T cell response, including, but not limited to, proliferation activation, differentiation and the like. A co-stimulatory ligand can include but is not limited to CD7, B7-1 (CD80), B7-2 (CD86), PD-L1, PD-L2, 4-1BBL, OX40L, inducible costimulatory ligand (ICOS-L), intercellular adhesion molecule (ICAM, CD30L, CD40, CD70, CD83, HLA-G, MICA, M1CB, HVEM, lymphotoxin beta receptor, 3/TR6, ILT3, ILT4, an agonist or antibody that binds Toll ligand receptor and a ligand that specifically binds with B7-H3. A co-stimulatory ligand also encompasses, inter alia, an antibody that specifically binds with a co-stimulatory molecule present on a T cell, such as but not limited to, CD27, CD28, 4-1BB, OX40, CD30, CD40, PD-1, ICOS, lymphocyte function-associated antigen-1 (LFA-1), CD2, CD7, LTGHT, NKG2C, B7-H3, a ligand that specifically binds with CD83.
In a preferred embodiment, the signal transduction domain of the CAR of the present invention comprises a part of co-stimulatory signal molecule selected from the group consisting of fragment of 4-1BB (GenBank: AAA53133.) and CD28 (NP_006130.1). In particular the signal transduction domain of the CAR of the present invention comprises amino acid sequence which comprises at least 70%, preferably at least 80%, more preferably at least 90%, 95% 97% or 99% sequence identity with either 4-1BB or CD28. Accordingly, the mesothelin specific chimeric antigen receptor as per the present invention preferably comprises a CD3 zeta signalling domain that has at least 80% identity with SEQ ID NO. 19 and generally comprises a co-stimulatory domain that has at least 80% identity with SEQ ID NO.18. (4-1BB).
A CAR according to the present invention is generally expressed on the surface membrane of the cell. Thus, such CAR further comprises a transmembrane domain. The distinguishing features of appropriate transmembrane domains comprise the ability to be expressed at the surface of a cell, preferably in the present invention an immune cell, in particular lymphocyte cells or Natural killer (NK) cells, and to interact together for directing cellular response of immune cell against a predefined target cell. The transmembrane domain can be derived either from a natural or from a synthetic source. The transmembrane domain can be derived from any membrane-bound or transmembrane protein. As non-limiting examples, the transmembrane polypeptide can be a subunit of the T-cell receptor such as α, β, γ or ζ, polypeptide constituting CD3 complex, IL2 receptor p55 (α chain), p75 (β chain) or γ chain, subunit chain of Fc receptors, in particular Fcγ receptor III or CD proteins. Alternatively the transmembrane domain can be synthetic and can comprise predominantly hydrophobic residues such as leucine and valine. In a preferred embodiment said transmembrane domain is derived from the human CD8 alpha chain (e.g. NP_001139345.1) The transmembrane domain can further comprise a hinge region between said extracellular ligand-binding domain and said transmembrane domain. The term “hinge region” used herein generally means any oligo- or polypeptide that functions to link the transmembrane domain to the extracellular ligand-binding domain. In particular, hinge region are used to provide more flexibility and accessibility for the extracellular ligand-binding domain. A hinge region may comprise up to 300 amino acids, preferably 10 to 100 amino acids and most preferably 25 to 50 amino acids. Hinge region may be derived from all or part of naturally occurring molecules, such as from all or part of the extracellular region of CD8, CD4 or CD28, or from all or part of an antibody constant region. Alternatively the hinge region may be a synthetic sequence that corresponds to a naturally occurring hinge sequence, or may be an entirely synthetic hinge sequence. In a preferred embodiment said hinge domain comprises a part of human CD8 alpha chain, FcγRIIIα receptor or IgG1 respectively, or hinge polypeptides which display preferably at least 80%, more preferably at least 90%, 95% 97% or 99% sequence identity with these polypeptides.
Accordingly mesothelin specific chimeric antigen receptor (CAR) according to the present invention comprises a hinge between the extracellular ligand-binding domain and the transmembrane domain, said hinge being generally selected from CD8α hinge, IgG1 hinge and FcγRIIIα hinge or polypeptides sharing at least 80%, preferably at least 90%, more preferably at least 95%, and even more preferably at least 99% sequence identity with these polypeptides, in particular with SEQ ID NO:16 (CD8a).
A CAR according to the invention generally further comprises a transmembrane domain (TM) preferably selected from CD8α and 4-1B, more preferably from CD8α-TM or a polypeptide showing at least 80%, more preferably at least 90%, 95% 97% or 99% sequence identity with SEQ ID NO.17 (CD8α TM).
According to a further embodiment, the mesothelin specific CAR according to the invention comprises a safety switch useful for sorting, purifying and/or depleting the engineered immune cells. Although the methods of the invention are designed to be performed ex-vivo, depletion may be performed in-vivo to control immune cell's expansion into the patient and to potentially stop the effects of the treatment by using antibodies approved for human therapeutic use by regulatory agencies. Examples of mAb-specific epitopes (and their corresponding mAbs) that can be integrated in the extracellular binding domain of the CAR of the invention are listed in Table 5.
Accordingly, a mesothelin specific CAR according to the invention preferably comprises a safety switch which comprises at least one exogenous mAb epitope listed in Table 5. Preferably, a mesothelin specific CAR according to the invention preferably comprises a safety switch which comprises the epitope CPYSNPSLC (SEQ ID NO:26) that is specifically bound by rituximab. More preferably, a mesothelin specific CAR comprises a safety switch referred to as “R2”, that has at least 90% identity with SEQ ID NO:15.
A mesothelin specific CAR according to the invention generally also comprises a signal peptide to help its expression at the surface of the engineered cells. The chimeric antigen receptor (CAR) generally form single-chain polypeptides, but may also be produced in multi-chain formats as described for instance in WO2014039523.
As illustrated in the examples, preferred CARs according to the invention is MSLN-CAR-Meso1-R2 or MSLN-CAR-Meso1, which has respectively at least 80%, preferably at least 90%, more preferably at least 95%, and even more preferably at least 99% overall amino acid sequence identity with SEQ ID NO:21 (Meso1-R2) or SEQ ID NO:22 (Meso1).
The structure of the preferred polypeptide structure of the MSLN-CARs of the present invention are illustrated in
More generally, the CARs of the present invention are produced by assembling the different polynucleotides sequences encoding the successive fragments of the CAR polypeptide(s) into vectors for transfection and expression into immune cells as described in the art and as reviewed for instance by [Boyiadzis, M. M., et al. (2018) Chimeric antigen receptor (CAR) T therapies for the treatment of hematologic malignancies: clinical perspective and significance. j. immunotherapy cancer 6, 137].
The present invention is drawn to the polynucleotides and vectors as well as any intermediary steps intervening in the process of manufacturing the immune cells referred herein.
In particular, the present invention provides inter alia an expression vector in the form of a lentiviral vector or an AAV vector comprising a polynucleotide sequence encoding a CAR as described herein.
Such lentiviral vector may comprise a polynucleotide sequence encoding a CAR according to the present invention operably linked to a promoter (such as the Spleen Focus Forming Virus promoter (SFFV)). By “operably linked” it is meant a juxtaposition wherein the components described are in a relationship permitting them to function in their intended manner. A gene (such as a CAR encoding polynucleotide sequence) is “operably linked” to a promoter when its transcription is under the control of said promoter and this transcription results in the production of the product encoded by said gene.
The lentiviral vector of the present invention typically contains regulatory elements such as 5′ and 3′ long terminal repeat (LTR) sequences, but may also contain other structural and functional genetic elements that are primarily derived from a lentivirus. Such structural and functional genetic elements are well known in the art. The lentiviral vector may, for example, contain the genes gag, pol and env. Preferably, however, the lentiviral vector of the present invention does not contain the genes gag, pol and env. As further regulatory elements the lentiviral vector may include one or more (such as two or more) of a packaging signal (such as the packaging signal ψ), a primer binding site, a trans-activation-responsive region (TAR) and a rev-responsive element (RRE).
The 5′ and 3′ long terminal repeat (LTR) sequences typically flanking the lentiviral genome have promoter/enhancer activity and are essential for the correct expression of the full-length lentiviral vector transcript. The LTRs usually include the repetitive sequence U3RU5 present at both the 5′- and 3′ ends of a double-stranded DNA molecule, which is a combination of 5′ R-U5 segment and the 3′ U3-R segment of the single-stranded RNA, wherein repetition R occurs at both termini of the RNA, while U5 (unique sequence 5) only occurs at the 5′ end of the RNA and U3 (unique sequence 3) only occurs at the 3′ end of the RNA. Lentiviral vectors can been improved in their safety by removal of the U3 sequence, resulting in “self-inactivating” vectors that are entirely devoid of viral promoter and enhancer sequences originally present within the LTRs. Consequently, the vector is capable of infecting and then integrating into the host genome only once, and cannot be passed further, thereby increasing the safety of the use of the vector as a gene delivery vector.
According to some embodiments, the lentiviral vector is a self-inactivating (SIN) lentiviral vector. According to particular embodiments, the lentiviral vector contains a 3′ LTR in which the 3′ LTR enhancer-promoter sequence (i.e. U3 sequence) has been modified (e.g., deleted).
According to some embodiments, the lentiviral vector comprises a polynucleotide sequence which comprises one or several of the following elements in a 5′ to 3′ order:
According to particular embodiments, the lentiviral vector can further comprise a polynucleotide sequence which comprises at least one of the following elements in a 5′ to 3′ order:
Alternatively, the lentiviral vector can comprise at least one of the following elements in a 5′ to 3′ order:
In general, the resulting vector form a single transcription unit operably linked to the promoter of item (b) and are all transcribed under the control of said promoter.
AAV vectors, especially vectors from the AAV6 family [Wang, J., et al. (2015) Homology-driven genome editing in hematopoietic stem and progenitor cells using ZFN mRNA and AAV6 donors. Nat Biotechnol 33, 1256-1263] are particularly useful to introduce the MSLN-CARs according to the present invention into the genome by using site-specific homologous recombination. In general, site specific homologous recombination is induced in immune cells by expressing rare-cutting endonucleases, such as TALEN, as already taught in EP3276000 and WO2018073391 with respect to other CARs for treating blood cancers. CAR site-specific integration can have several benefits, such as a more stable integration, an integration that places the transgene under the transcription control of an endogenous promoter at a selected locus, an integration that can inactivate an endogenous locus. These later aspects are detailed into the following section pertaining to the genome engineering of the therapeutic immune cells.
As one object of the present invention is provided an AAV vector comprising a polynucleotide sequence encoding a MSLN-CAR as previously specified and optionally another sequence encoding a cis-regulatory elements (e.g. 2A peptide cleavage site) or an internal ribosome entry site (IRES), allowing the co-expression of a third sequence encoding a product improving the therapeutic potency of the engineered immune cells. Example is given herein of over expression of dnTGFβRII, which was found to reduce SMAD2-3 phosphorylation, which concurs to reduce exhaustion of the cells that is induced by TGFβ in the tumor environment.
The term “therapeutic properties” encompasses the different ways such cells can be improved in the perspective of their use in therapeutic treatments. This means that the cells are genetically engineered to confer them a therapeutic advantage benefit (i.e. therapeutic potency) or to facilitate their use or their production. For instance, the genetic engineering can concur to the effector cells having better survival, faster growth, shorter cell cycles, improved immune activity, be more functional, more differentiated, more specific with respect to their target cells, more sensitive or resistant to drugs, less sensitive to glucose deprivation, oxygen or amino acid depletion (i.e. resilient to tumor microenvironment). Progenitor cells may be more productive, better tolerated by the recipient patient, more likely to produce cells that will differentiate in the desired effector cells. These examples of “therapeutic properties” are given as examples without limitation.
The invention more particularly involves cells and reagents with the following characteristics:
Effector cells: Effector cells are the relatively short-lived activated cells that defend the body in an immune response. Activated T cells, which include cytotoxic T cells and helper T cells are preferred effector cells to carry out cell-mediated responses. The category of effector T cell is a broad one that includes various T cell types that actively respond to a stimulus, such as co-stimulation. This includes helper, killer, regulatory, and potentially other T cell types.
By “immune cell” is meant a cell of hematopoietic origin functionally involved in the initiation and/or execution of innate and/or adaptative immune response, such as typically CD3 or CD4 positive cells. The immune cell according to the present invention may be a dendritic cell, killer dendritic cell, a mast cell, a NK-cell, a B-cell or a T-cell selected from the group consisting of inflammatory T-lymphocytes, cytotoxic T-lymphocytes, regulatory T-lymphocytes or helper T-lymphocytes.
By “primary cell” or “primary cells” are intended cells taken directly from living tissue (e.g. biopsy material) and established for growth in vitro for a limited amount of time, meaning that they can undergo a limited number of population doublings. Primary cells are opposed to continuous tumorigenic or artificially immortalized cell lines. Non-limiting examples of such cell lines are CHO-K1 cells; HEK293 cells; Caco2 cells; U2-OS cells; NIH 3T3 cells; NSO cells; SP2 cells; CHO-S cells; DG44 cells; K-562 cells, U-937 cells; MRC5 cells; IMR90 cells; Jurkat cells; HepG2 cells; HeLa cells; HT-1080 cells; HCT-116 cells; Hu-h7 cells; Huvec cells; Molt 4 cells.
Primary immune cells can be obtained from a number of non-limiting sources, including peripheral blood mononuclear cells (PBMC), bone marrow, lymph node tissue, cord blood, thymus tissue, tissue from a site of infection, ascites, pleural effusion, spleen tissue, and from tumors, such as tumor infiltrating lymphocytes. In some embodiments, said immune cell can be derived from a healthy donor, from a patient diagnosed with cancer or from a patient diagnosed with an infection. In another embodiment, said cell is part of a mixed population of immune cells which present different phenotypic characteristics, such as comprising CD4, CD8 and CD56 positive cells. Primary immune cells are provided from donors or patients through a variety of methods known in the art, as for instance by leukapheresis techniques as reviewed by Schwartz J. et al. (Guidelines on the use of therapeutic apheresis in clinical practice-evidence-based approach from the Writing Committee of the American Society for Apheresis: the sixth special issue (2013) J Clin Apher. 28(3):145-284).
The immune cells derived from stem cells are also regarded as primary immune cells according to the present invention, in particular those deriving from induced pluripotent stem cells (iPS) [Yamanaka, K. et al. (2008). “Generation of Mouse Induced Pluripotent Stem Cells Without Viral Vectors”. Science. 322 (5903): 949-53]. Lentiviral expression of reprogramming factors has been used to induce multipotent cells from human peripheral blood cells [Staerk, J. et al. (2010). “Reprogramming of human peripheral blood cells to induced pluripotent stem cells”. Cell stem cell. 7 (1): 20-4] [Loh, Y H. et al. (2010). “Reprogramming of T cells from human peripheral blood”. Cell stem cell. 7 (1): 15-9].
According to a preferred embodiment of the invention, the immune cells are derived from human embryonic stem cells by techniques well known in the art that do not involve the destruction of human embryos [Chung et al. (2008) Human Embryonic Stem Cell lines generated without embryo destruction, Cell Stem Cell 2(2):113-117].
By “Genetic engineering” is meant any methods aiming to introduce, modify and/or withdraw genetic material from a cell. By “gene editing” is meant a genetic engineering allowing genetic material to be added, removed, or altered at specific locations (loci) in the genome, including punctual mutations. Gene editing generally involves sequence specific reagents.
By “sequence-specific reagent” is meant any active molecule that has the ability to specifically recognize a selected polynucleotide sequence at a genomic locus, referred to as “target sequence”, which is generally of at least 9 bp, more preferably of at least 10 bp and even more preferably of at least 12 pb in length, in view of modifying the expression of said genomic locus. Said expression can be modified by mutation, deletion or insertion into coding or regulatory polynucleotide sequences, by epigenetic change, such as by methylation or histone modification, or by interfering at the transcriptional level by interacting with transcription factors or polymerases.
Examples of sequence-specific reagents are endonucleases, RNA guides, RNAi, methylases, exonucleases, histone deacetylases, endonucleases, end-processing enzymes such as exonucleases, and more particularly cytidine deaminases such as those coupled with the CRISPR/cas9 system to perform base editing (i.e. nucleotide substitution) without necessarily resorting to cleavage by nucleases as described for instance by Hess, G. T. et al. [Methods and applications of CRISPR-mediated base editing in eukaryotic genomes (2017) Mol Cell. 68(1): 26-43.
According to a preferred aspect of the invention, said sequence-specific reagent is preferably a sequence-specific nuclease reagent, such as a RNA guide coupled with a guided endonuclease.
The present invention aims to improve the therapeutic potential of immune cells through gene editing techniques, especially by gene targeted integration.
By “gene targeting integration” is meant any known site-specific methods allowing to insert, replace or correct a genomic coding sequence into a living cell.
According to a preferred aspect of the present invention, said gene targeted integration involves homologous gene recombination at the locus of the targeted gene to result the insertion or replacement of at least one exogenous nucleotide, preferably a sequence of several nucleotides (i.e. polynucleotide), and more preferably a coding sequence.
“Rare-cutting endonucleases” are sequence-specific endonuclease reagents of choice, insofar as their recognition sequences generally range from 10 to 50 successive base pairs, preferably from 12 to 30 bp, and more preferably from 14 to 20 bp.
According to a preferred aspect of the invention, said endonuclease reagent is a nucleic acid encoding an “engineered” or “programmable” rare-cutting endonuclease, such as a homing endonuclease as described for instance by Arnould S., et al. [WO2004067736], a zinc finger nuclease (ZFN) as described, for instance, by Urnov F., et al. [Highly efficient endogenous human gene correction using designed zinc-finger nucleases (2005) Nature 435:646-651], a TALE-Nuclease as described, for instance, by Mussolino et al. [A novel TALE nuclease scaffold enables high genome editing activity in combination with low toxicity (2011) Nucl. Acids Res. 39(21):9283-9293], or a MegaTAL nuclease as described, for instance by Boissel et al. [MegaTALs: a rare-cleaving nuclease architecture for therapeutic genome engineering (2013) Nucleic Acids Research 42(4):2591-2601].
According to another embodiment, the endonuclease reagent is a RNA-guide to be used in conjunction with a RNA guided endonuclease, such as Cas9 or Cpf1, as per, inter alia, the teaching by Doudna, J., and Chapentier, E., [The new frontier of genome engineering with CRISPR-Cas9 (2014) Science 346 (6213):1077], which is incorporated herein by reference.
According to a preferred aspect of the invention, the endonuclease reagent is transiently expressed into the cells, meaning that said reagent is not supposed to integrate into the genome or persist over a long period of time, such as be the case of RNA, more particularly mRNA, proteins or complexes mixing proteins and nucleic acids (eg: Ribonucleoproteins).
An endonuclease under mRNA form is preferably synthetized with a cap to enhance its stability according to techniques well known in the art, as described, for instance, by Kore A. L., et al. [Locked nucleic acid (LNA)-modified dinucleotide mRNA cap analogue: synthesis, enzymatic incorporation, and utilization (2009) J Am Chem Soc. 131(18):6364-5].
In general, electroporation steps that are used to transfect primary immune cells, such as PBMCs are typically performed in closed chambers comprising parallel plate electrodes producing a pulse electric field between said parallel plate electrodes greater than 100 volts/cm and less than 5,000 volts/cm, substantially uniform throughout the treatment volume such as described in WO2004083379, which is incorporated by reference, especially from page 23, line 25 to page 29, line 11. One such electroporation chamber preferably has a geometric factor (cm−1) defined by the quotient of the electrode gap squared (cm2) divided by the chamber volume (cm3), wherein the geometric factor is less than or equal to 0.1 cm−1, wherein the suspension of the cells and the sequence-specific reagent is in a medium which is adjusted such that the medium has conductivity in a range spanning 0.01 to 1.0 milliSiemens. In general, the suspension of cells undergoes one or more pulsed electric fields. With the method, the treatment volume of the suspension is scalable, and the time of treatment of the cells in the chamber is substantially uniform.
Due to their higher specificity, TALE-nuclease have proven to be particularly appropriate sequence specific nuclease reagents for therapeutic applications, especially under heterodimeric forms—i.e. working by pairs with a “right” monomer (also referred to as “5′” or “forward”) and “left” monomer (also referred to as “3′” or “reverse”) as reported for instance by Mussolino et al. [TALEN facilitate targeted genome editing in human cells with high specificity and low cytotoxicity (2014) Nucl. Acids Res. 42(10): 6762-6773].
As previously stated, the sequence specific reagent is preferably under the form of nucleic acids, such as under DNA or RNA form encoding a rare cutting endonuclease a subunit thereof, but they can also be part of conjugates involving polynucleotide(s) and polypeptide(s) such as so-called “ribonucleoproteins”. Such conjugates can be formed with reagents as Cas9 or Cpf1 (RNA-guided endonucleases) as respectively described by Zetsche, B. et al. [Cpf1 Is a Single RNA-Guided Endonuclease of a Class 2 CRISPR-Cas System (2015) Cell 163(3): 759-771] and by Gao F. et al. [DNA-guided genome editing using the Natronobacterium gregoryi Argonaute (2016) Nature Biotech], which involve RNA or DNA guides that can be complexed with their respective nucleases.
“Exogenous sequence” refers to any nucleotide or nucleic acid sequence that was not initially present at the selected locus. This sequence may be homologous to, or a copy of, a genomic sequence, or be a foreign sequence introduced into the cell. By opposition “endogenous sequence” means a cell genomic sequence initially present at a locus. The exogenous sequence preferably codes for a polypeptide which expression confers a therapeutic advantage over sister cells that have not integrated this exogenous sequence at the locus. An endogenous sequence that is gene edited by the insertion of a nucleotide or polynucleotide as per the method of the present invention, in order to express a different polypeptide is broadly referred to as an exogenous coding sequence.
By using the above reagents and techniques, the present invention concurs to develop methods for producing therapeutic cells by proceeding with one or several of the following steps:
According to some aspects of the invention the immune cells originate from a patient or a compatible donor, in which the MSLN CAR is expressed in view of performing so called “autologous” infusion of the engineered immune cells. They can also be derived from stem cells, such as iPS cells, originating from such patient or compatible donor or from tumor infiltrating lymphocytes (TILL).
According to some aspects of the invention, the method aims to provide “off the shelf” compositions of immune cells, said immune cells being engineered for allogeneic therapeutic treatments.
By “allogeneic” is meant that the cells originate from a donor, is produced or differentiated from stem cells in view of being infused into patients having a different haplotype.
Such immune cells are generally engineered to be less alloreactive and/or become more persistent with respect to their patient host. More specifically the present methods comprise the steps of reducing or inactivating TCR expression into T-cells, or stem cells to be derived into T-cells. This can be obtained by different sequence specific-reagents, such as by gene silencing or gene editing techniques (nuclease, base editing, RNAi . . . ).
The applicant has formerly made available robust protocols and gene editing strategies to produce allogeneic therapeutic grade T-cells from PBMCs, especially by providing very safe and specific endonuclease reagents under the form of TALE-nucleases (TALEN®). The production of so-called “universal T-cells”, which are [TCR]neg T-cells from donors was achieved and successfully injected to patients with reduced Graft versus Host Disease (GVhD) [Poirot et al. (2015) Multiplex Genome-Edited T-cell Manufacturing Platform for “Off-the-Shelf” Adoptive T-cell Immunotherapies. Cancer. Res. 75 (18): 3853-3864] [Qasim, W. et al. (2017) Molecular remission of infant B-ALL after infusion of universal TALEN gene-edited CAR T cells. Science Translational 9(374)]. Meanwhile, inactivation of TCR or β2m components in primary T-cells can be combined with the inactivation of further genes encoding checkpoint inhibitor proteins, such as described for instance in WO2014184744.
In preferred embodiments, the present invention provides with a method to engineer an immune cell, wherein at least one gene encoding TCRalpha or TCRbeta is inactivated in said immune cell, preferably by expression of a rare-cutting endonuclease, whereas an exogenous polynucleotide encoding MSLN-CAR is introduced into the genome of said cell for stable expression. Preferably, said exogenous sequence is integrated at said locus encoding TCRalpha or TCRbeta, more preferably under transcriptional control of an endogenous promoter of TCRalpha or TCRbeta.
In further embodiments, the engineered immune cell can be further modified to confer resistance to at least one immune suppressive drug, such as by inactivating CD52 the target of anti-CD52 antibody (e.g.: alemtuzumab), which has been previously described with respect to the treatment of blood cancers for instance in WO2013176915.
While the use of anti-CD52 lymphodepletion agents had been limited so far to liquid tumor cancers [Quasim W. et al. (2019) Allogeneic CAR T cell therapies for leukemia Am J Hematol. 94:S50-S54.], one major aspect of the present invention is the use of genetically engineered lymphocytes made resistant to lymphodepletion regimen for the treatment of solid tumors.
Also the present invention provides engineered lymphocytes endowed with chimeric antigen receptors directed against solid tumors, especially against mesothelin positive cells, for their use in solid tumor cancer treatments in combination with, or preceded by, a lymphodepletion treatment step.
Such lymphodepletion regimen can comprise anti-CD52 reagents, such as Alemtuzumab, or purine analogues, as those used for treating blood cancers.
In preferred embodiments, the engineered lymphocytes endowed with MSLN-CAR described herein are made resistant to such lymphodepleting regimen by inhibiting or disrupting the expression of the molecules that are targeted by the lymphodepletion reagents, like for instance the antigen CD52 in the case of Alemtuzumab.
In further embodiments, the engineered immune cell can be further modified to confer resistance to and/or a chemotherapy drug, in particular a purine analogue drug, for example by inactivating DCK as described in WO201575195.
As indicated before, it is an important aspect of the present invention to treat solid tumor cancers with genetically engineered lymphocytes endowed with chimeric antigen receptors, which are made resistant to chemotherapy or lymphodepletion regimen. Such regimen can comprise antibodies targeting antigens present at the surface of immune cells, such as CD52, CD3, CD4, CD8, CD45, or other specific markers, but also less specific drugs such as purine analogues (ex: fludarabine and/or chlorofarabine) and glucocorticoids. One aspect of the invention is to make the engineered lymphocytes resistant to such regimen by inactivating or reducing the expression of the genes that encode at least one molecular target of these lymphodepletion reagents, for instance the gene DCK that metabolizes purine analogues or the genes encoding glucocorticoid receptors (GR).
The present invention is therefore more particularly focused on CAR positive cells, which expression of TCR, CD52 and/or DCK and/or GR is reduced, inactivated or deficient to make them less alloreactive and resistant to lymphodepletion regimen, for their allogeneic use in solid cancer treatments.
In further embodiments, the engineered immune cell can be further modified to improve its persistence or its lifespan into the patient, in particular inactivating a gene encoding MHC-I component(s) such as HLA or β2m, such as described in WO2015136001 or by Liu, X. et al. [CRISPR-Cas9-mediated multiplex gene editing in CAR-T cells (2017) Cell Res 27:154-157].
According to a preferred aspect of the invention, the engineered immune cell is mutated to improve its CAR-dependent immune activation, in particular to reduce or suppress the expression of immune checkpoint proteins and/or their receptors thereof, such as PD1 or CTLA4 as described in WO2014184744.
In further embodiments, the engineered immune cell can be further modified to obtain co-expression in said cell of another exogenous genetic sequence selected from one encoding:
The present application claims immune cells co-expressing in engineered immune cells at least one exogenous sequence encoding MSLN-CAR as described herein, with another exogenous sequence encoding a human polypeptide selected in the above list for the purpose of producing therapeutic compositions against solid tumors.
The present invention more particularly combines the expression of an exogenous sequence encoding MSLN-CAR as previously described, with another exogenous sequence encoding an inhibitor of a TGFbeta receptor, especially an inhibitor of TGFβRII (Uniprot—P37173).
TGFbeta receptors have been described as having preponderant roles in tumor microenvironment [Papageorgis, P. et al. (2015). Role of TGFβ in regulation of the tumor microenvironment and drug delivery (Review). International Journal of Oncology, 46, 933-943].
Although, the exact role of TGFbeta receptors in tumorogenesis remains controversial, the inventors have found that co-expressing mesothelin-specific chimeric antigen receptor (CAR) with another exogenous genetic sequence encoding an inhibitor of TGFBRII signalling and/or inactivating or reducing TGFbeta receptor signalling by using a sequence-specific reagent, was leading to an improved therapeutic potency of the engineered immune cells. In particular, the inventors have used two different approaches to impair TGFβRII signalling pathway, which may be combined together:
and/or
An anti-TGFβRII IgG1 monoclonal antibody that inhibits receptor-mediated signaling activation such as LY3022859 [Tolcher, A. W. et al. (2017) A phase 1 study of anti-TGFβ receptor type-II monoclonal antibody LY3022859 in patients with advanced solid tumors Cancer Chemother Pharmacol. 79(4):673-680] can also be used to inhibit TGFbeta receptor signalling in combination of the CAR as per the present invention.
The present application discloses herein a selection of TALE-nucleases, which are particularly specific to a selection of target sequences within the TGFβRII gene. These TALE-nucleases have displayed highest TGFβRII knock-out efficiency with very little off-target cleavage resulting into large populations of viable engineered cells, sufficient for dosing several patients. These preferred TALE-nuclease and their corresponding target sequences are listed in Table 6.
RNA guides avec also been designed to inactivate TGFβRII gene by using Cas9 nuclease reagent. Their corresponding respective target sequences are disclosed in Table 7.
The present invention thus encompasses the use of a TALE-nuclease or RNA-guided endonuclease designed to bind any of the target sequences SEQ ID NO:X to Y referred to in table 5 or 6 for the inactivation or reducing of expression of TGFβRII for the production of therapeutic immune cells within the teaching of the present specification.
The present invention also pertains to engineered immune cells comprising an exogenous polynucleotide encoding a nuclease, such as one referred to before, to inactivate or reduce the expression of its endogenous TGFβRII gene.
The present application thus reports engineered immune cells, especially CAR immune cells, into which an exogenous sequence encoding an inhibitor of TGFbeta receptor has been introduced, more particularly a sequence encoding a dominant negative TGFbeta receptor. Such cells are more particularly dedicated to the treatment of solid tumors, especially MSLN positive tumors.
Accordingly, the present application also claims vectors, especially viral vectors, such as lentiviral vectors or AAV vectors as described in the art, comprising at least a polynucleotide sequence encoding a dominant negative TGFβRII, and optionally, a mesothelin-specific chimeric antigen receptor. In preferred embodiments, said vectors comprise a first polynucleotide sequence encoding said dominant negative TGFβRII, a second polynucleotide sequence encoding 2A self-cleaving peptide and a third one encoding said mesothelin-specific chimeric antigen receptor.
Targeted insertion into immune cells can be significantly improved by using AAV vectors, especially vectors from the AAV6 family or chimeric vectors AAV2/6 previously described by Sharma A., et al. [Transduction efficiency of AAV 2/6, 2/8 and 2/9 vectors for delivering genes in human corneal fibroblasts. (2010) Brain Research Bulletin. 81 (2-3): 273-278].
One aspect of the present invention is thus the transduction of AAV vectors comprising MSLN-CAR coding sequence in human primary immune cells, in conjunction with the expression of sequence-specific endonuclease reagents, such as TALE endonucleases, to increase gene integration at the loci previously cited.
According to a preferred aspect of the invention, sequence specific endonuclease reagents can be introduced into the cells by transfection, more preferably by electroporation of mRNA encoding said sequence specific endonuclease reagents.
The obtained insertion of the exogenous nucleic acid sequence may result into the introduction of genetic material, correction or replacement of the endogenous sequence, more preferably “in frame” with respect to the endogenous gene sequences at that locus.
According to another aspect of the invention, from 105 to 107, preferably from 106 to 107, more preferably about 5·106 viral genomes viral genomes are transduced per cell.
According to another aspect of the invention, the cells can be treated with proteasome inhibitors, such as Bortezomib or HDAC inhibitors to further help homologous recombination.
As one object of the present invention, the AAV vector used in the method can comprise an exogenous coding sequence that is promoter less, said coding sequence being any of those referred to in this specification.
The present invention also provides with an efficient method for obtaining primary immune cells, which can be gene edited in various gene loci more particularly involved into host-graft interaction and recognition. Other loci may also be edited in view of improving the activity, the survival or the life-time of the engineered primary cells, especially primary T cells.
The present invention provides more particularly with combinations of genetic modifications (genotypes) into immune cells prompt to improve immune cells potency against solid tumor, especially against MSLN positive malignant cells, such as:
As mentioned before, the present invention is also particularly focused on the use of CAR positive cells in solid cancer treatments, which are made resistant to lymphodepleting agents, so that they can be combined with or preceded by lymphodepletion regimen for their use in allogeneic settings. Such cells preferably display the following genotypes:
The above preferred genotypes can be obtained by gene targeting integration, preferably at the PD1, TCR (TCRalpha and/or TCRbeta) or TGFβRII loci, but also at further selected loci as described here after.
By “gene targeting integration” is meant any known site-specific methods allowing to insert, replace or correct a genomic sequence into a living cell. Gene targeted integration usually involves the mechanisms of homologous gene recombination or NHEJ (Non homologous Ends Joining), which are enhanced by endonuclease sequence specific reagents, to result into insertion or replacement of at least one exogenous nucleotide, preferably a sequence of several nucleotides (i.e. polynucleotide), and more preferably a coding sequence at a predefined locus.
The method of the present invention can be associated with other methods involving genetic transformations, such as a viral transduction, and also may be combined with other transgene expression not necessarily involving integration.
According to one aspect, the method according to the invention comprises the steps of introducing into an immune cell a mutation or polynucleotide coding sequence at an endogenous locus selected from:
Said transgene or exogenous polynucleotide sequence is preferably inserted so that its expression is placed under transcriptional control of at least one endogenous promoter present at one of said locus.
Targeting one locus as referred to above by performing gene integration is beneficial to further improve the potency of the therapeutic immune cells of the invention.
Examples of such exogenous sequences or transgenes that can be expressed or overexpressed at the selected loci are given hereafter:
According to one aspect of the present method, the exogenous sequence that is integrated into the immune cells genomic locus encodes a molecule that confers resistance of said immune cells to a drug.
Examples of preferred exogenous sequences are variants of dihydrofolate reductase (DHFR) conferring resistance to folate analogs such as methotrexate, variants of inosine monophosphate dehydrogenase 2 (IMPDH2) conferring resistance to IMPDH inhibitors such as mycophenolic acid (MPA) or its prodrug mycophenolate mofetil (MMF), variants of calcineurin or methylguanine transferase (MGMT) conferring resistance to calcineurin inhibitor such as FK506 and/or CsA, variants of mTOR such as mTORmut conferring resistance to rapamycin) and variants of Lck, such as Lckmut conferring resistance to Imatinib and Gleevec.
The term “drug” is used herein as referring to a compound or a derivative thereof, preferably a standard chemotherapy agent that is generally used for interacting with a cancer cell, thereby reducing the proliferative or living status of the cell. Examples of chemotherapeutic agents include, but are not limited to, alkylating agents (e.g., cyclophosphamide, ifosamide), metabolic antagonists (e.g., purine nucleoside antimetabolite such as clofarabine, fludarabine or 2′-deoxyadenosine, methotrexate (MTX), 5-fluorouracil or derivatives thereof), antitumor antibiotics (e.g., mitomycin, adriamycin), plant-derived antitumor agents (e.g., vincristine, vindesine, Taxol), cisplatin, carboplatin, etoposide, and the like. Such agents may further include, but are not limited to, the anti-cancer agents TRIMETHOTRIXATE™ (TMTX), TEMOZOLOMIDE™, RALTRITREXED™, S-(4-Nitrobenzyl)-6-thioinosine (NBMPR), 6-benzyguanidine (6-BG), bis-chloronitrosourea (BCNU) and CAMPTOTHECIN™, or a therapeutic derivative of any thereof.
As used herein, an immune cell is made “resistant or tolerant” to a drug when said cell, or population of cells is modified so that it can proliferate, at least in-vitro, in a culture medium containing half maximal inhibitory concentration (IC50) of said drug (said IC50 being determined with respect to an unmodified cell(s) or population of cells).
In a particular embodiment, said drug resistance can be conferred to the immune cells by the expression of at least one “drug resistance coding sequence”. Said drug resistance coding sequence refers to a nucleic acid sequence that confers “resistance” to an agent, such as one of the chemotherapeutic agents referred to above. A drug resistance coding sequence of the invention can encode resistance to anti-metabolite, methotrexate, vinblastine, cisplatin, alkylating agents, anthracyclines, cytotoxic antibiotics, anti-immunophilins, their analogs or derivatives, and the like (Takebe, N., S. C. Zhao, et al. (2001) “Generation of dual resistance to 4-hydroperoxycyclophosphamide and methotrexate by retroviral transfer of the human aldehyde dehydrogenase class 1 gene and a mutated dihydrofolate reductase gene”. Mol. Ther. 3(1): 88-96), (Zielske, S. P., J. S. Reese, et al. (2003) “In vivo selection of MGMT(P140K) lentivirus-transduced human NOD/SCID repopulating cells without pretransplant irradiation conditioning.” J. Clin. Invest. 112(10): 1561-70) (Nivens, M. C., T. Felder, et al. (2004) “Engineered resistance to camptothecin and antifolates by retroviral coexpression of tyrosyl DNA phosphodiesterase-I and thymidylate synthase” Cancer Chemother Pharmacol 53(2): 107-15), (Bardenheuer, W., K. Lehmberg, et al. (2005). “Resistance to cytarabine and gemcitabine and in vitro selection of transduced cells after retroviral expression of cytidine deaminase in human hematopoietic progenitor cells”. Leukemia 19(12): 2281-8), (Kushman, M. E., S. L. Kabler, et al. (2007) “Expression of human glutathione S-transferase P1 confers resistance to benzo[a]pyrene or benzo[a]pyrene-7,8-dihydrodiol mutagenesis, macromolecular alkylation and formation of stable N2-Gua-BPDE adducts in stably transfected V79MZ cells co-expressing hCYP1A1” Carcinogenesis 28(1): 207-14).
The expression of such drug resistance exogenous sequences in the immune cells as per the present invention more particularly allows the use of said immune cells in cell therapy treatment schemes where cell therapy is combined with chemotherapy or into patients previously treated with these drugs.
Several drug resistance coding sequences have been identified that can potentially be used to confer drug resistance according to the invention. One example of drug resistance coding sequence can be for instance a mutant or modified form of Dihydrofolate reductase (DHFR). DHFR is an enzyme involved in regulating the amount of tetrahydrofolate in the cell and is essential to DNA synthesis. Folate analogs such as methotrexate (MTX) inhibit DHFR and are thus used as anti-neoplastic agents in clinic. Different mutant forms of DHFR which have increased resistance to inhibition by anti-folates used in therapy have been described. In a particular embodiment, the drug resistance coding sequence according to the present invention can be a nucleic acid sequence encoding a mutant form of human wild type DHFR (GenBank: AAH71996.1), which comprises at least one mutation conferring resistance to an anti-folate treatment, such as methotrexate. In particular embodiment, mutant form of DHFR comprises at least one mutated amino acid at position G15, L22, F31 or F34, preferably at positions L22 or F31 (Schweitzer et al. (1990) “Dihydrofolate reductase as a therapeutic target” Faseb J 4(8): 2441-52; International application WO94/24277; and U.S. Pat. No. 6,642,043). In a particular embodiment, said DHFR mutant form comprises two mutated amino acids at position L22 and F31. Correspondence of amino acid positions described herein is frequently expressed in terms of the positions of the amino acids of the form of wild-type DHFR polypeptide. In a particular embodiment, the serine residue at position 15 is preferably replaced with a tryptophan residue. In another particular embodiment, the leucine residue at position 22 is preferably replaced with an amino acid which will disrupt binding of the mutant DHFR to antifolates, preferably with uncharged amino acid residues such as phenylalanine or tyrosine. In another particular embodiment, the phenylalanine residue at positions 31 or 34 is preferably replaced with a small hydrophilic amino acid such as alanine, serine or glycine.
Another example of drug resistance coding sequence can also be a mutant or modified form of ionisine-5′-monophosphate dehydrogenase II (IMPDH2), a rate-limiting enzyme in the de novo synthesis of guanosine nucleotides. The mutant or modified form of IMPDH2 is a IMPDH inhibitor resistance gene. IMPDH inhibitors can be mycophenolic acid (MPA) or its prodrug mycophenolate mofetil (MMF). The mutant IMPDH2 can comprises at least one, preferably two mutations in the MAP binding site of the wild type human IMPDH2 (Genebank: NP_000875.2) leading to a significantly increased resistance to IMPDH inhibitor. Mutations in these variants are preferably at positions T333 and/or S351 (Yam, P., M. Jensen, et al. (2006) “Ex vivo selection and expansion of cells based on expression of a mutated inosine monophosphate dehydrogenase 2 after HIV vector transduction: effects on lymphocytes, monocytes, and CD34+ stem cells” Mol. Ther. 14(2): 236-44) (Jonnalagadda, M., et al. (2013) “Engineering human T cells for resistance to methotrexate and mycophenolate mofetil as an in vivo cell selection strategy.” PLoS One 8(6): e65519).
Another drug resistance coding sequence is the mutant form of calcineurin. Calcineurin (PP2B—NCBI: ACX34092.1) is an ubiquitously expressed serine/threonine protein phosphatase that is involved in many biological processes and which is central to T-cell activation. Calcineurin is a heterodimer composed of a catalytic subunit (CnA; three isoforms) and a regulatory subunit (CnB; two isoforms). After engagement of the T-cell receptor, calcineurin dephosphorylates the transcription factor NFAT, allowing it to translocate to the nucleus and active key target gene such as IL2. FK506 in complex with FKBP12, or cyclosporine A (CsA) in complex with CyPA block NFAT access to calcineurin's active site, preventing its dephosphorylation and thereby inhibiting T-cell activation (Brewin et al. (2009) “Generation of EBV-specific cytotoxic T cells that are resistant to calcineurin inhibitors for the treatment of posttransplantation lymphoproliferative disease” Blood 114(23): 4792-803). In a particular embodiment, said mutant form can comprise at least one mutated amino acid of the wild type calcineurin heterodimer a at positions: V314, Y341, M347, T351, W352, L354, K360, preferably double mutations at positions T351 and L354 or V314 and Y341. In a particular embodiment, the valine residue at position 341 can be replaced with a lysine or an arginine residue, the tyrosine residue at position 341 can be replaced with a phenylalanine residue; the methionine at position 347 can be replaced with the glutamic acid, arginine or tryptophane residue; the threonine at position 351 can be replaced with the glutamic acid residue; the tryptophane residue at position 352 can be replaced with a cysteine, glutamic acid or alanine residue, the serine at position 353 can be replaced with the histidine or asparagines residue, the leucine at position 354 can be replaced with an alanine residue; the lysine at position 360 can be replaced with an alanine or phenylalanine residue. In another particular embodiment, said mutant form can comprise at least one mutated amino acid of the wild type calcineurin heterodimer b at positions: V120, N123, L124 or K125, preferably double mutations at positions L124 and K125. In a particular embodiment, the valine at position 120 can be replaced with a serine, an aspartic acid, phenylalanine or leucine residue; the asparagines at position 123 can be replaced with a tryptophan, lysine, phenylalanine, arginine, histidine or serine; the leucine at position 124 can be replaced with a threonine residue; the lysine at position 125 can be replaced with an alanine, a glutamic acid, tryptophan, or two residues such as leucine-arginine or isoleucine-glutamic acid can be added after the lysine at position 125 in the amino acid sequence. Correspondence of amino acid positions described herein is frequently expressed in terms of the positions of the amino acids of the form of wild-type human calcineurin heterodimer b polypeptide (NCBI: ACX34095.1).
Another drug resistance coding sequence is O(6)-methylguanine methyltransferase (MGMT—UniProtKB: P16455) encoding human alkyl guanine transferase (hAGT). AGT is a DNA repair protein that confers resistance to the cytotoxic effects of alkylating agents, such as nitrosoureas and temozolomide (TMZ). 6-benzylguanine (6-BG) is an inhibitor of AGT that potentiates nitrosourea toxicity and is co-administered with TMZ to potentiate the cytotoxic effects of this agent. Several mutant forms of MGMT that encode variants of AGT are highly resistant to inactivation by 6-BG, but retain their ability to repair DNA damage (Maze, R. et al. (1999) “Retroviral-mediated expression of the P140A, but not P140A/G156A, mutant form of O6-methylguanine DNA methyltransferase protects hematopoietic cells against O6-benzylguanine sensitization to chloroethylnitrosourea treatment” J. Pharmacol. Exp. Ther. 290(3): 1467-74). In a particular embodiment, AGT mutant form can comprise a mutated amino acid of the wild type AGT position P140. In a preferred embodiment, said proline at position 140 is replaced with a lysine residue.
Another drug resistance coding sequence can be multidrug resistance protein (MDR1) gene. This gene encodes a membrane glycoprotein, known as P-glycoprotein (P-GP) involved in the transport of metabolic byproducts across the cell membrane. The P-Gp protein displays broad specificity towards several structurally unrelated chemotherapy agents. Thus, drug resistance can be conferred to cells by the expression of nucleic acid sequence that encodes MDR-1 (Genebank NP_000918).
Another drug resistance coding sequence can contribute to the production of cytotoxic antibiotics, such as those from ble or mcrA genes. Ectopic expression of ble gene or mcrA in an immune cell gives a selective advantage when exposed to the respective chemotherapeutic agents bleomycine and mitomycin C (Belcourt, M. F. (1999) “Mitomycin resistance in mammalian cells expressing the bacterial mitomycin C resistance protein MCRA”. PNAS. 96(18):10489-94).
Another drug resistance coding sequence can come from genes encoded mutated version of drug targets, such as mutated variants of mTOR (mTOR mut) conferring resistance to rapamycin such as described by Lorenz M. C. et al. (1995) “TOR Mutations Confer Rapamycin Resistance by Preventing Interaction with FKBP12-Rapamycin” The Journal of Biological Chemistry 270, 27531-27537, or certain mutated variants of Lck (Lckmut) conferring resistance to Gleevec as described by Lee K. C. et al. (2010) “Lck is a key target of imatinib and dasatinib in T-cell activation”, Leukemia, 24: 896-900.
As described above, the genetic modification step of the method can comprise a step of introduction into cells of an exogeneous nucleic acid comprising at least a sequence encoding the drug resistance coding sequence and a portion of an endogenous gene such that homologous recombination occurs between the endogenous gene and the exogeneous nucleic acid. In a particular embodiment, said endogenous gene can be the wild type “drug resistance” gene, such that after homologous recombination, the wild type gene is replaced by the mutant form of the gene which confers resistance to the drug.
According to one aspect of the present method, the exogenous sequence that is integrated into the immune cells genomic locus encodes a molecule that enhances persistence of the immune cells, especially in-vivo persistence in a tumor environment.
By “enhancing persistence” is meant extending the survival of the immune cells in terms of life span, especially once the engineered immune cells are injected into the patient. For instance, persistence is enhanced, if the mean survival of the modified cells is significantly longer than that of non-modified cells, by at least 10%, preferably 20%, more preferably 30%, even more preferably 50%.
This especially relevant when the immune cells are allogeneic. This may be done by creating a local immune protection by introducing coding sequences that ectopically express and/or secrete immunosuppressive polypeptides at, or through, the cell membrane. A various panel of such polypeptides in particular antagonists of immune checkpoints, immunosuppressive peptides derived from viral envelope or NKG2D ligand can enhance persistence and/or an engraftment of allogeneic immune cells into patients.
According to one embodiment, the immunosuppressive polypeptide to be encoded by said exogenous coding sequence is a ligand of Cytotoxic T-Lymphocyte Antigen 4 (CTLA-4 also known as CD152, GenBank accession number AF414120.1). Said ligand polypeptide is preferably an anti-CTLA-4 immunoglobulin, such as CTLA-4a Ig and CTLA-4b Ig or a functional variant thereof.
According to one embodiment, the immunosuppressive polypeptide to be encoded by said exogenous coding sequence is an antagonist of PD1, such as PD-L1 (other names: CD274, Programmed cell death 1 ligand; ref. UniProt for the human polypeptide sequence Q9NZQ7), which encodes a type I transmembrane protein of 290 amino acids consisting of a Ig V-like domain, a Ig C-like domain, a hydrophobic transmembrane domain and a cytoplasmic tail of 30 amino acids. Such membrane-bound form of PD-L1 ligand is meant in the present invention under a native form (wild-type) or under a truncated form such as, for instance, by removing the intracellular domain, or with one or more mutation(s) (Wang S et al., 2003, J Exp Med. 2003; 197(9): 1083-1091). Of note, PD1 is not considered as being a membrane-bound form of PD-L1 ligand according to the present invention. According to another embodiment, said immunosuppressive polypeptide is under a secreted form. Such recombinant secreted PD-L1 (or soluble PD-L1) may be generated by fusing the extracellular domain of PD-L1 to the Fc portion of an immunoglobulin (Haile S T et al., 2014, Cancer Immunol. Res. 2(7): 610-615; Song M Y et al., 2015, Gut. 64(2):260-71). This recombinant PD-L1 can neutralize PD-1 and abrogate PD-1-mediated T-cell inhibition. PD-L1 ligand may be co-expressed with CTLA4 Ig for an even enhanced persistence of both.
According to another embodiment, the exogenous sequence encodes a non-human MHC homolog, especially a viral MHC homolog, or a chimeric β2m polypeptide such as described by Margalit A. et al. (2003) “Chimeric β2 microglobulin/CD3ζ polypeptides expressed in T cells convert MHC class I peptide ligands into T cell activation receptors: a potential tool for specific targeting of pathogenic CD8+ T cells” Int. Immunol. 15 (11): 1379-1387.
According to one embodiment, the exogenous sequence encodes NKG2D ligand. Some viruses such as cytomegaloviruses have acquired mechanisms to avoid NK cell mediate immune surveillance and interfere with the NKG2D pathway by secreting a protein able to bind NKG2D ligands and prevent their surface expression (Welte, S. A et al. (2003) “Selective intracellular retention of virally induced NKG2D ligands by the human cytomegalovirus UL16 glycoprotein”. Eur. J. Immunol., 33, 194-203). In tumors cells, some mechanisms have evolved to evade NKG2D response by secreting NKG2D ligands such as ULBP2, MICB or MICA (Salih H R, Antropius H, Gieseke F, Lutz S Z, Kanz L, et al. (2003) Functional expression and release of ligands for the activating immunoreceptor NKG2D in leukemia. Blood 102: 1389-1396).
According to one embodiment, the exogenous sequence encodes a cytokine receptor, such as an IL-12 receptor. IL-12 is a well known activator of immune cells activation (Curtis J. H. (2008) “IL-12 Produced by Dendritic Cells Augments CD8+ T Cell Activation through the Production of the Chemokines CCL1 and CCL171”. The Journal of Immunology. 181 (12): 8576-8584.
According to one embodiment the exogenous sequence encodes an antibody that is directed against inhibitory peptides or proteins. Said antibody is preferably be secreted under soluble form by the immune cells. Nanobodies from shark and camels are advantageous in this respect, as they are structured as single chain antibodies (Muyldermans S. (2013) “Nanobodies: Natural Single-Domain Antibodies” Annual Review of Biochemistry 82: 775-797). Same are also deemed more easily to fuse with secretion signal polypeptides and with soluble hydrophilic domains.
The different aspects developed above to enhance persistence of the cells are particularly preferred, when the exogenous coding sequence is introduced by disrupting an endogenous gene encoding β2m or another MHC component, as detailed further on.
According to one aspect of the present method, the exogenous sequence that is integrated into the immune cells genomic locus encodes a molecule that enhances the therapeutic activity of the immune cells.
By “enhancing the therapeutic activity” is meant that the immune cells, or population of cells, engineered according to the present invention, become more aggressive than non-engineered cells or population of cells with respect to a selected type of target cells. Said target cells consists of a defined type of cells, or population of cells, preferably characterized by common surface marker(s). In the present specification, “therapeutic potential” reflects the therapeutic activity, as measured through in-vitro experiments. In general sensitive cancer cell lines, such as Daudi cells, are used to assess whether the immune cells are more or less active towards said cells by performing cell lysis or growth reduction measurements. This can also be assessed by measuring levels of degranulation of immune cells or chemokines and cytokines production. Experiments can also be performed in mice with injection of tumor cells, and by monitoring the resulting tumor expansion. Enhancement of activity is deemed significant when the number of developing cells in these experiments is reduced by the immune cells by more than 10%, preferably more than 20%, more preferably more than 30%, even more preferably by more than 50%.
According to one aspect of the invention, said exogenous sequence encodes a chemokine or a cytokine, such as IL-12. It is particularly advantageous to express IL-12 as this cytokine is extensively referred to in the literature as promoting immune cell activation (Colombo M. P. et al. (2002) “Interleukin-12 in anti-tumor immunity and immunotherapy” Cytokine Growth Factor Rev. 13(2):155-68).
According to a preferred aspect of the invention the exogenous coding sequence encodes or promote secreted factors that act on other populations of immune cells, such as T-regulatory cells, to alleviate their inhibitory effect on said immune cells.
According to one aspect of the invention, said exogenous sequence encodes an inhibitor of regulatory T-cell activity is a polypeptide inhibitor of forkhead/winged helix transcription factor 3 (FoxP3), and more preferably is a cell-penetrating peptide inhibitor of FoxP3, such as that referred as P60 (Casares N. et al. (2010) “A peptide inhibitor of FoxP3 impairs regulatory T cell activity and improves vaccine efficacy in mice.” J Immunol 185(9):5150-9).
By “inhibitor of regulatory T-cells activity” is meant a molecule or precursor of said molecule secreted by the T-cells and which allow T-cells to escape the down regulation activity exercised by the regulatory T-cells thereon. In general, such inhibitor of regulatory T-cell activity has the effect of reducing FoxP3 transcriptional activity in said cells.
According to one aspect of the invention, said exogenous sequence encodes a secreted inhibitor of Tumor Associated Macrophages (TAM), such as a CCR2/CCL2 neutralization agent. Tumor-associated macrophages (TAMs) are critical modulators of the tumor microenvironment. Clinicopathological studies have suggested that TAM accumulation in tumors correlates with a poor clinical outcome. Consistent with that evidence, experimental and animal studies have supported the notion that TAMs can provide a favorable microenvironment to promote tumor development and progression. (Theerawut C. et al. (2014) “Tumor-Associated Macrophages as Major Players in the Tumor Microenvironment” Cancers (Basel) 6(3): 1670-1690). Chemokine ligand 2 (CCL2), also called monocyte chemoattractant protein 1 (MCP1—NCBI NP_002973.1), is a small cytokine that belongs to the CC chemokine family, secreted by macrophages, that produces chemoattraction on monocytes, lymphocytes and basophils. CCR2 (C—C chemokine receptor type 2—NCBI NP_001116513.2), is the receptor of CCL2.
Although the coding sequence which is inserted at said locus generally encodes polypeptide(s) improving the therapeutic potential of the engineered immune cells, the inserted sequence can also be a nucleic acid able to direct or repress expression of other genes, such as interference RNAs or guide-RNAs. The polypeptides encoded by the inserted sequence may act directly or indirectly, such as signal transducers or transcriptional regulators.
The present invention is also drawn to the variety of engineered immune cells obtainable according to one of the method described herein, under isolated form, or as part of populations of cells.
According to a preferred aspect of the invention the engineered cells are primary immune cells, such as NK cells or T-cells, which are generally part of populations of cells that may involve different types of cells. In general, population deriving from patients or donors isolated by leukapheresis from PBMC (peripheral blood mononuclear cells).
The present invention encompasses immune cells comprising any combinations of the different exogenous coding sequences and gene inactivation, which have been respectively and independently described above. Among these combinations are particularly preferred those combining the expression of a CAR under the transcriptional control of an endogenous promoter that is active during immune cell activation, in particular one promoter present at one TCR locus, in particular a TCRalpha promoter.
Another preferred combination is the insertion of an exogenous sequence encoding a CAR or one of its constituents under the transcription control of the hypoxia-inducible factor 1 gene promoter (Uniprot: Q16665).
The invention is also drawn to a pharmaceutical composition comprising an engineered primary immune cell or immune cell population as previously described for the treatment of infection or cancer, and to a method for treating a patient in need thereof, wherein said method comprises:
Whether prior to or after genetic modification, the immune cells according to the present invention can be activated or expanded, even if they can activate or proliferate independently of antigen binding mechanisms. T-cells, in particular, can be activated and expanded using methods as described, for example, in U.S. Pat. Nos. 6,352,694; 6,534,055; 6,905,680; 6,692,964; 5,858,358; 6,887,466; 6,905,681; 7,144,575; 7,067,318; 7,172,869; 7,232,566; 7,175,843; 5,883,223; 6,905,874; 6,797,514; 6,867,041; and U.S. Patent Application Publication No. 20060121005. T-cells can be expanded in vitro or in vivo. T cells are generally expanded by contact with an agent that stimulates a CD3 TCR complex and a co-stimulatory molecule on the surface of the T-cells to create an activation signal for the T-cell. For example, chemicals such as calcium ionophore A23187, phorbol 12-myristate 13-acetate (PMA), or mitogenic lectins like phytohemagglutinin (PHA) can be used to create an activation signal for the T-cell.
As non-limiting examples, T cell populations may be stimulated in vitro such as by contact with an anti-CD3 antibody, or antigen-binding fragment thereof, or an anti-CD2 antibody immobilized on a surface, or by contact with a protein kinase C activator (e.g., bryostatin) in conjunction with a calcium ionophore. For co-stimulation of an accessory molecule on the surface of the T cells, a ligand that binds the accessory molecule is used. For example, a population of T cells can be contacted with an anti-CD3 antibody and an anti-CD28 antibody, under conditions appropriate for stimulating proliferation of the T cells. Conditions appropriate for T cell culture include an appropriate media (e.g., Minimal Essential Media or RPMI Media 1640 or, X-vivo 5, (Lonza)) that may contain factors necessary for proliferation and viability, including serum (e.g., fetal bovine or human serum), interleukin-2 (IL-2), insulin, IFN-g, IL-4, IL-7, GM-CSF, IL-10, IL-2, IL-15, TGFβ, and TNF- or any other additives for the growth of cells known to the skilled artisan. Other additives for the growth of cells include, but are not limited to, surfactant, plasmanate, and reducing agents such as N-acetyl-cysteine and 2-mercaptoethanoi. Media can include RPMI 1640, A1M-V, DMEM, MEM, a-MEM, F-12, X-Vivo 1, and X-Vivo 20, Optimizer, with added amino acids, sodium pyruvate, and vitamins, either serum-free or supplemented with an appropriate amount of serum (or plasma) or a defined set of hormones, and/or an amount of cytokine(s) sufficient for the growth and expansion of T cells. Antibiotics, e.g., penicillin and streptomycin, are included only in experimental cultures, not in cultures of cells that are to be infused into a subject. The target cells are maintained under conditions necessary to support growth, for example, an appropriate temperature (e.g., 37° C.) and atmosphere (e.g., air plus 5% CO2). T cells that have been exposed to varied stimulation times may exhibit different characteristics.
In another particular embodiment, said cells can be expanded by co-culturing with tissue or cells. Said cells can also be expanded in vivo, for example in the subject's blood after administrating said cell into the subject.
The method of the present invention described above allows producing engineered primary immune cells within a limited time frame of about 15 to 30 days, preferably between 15 and 20 days, and most preferably between 18 and 20 days so that they keep their full immune therapeutic potential, especially with respect to their cytotoxic activity.
These cells form a population of cells, which preferably originate from a single donor or patient. These populations of cells can be expanded under closed culture recipients to comply with highest manufacturing practices requirements and can be frozen prior to infusion into a patient, thereby providing “off the shelf” or “ready to use” therapeutic compositions.
As per the present invention, a significant number of cells originating from the same Leukapheresis can be obtained, which is critical to obtain sufficient doses for treating a patient. Although variations between populations of cells originating from various donors may be observed, the number of immune cells procured by a leukapheresis is generally about from 108 to 1010 cells of PBMC. PBMC comprises several types of cells: granulocytes, monocytes and lymphocytes, among which from 30 to 60% of T-cells, which generally represents between 108 to 109 of primary T-cells from one donor. The method of the present invention generally ends up with a population of engineered cells that reaches generally more than about 108 T-cells, more generally more than about 109 T-cells, even more generally more than about 1010 T-cells, and usually more than 1011 T-cells.
The invention is thus more particularly drawn to a therapeutically effective population of primary immune cells, wherein at least 30%, preferably 50%, more preferably 80% of the cells in said population have been modified according to any one the methods described herein.
According to a preferred aspect of the invention, more than 50% of the immune cells comprised in said population are TCR negative T-cells. According to a more preferred aspect of the invention, more than 50% of the immune cells comprised in said population are CAR positive T-cells. Engineered immune cells, Populations of cells, therapeutic compositions and uses.
Such compositions or populations of cells can therefore be used as medicaments; especially for treating cancer, particularly for the treatment of lymphoma, but also for solid tumors such as melanomas, neuroblastomas, gliomas or carcinomas such as lung, breast, colon, prostate or ovary tumors in a patient in need thereof.
The invention is more particularly drawn to populations of primary TCR negative T-cells originating from a single donor, wherein at least 20%, preferably 30%, more preferably 50% of the cells in said population have been modified using sequence-specific reagents in at least two, preferably three different loci.
In another aspect, the present invention relies on methods for treating patients in need thereof, said method comprising at least one of the following steps:
Generally, said populations of cells mainly comprises CD4 and CD8 positive immune cells, such as T-cells, which can undergo robust in vivo T cell expansion and can persist for an extended amount of time in-vitro and in-vivo.
The treatments involving the engineered primary immune cells according to the present invention can be ameliorating, curative or prophylactic. It may be either part of an autologous immunotherapy or part of an allogenic immunotherapy treatment.
In another embodiment, said isolated cell according to the invention or cell line derived from said isolated cell can be used for the treatment of solid tumors, in particular solid tumors, such as typically: oesophageal cancer, breast cancer, gastric cancer, cholangiocarcinoma, pancreatic cancer, colon cancer, lung cancer, thymic carcinoma, mesothelioma, ovarian cancer and/or endometrial cancer.
Adult tumors/cancers and pediatric tumors/cancers are also included.
The treatment with the engineered immune cells according to the invention may be in combination with one or more therapies against cancer selected from the group of antibodies therapy, chemotherapy, cytokines therapy, dendritic cell therapy, gene therapy, hormone therapy, laser light therapy and radiation therapy.
According to a preferred embodiment of the invention, said treatment can be administrated into patients undergoing an immunosuppressive treatment. Indeed, the present invention preferably relies on cells or population of cells, which have been made resistant to at least one immunosuppressive agent due to the inactivation of a gene encoding a receptor for such immunosuppressive agent. In this aspect, the immunosuppressive treatment should help the selection and expansion of the T-cells according to the invention within the patient.
The administration of the cells or population of cells according to the present invention may be carried out in any convenient manner, including by aerosol inhalation, injection, ingestion, transfusion, implantation or transplantation. The compositions described herein may be administered to a patient subcutaneously, intradermally, intratumorally, intranodally, intramedullary, intramuscularly, by intravenous or intralymphatic injection, or intraperitoneally. In one embodiment, the cell compositions of the present invention are preferably administered by intravenous injection.
The administration of the cells or population of cells can consist of the administration of 104-109 cells per kg body weight, preferably 105 to 106 cells/kg body weight including all integer values of cell numbers within those ranges. The present invention thus can provide more than 10, generally more than 50, more generally more than 100 and usually more than 1000 doses comprising between 106 to 108 gene edited cells originating from a single donor's or patient's sampling.
The cells or population of cells can be administrated in one or more doses. In another embodiment, said effective amount of cells are administrated as a single dose. In another embodiment, said effective amount of cells are administrated as more than one dose over a period time. Timing of administration is within the judgment of managing physician and depends on the clinical condition of the patient. The cells or population of cells may be obtained from any source, such as a blood bank or a donor. While individual needs vary, determination of optimal ranges of effective amounts of a given cell type for a particular disease or conditions within the skill of the art. An effective amount means an amount which provides a therapeutic or prophylactic benefit. The dosage administrated will be dependent upon the age, health and weight of the recipient, kind of concurrent treatment, if any, frequency of treatment and the nature of the effect desired.
In another embodiment, said effective amount of cells or composition comprising those cells are administrated parenterally. Said administration can be an intravenous administration. Said administration can be directly done by injection within a tumor.
In certain embodiments of the present invention, cells are administered to a patient in conjunction with (e.g., before, simultaneously or following) any number of relevant treatment modalities, including but not limited to treatment with agents such as antiviral therapy, cidofovir and interleukin-2, Cytarabine (also known as ARA-C) or nataliziimab treatment for MS patients or efaliztimab treatment for psoriasis patients or other treatments for PML patients. In further embodiments, the T cells of the invention may be used in combination with chemotherapy, radiation, immunosuppressive agents, such as cyclosporin, azathioprine, methotrexate, mycophenolate, and FK506, antibodies, or other immunoablative agents such as CAMPATH, anti-CD3 antibodies or other antibody therapies, cytoxin, fludaribine, cyclosporin, FK506, rapamycin, mycoplienolic acid, steroids, FR901228, cytokines, and irradiation. These drugs inhibit either the calcium dependent phosphatase calcineurin (cyclosporine and FK506) or inhibit the p70S6 kinase that is important for growth factor induced signaling (rapamycin) (Henderson, Naya et al. 1991; Liu, Albers et al. 1992; Bierer, Hollander et al. 1993). In a further embodiment, the cell compositions of the present invention are administered to a patient in conjunction with (e.g., before, simultaneously or following) bone marrow transplantation, T cell ablative therapy using either chemotherapy agents such as, fludarabine, external-beam radiation therapy (XRT), cyclophosphamide, or antibodies such as OKT3 or CAMPATH, In another embodiment, the cell compositions of the present invention are administered following B-cell ablative therapy such as agents that react with CD20, e.g., Rituxan. For example, in one embodiment, subjects may undergo standard treatment with high dose chemotherapy followed by peripheral blood stem cell transplantation. In certain embodiments, following the transplant, subjects receive an infusion of the expanded immune cells of the present invention. In an additional embodiment, expanded cells are administered before or following surgery.
The present invention is also particularly drawn to a general method of treating solid tumor(s) in a patient, comprising the steps of immunodepleting said patient with a lymphodepletion regimen and infusing genetically engineered lymphocytes made resistant to the lymphodepletion agent used in the lymphodepletion regimen and specifically targeting said solid tumor(s). Such genetically engineered lymphocytes are preferably CAR positive T-cells, more preferably endowed with a MSLN-CAR as described herein.
The lymphodepletion regimen preferably comprises an antibody directed against an antigen present at the surface of immune cells, such as CD52, CD3, CD4, CD8, CD45, or other specific markers, or being drugs such as purine analogues (ex: fludarabine and/or chlorofarabine) and glucocorticoids.
According to a preferred embodiment of the invention, the method comprises submitting the patient to a lymphodepletion regimen comprising an antibody directed against CD52, and administrating an engineered CAR T-cell endowed with a MSLN-CAR, which expression of CD52 is reduced, deficient or inactivated.
As a preferred embodiment of the present invention, the lymphodepleting treatment can comprise an anti-CD52 antibody, such as alemtuzumab, alone or in combination. The lymphodepletion regimen may for instance combine cyclophosphamide, typically for 1 to 3 days, fludarabine for 1 to 5 days, and alemtuzumab from 1 to 5 days. In general, the lymphodepletion regimen can comprise cyclophosphamide between 50 and 70 mg/kg/day, fludarabine between 20 and 40 mg/m2/day, and alemtuzumab 0.1 to 0.5 mg/kg/day alone or in combination.
To this aim, the present invention provides with the combined use of a composition for lymphodepleting a patient affected by a solid tumor, said composition comprising an anti-CD52 antibody, and a population of engineered lymphocytes targeting MSLN that are not sensitive to said antibody, such population preferably comprising cells that express MSLN-CAR and have impaired CD52 expression. In such engineered cells, allele(s) of the CD52 gene has been preferably inactivated by a rare-cutting endonuclease, such as a TALE-nuclease or a RNA-guided endonuclease as previously described.
The present invention also provides with a medical kit comprising said lymphodepleting composition and said population of engineered cells resistant thereto for its use in solid tumors cancer treatment.
By “cytolytic activity” or “cytotoxic activity” or “cytotoxicity” is meant the percentage of cell lysis of target cells conferred by an immune cell.
A method for determining the cytotoxicity is described below:
With adherent target cells: 2.104 specific target antigen (STA)-positive or STA-negative cells are seeded in 0.1 ml per well in a 96 well plate. The day after the plating, the STA-positive and the STA-negative cells are labeled with CellTrace CFSE and co-cultured with 4×105 T cells for 4 hours. The cells are then harvested, stained with a fixable viability dye (eBioscience) and analyzed using the MACSQuant flow cytometer (Miltenyi).
With suspension target cells: STA-positive and STA-negative cells are respectively labeled with CellTrace CFSE and CellTrace Violet. About 2×104 ROR1-positive cells are co-cultured with 2×104 STA-negative cells with 4×105 T cells in 0.1 ml per well in a 96-well plate. After a 4 hour incubation, the cells are harvested and stained with a fixable viability dye (eBioscience) and analyzed using the MACSQuant flow cytometer (Miltenyi).
The percentage of specific lysis can be calculated using the following formula:
The above written description of the invention provides a manner and process of making and using it such that any person skilled in this art is enabled to make and use the same, this enablement being provided in particular for the subject matter of the appended claims, which make up a part of the original description.
Where a numerical limit or range is stated herein, the endpoints are included. Also, all values and subranges within a numerical limit or range are specifically included as if explicitly written out.
Having generally described this invention, a further understanding can be obtained by reference to certain specific examples, which are provided herein for purposes of illustration only, and are not intended to limit the scope of the claimed invention.
Mesothelin (MSLN) is a glycophosphatidylinsositol (GPI)-linked cell surface protein normally expressed in mesothelioma cells that line the pleura, peritoneum, and pericardium. The MSLN gene encodes a precursor protein of 71 kDa that is processed to a 31 kDa shed protein called MPF (megakaryocyte potentiating factor) and a 40 kDa membrane bound protein, mesothelin.
Mesothelin is reported to be highly expressed in several types of malignant tumors, such as malignant mesothelioma, ovarian cancer, pancreatic adenocarcinoma, and lung adenocarcinoma (Morello et al., 2016; O'Hara et al., 2016). In some cases, mesothelin expression has been associated with increased tumor aggressiveness and poor clinical outcome.
Three second-generation CARs composed of the respective scFvs P4, meso1 and MESO2, comprising CD8α hinge/transmembrane domain, and the 4-1BB and CD3ζ activation domains, were generated and screened for chimeric antigen receptor (CAR) expression and anti-tumor activity in vitro, through the activity of primary mesoCAR+ T-cells against target cell lines expressing different levels of Mesothelin (MSLN). In certain versions, a suicide switch “R2” was introduced in the CAR architecture. The “R2” polypeptide, which includes two CD20 mimotopes, was located between the scFv and the hinge to confer sensitivity to anti-CD20 therapeutic antibodies, such as rituximab, as previously described in WO2016120216.
A schematic representation of the CAR structure is presented in
The different sequences comprised into each CARs are detailed in tables 1, 2 and 3 and the full amino acid sequence thereof are shown in table 4.
CARs were screened for expression in primary T-cells from PBMC and assayed for their anti-tumor activity against 3 target cell lines expressing different levels of MSLN, respectively:
Expression of mesothelin at the surface of these cells was assessed by flow cytometry as shown in
P4-R2, Meso1-R2 and MESO2-R2 CARs were used to generate three MSLN-specific UCART cell products. The different UCART cell products were then evaluated in vitro.
The first in vitro study performed on the four UCART cell products aimed at determining the phenotype of UCART cells at day 18. For this purpose, CAR and TCRαβ expression at the surface of UCART cells, as well as CD4 and CD8 expression at the surface of the CAR+ fraction of UCART cells were analyzed by flow cytometry. CAR surface expression was evaluated using either His-tagged recombinant human mesothelin protein, or biotinylated protein L, that all recognize the scFv portion of the CARs or biotinylated rituximab that recognizes the R2 suicide switch portion of the CARs. TCRαβ receptor surface expression was evaluated using PE-vio770 conjugated anti-TCRαβ antibody. CD4 and CD8 surface expression were evaluated using FITC-conjugated CD4 and BV510-conjugated CD8 antibodies.
CAR surface expression was evaluated by flow cytometry using either His-tagged recombinant human mesothelin protein that recognizes the scFv portion of the CARs, or biotinylated rituximab that recognizes the R2 suicide switch portion of the CARs.
As shown in
As shown in
The second in vitro study performed on the three UCART cell products aimed at analysing UCART cells function. The capacity of UCART cells to produce cytokines upon a 24 hours coculture with HPAC (MSLN +) or 293H (MSLN −) cells was evaluated by quantifying the IFNg in cell culture supernatants by ELISA according to standard procedures.
As shown in
The capacity of UCART cells to perform serial killing of HPAC cells was then evaluated over a period of 15 days including 6 rounds of exposure to MSLN+(HPAC) cells at ratios 1:2 and 1:8.
As shown in
Importantly, none of these CART cell products displayed significant killing activity against mesothelin negative A2058 and 293H cells.
3.1 Knock-Out of the TRAC and/or CD52 Genes
As shown in
Further, according to the flow cytometry data presented in
To fully demonstrate that the absence of detection of the TCRαβ receptor at the surface of cells knocked-out for the TRAC gene and depleted in TCRαβ+ cells was associated with an absence of expression of functional TCRαβ receptor, non-engineered T-cells, T-cells knocked-out for the TRAC gene, and T-cells knocked-out for the TRAC gene and depleted in TCRαβ+ cells, were exposed for 24 hours to phytohaemagglutinin (PHA) and analyzed by flow cytometry to monitor the expression of the activation marker CD25.
As shown in
Inactivation of CD52 genes was assessed by incubating the engineered Cells after 7 days of culture in 50 μg/ml anti-CD52 monoclonal antibody (or rat IgG as control) with or without 30% rabbit complement (Cedarlane). After 2 hours of incubation at 37° C., the cells were labeled with a fluorochrome-conjugated anti-CD52 antibody together with a fluorescent viability dye (eBioscience) and analyzed by flow cytometry to measure the frequency of CD52-positive and CD52-negative cells among live cells. On another hand the cells were cultured with the antibody to select resistant
Another in vitro study performed on the UCART cell products aimed at evaluating the ability of the CAR+ fraction of UCART cells to be depleted upon treatment with rituximab.
UCART cells modified with P4-R2, Meso1-R2 and MESO2-R2 CARs were co-cultured for two days with HPAC cells, exposed for two hours to medium, rituximab (RTX), baby rabbit complement (BRC) or a mixture of rituximab and baby rabbit complement, and analyzed by flow cytometry to monitor the percentage of CAR+ cells. As shown in
Another attribute provided to MesoCAR T cell, was to resist to tumor microenvironment by inactivating TGFb signaling pathway. Two different strategies were investigated, either inactivating the expression of TGFbRII gene by knock out or by overexpressing a dominant negative form of the TGFbRII gene (dnTGFbRII).
Activated T cells were electroporated with 10 μg of mRNA encoding the right and the left arms of two TALENs targeting TGFbRII gene (SEQ ID NO:155 (pCLS32939) and SEQ ID NO:156 (pCLS32940) or SEQ ID NO:157 (pCLS32967) and SEQ ID NO:158 (pCLS32968)). Three days post transfection, T cells were harvested, gDNA was extracted and PCR was performed in order to amplify the amplicons. PCR products were analyzed by deepsequencing and results show that transfection with TALEN encoded by pCLS32939 and pCLS32940 or with TALEN encoded by pCLS32967 and pCLS32968 showed 96.62% and 97.28% of gene editions (i.e. insertions and/or deletions) respectively, demonstrating the high efficiency of TGFbRII KO.
3.3.2. Inactivation of TGFbRII by Overexpression of dnTGFbRII
MSLN-CAR T cells were produced as described in Example 2 using two different Donors and with rLV vectors encoding the different MSLN CARs and with or without a dnTGFbRII (SEQ ID NO:24) separated by a 2A cleavage peptide. After the production process, the different MSLN-CAR T cells were thawed and seeded at 3 millions cells/ml with 70 UI/ml of IL-2. One day post thawing cells were exposed to 5 ng/ml of TGFb (R&D systems). One hour later, cells were stained for CAR expression by performing a cell surface staining of the cells with biotinylated recombinant mesothelin protein (LakePharma) and brilliant Violet 421 streptavidin (BD). In addition, an intracellular staining of the MSLN-CAR T cells was performed with PE-conjugated anti-phospho SMAD2/3 (BD) according to the provider's instructions. Cells were analyzed by flow cytometry and phosphorylated SMAD2/3 status was determined in either CAR positive or CAR negative subpopulation (
Preliminary in vivo studies were performed to define and validate the animal/tumor model and route of administration of the CAR T-cells. HPAC tumor cells injected subcutaneously (SC) in NSG mice was selected as the animal/tumor model to be used to evaluate the anti-tumor activity in vivo of T-cells expressing the 3 selected mesoCAR constructs. Although meso1-R2 was below in terms of level of expression at the cell surface, cytotoxicity and IFNγ secretion, this was kept in the study and compared to P4-R2 and MESO2-R2 CARs
Human T-cells expressing the mesoCAR candidates and the P4-CAR were then evaluated for their anti-tumor activity in vivo. Briefly, NSG mice were engrafted with a MSLN+ cell line (HPAC cells, SC injection) and then treated with mesoCAR+ T-cells (IV injection, 3 doses). mesoCAR+ T-cells activity was assessed by the monitoring of tumor growth. The 3 mesoCAR+ T-cells evaluated showed anti-tumor activity in vivo against HPAC tumor cells with different level of activity. T-cells expressing the MESO2-R2 CAR showed less activity compared to the other mesoCAR+ T-cells evaluated.
Because of the human specificity of the mesoCAR+ T-cells, studies in standard immunocompetent animal models are not applicable due to the rapid targeting and elimination of human T-cells by xenogeneic immune reactions. The animal model selected is the highly immunodeficient NSG mice strain (NOD.Cg-Prkdcscid Il2rgtmw1Wjl/SzJ strain from the Jackson laboratory) as it allows the engraftment of both human MSLN+ tumor cells and human CAR T-cells.
Two mesothelin-expressing tumor cell lines: HeLa (ATCC® CCL-2), an epithelial cervix adenocarcinoma, and HPAC (ATCC® CRL-2119), an epithelial pancreatic adenocarcinoma, were used in this study. The aim of this first study was to evaluate the tumor take and tumor growth parameters of HeLa and HPAC cells after subcutaneous (SC) injection of NSG mice (6-8 weeks old).
Briefly, on Day 0, mice were randomized according to their individual body weight into 4 groups of 6 mice each and received a SC injection of HeLa (1×106 or 10×106 cells/mouse) or HPAC cells (2×106 or 10×106 cells/mouse). Quantity of tumor cells were chosen according to the literature [Abate-Daga, D., et al. (2014). A Novel Chimeric Antigen Receptor Against Prostate Stem Cell Antigen Mediates Tumor Destruction in a Humanized Mouse Model of Pancreatic. Cancer. Hum. Gene Ther, Arjomandnejad et al. (2014) Hela cell line xenograft tumor as a suitable cervical cancer model: Growth kinetic characterization and immunohistochemistry array. Arch. Iran. Med.; Kusakawa et al. (2015) Characterization of in vivo tumorigenicity tests using severe immunodeficient NOD/Shi-scid IL2Rγnull mice for detection of tumorigenic cellular impurities in human cell-processed therapeutic products. Regen. Ther.).
Body weight, viability and behavior were monitored every day. The tumor volume was measured three times a week. Surviving mice were terminated at Day 61 (end of study). Necropsy (macroscopic examination) was performed on all terminated animal in the study, and, if possible, on all euthanized moribund or found dead animal.
Both HPAC and Hela tumors have grown in NSG mice. HPAC tumor grew faster than Hela tumor. Mean tumor volume V (500 mm3) for mice injected with 1×106 and 10×106 HeLa cells was respectively 519 mm3 and 498 mm3 with a mean time to reach of 55 days and 49 days. Mean tumor volume V (500 mm3) for mice injected with 2×106 and 10×106 HPAC cells was respectively 557 mm3 and 500 mm3 with a mean time to reach of 24 days and 23 days.
The aim of the second study was to evaluate the level of expression of the mesothelin in both HPAC and Hela tumors after subcutaneous injection and growth of tumor cells in NSG mice.
Briefly, on Day 0, mice were randomized according to their individual body weight into 2 groups of 3 mice each and received a SC injection of HeLa (10×106 cells/mouse) or HPAC cells (2×106 cells/mouse). Body weight, viability and behavior were monitored every day. The tumor volume was measured three times a week. Tumors were collected when tumor volume reached 300-500 mm3. Tumor samples were analyzed by immunohistochemical (IHC) analysis of mesothelin expression. Last mouse was sacrificed at Day 63 (end of study).
Both HPAC and Hela tumors have grown in NSG mice. As observed in the previous study, HPAC tumors have grown faster than Hela tumors. The mean tumor volume of 300 mm3 for mice injected with HeLa cells or HPAC cells was respectively reached at 40 days and 28 days.
In addition, the expression of mesothelin on the tumor cells was checked using IHC on tumors collected on the mice. Both tumors expressed mesothelin.
Based on these confirmatory data, it was decided to use HPAC cells (2×106 cells, SC injected) to evaluate the anti-tumor activity of mesoCAR+ T-cells.
HPAC cells expressing firefly luciferase and GFP (HPAC-luc-GFP) were generated by Cellectis and the tumor take and tumor growth of HPAC-luc-GFP cells in NSG mice was evaluated as previously described.
Briefly, on Day 0, 3 mice received a SC injection of HPAC-luc-GFP cells (2×106 cells/mouse). Body weight, viability and behavior were monitored every day. The tumor volume was measured three times a week and bioluminescence imaging was performed on Day 7, 14 and 24. Viability and behavior were monitored every day.
Since these conditions offered sensitivity for this assay, it was decided to use wild type HPAC cells (SC injection, 2×106 cells/mouse) to evaluate mesoCAR+ T-cells activity in vivo.
The aim of this study was to compare the anti-tumor activity of the 3 UCARTmeso candidates (P4-R2, MESO2-R2 and meso1-R2) in NSG mice bearing subcutaneous HPAC tumors using the treatment conditions defined using the pilot study. 3 doses of CAR+ T-cells were evaluated (1, 3 and 10×106 CAR positive cells/mouse).
UCARTmeso and control T-cells were produced with PBMCs from the same donor. UCARTmeso and controls T-cells were not purified for TCRαβ-negative cells. Characteristics of the T-cells used are in Table 9.
Briefly, 85 NSG mice received a subcutaneous injection of HPAC tumor cells (2×106 cells/mouse) at Day −7. At Day 0, 80 tumor bearing mice were randomized according to the tumor volume into 16 groups of 5 mice.
Human T-cells (UCARTmeso cells and KO TRAC/NT cells in control) were injected on Day 0 (for groups 1 to 15) or on Day 12 (for group 16). For UCARTmeso cells, the total number of cells injected was defined according to the percentage of CAR positive cells in the batch in order to inject the indicated number of CAR positive cells per mouse (1, 3 or 10×106 CAR positive cells).
The anti-tumor activity of UCARTmeso candidates CARs (P4-R2, Meso1-R2 and MESO2-R2) was evaluated by measuring the tumor volume (
As shown in
An animal/tumor model and treatment conditions allowing the evaluation of anti-tumor activity of CAR T-cells targeting mesothelin has been set-up. Activity of the 3 CAR candidates MESO2-R2, Meso1-R2 and P4-R2) was evaluated in vivo using this animal model and all CAR T-cells showed anti-tumor activity against HPAC cells.
However, activity was lower for MESO2-R2 CAR+ T-cells compared to CAR+ T-cells expressing Meso1-R2.
Among the CAR T-cells bearing the selected attributes (R2 suicide switch and TRAC KO), Meso1-R2 CAR T-cells candidate is displaying the highest in-vivo activity at the 3 evaluated doses.
4.4—Evaluation of Anti-Tumor Activity of UCARTmeso Candidates Expressing dnTGFBRII
The aim of this study was to compare, in NSG mice, the anti-tumor activity of 2 UCARTmeso candidates (P4-R2, MESO1-R2) that are also expressing dnTGFBRII. Briefly, on Day 0, 4 to 6 mice per group received a SC injection of HPAC cells (2×106 cells/mouse). Body weight, viability and behavior were monitored every day. The tumor volume was measured three times a week. Viability and behavior were monitored every day.
All UCARTmeso expressing dnTGFBRII were produced with PBMCs from the same donor and 2 doses of CAR+ T-cells were evaluated (3 and 10×106 CAR positive cells/mouse).
The anti-tumor activity of UCARTmeso candidates expressing dnTGFBRII (P4-R2, MESO1-R2) was evaluated by measuring the tumor volume (
5—Comparison of TGFBRII Gene Inactivation (KO TGFBRII) and the dnTGFBRII Gene Overexpression Approaches for UCART Targeting Mesothelin (UCART MESO)
The work presented in this study aimed at comparing the TGFBRII KO and the dnTGFBRII gene overexpression approaches and to select the best approach for UCART MESO.
To conduct this study, six types of genetically modified T cells (as define in Table 10) were generated and tested.
At day 18, the UCART were analyzed by flow cytometry. CAR surface expression was evaluated using biotinylated recombinant mesothelin protein, that recognize the scFv portion of the CARs and PE-conjugated streptavidin. The dnTGFBRII was evaluated using an anti-TGFBRII (from Abcam) and an APC-conjugated anti mouse IgG antibody. CD4 and CD8 surface expression were evaluated using FITC-conjugated CD4 and BV510-conjugated CD8 antibodies. In addition, the stemness of the UCART cells in CAR+CD4+ or CAR+ CD8+ positive cells where analyzed using anti-CD62L conjugated to PECy7 and anti-CD45RA coupled to APC.
As shown in
Interestingly, among CAR positive cells, the percentage of CD8+ positive cells was varying between 27 and 35% when the UCART cells expressed the P4 CAR construct. Whereas when expressing the MESO1 construct, the percentage CD8+ cells (among CAR positive cells) was varying from 36 to 51% (
In addition, the analysis of stemness revealed that in CAR+CD4+ cells (
These results demonstrate that even if less expressed or detected, the MESO1 CAR led to a higher proportion of CD8+ (i.e. cytotoxic) and a higher proportion of Tn and Tscm subset than the P4CAR. Importantly the inactivation of TGFBRII either by overexpression of the dnTGFBRII construct or by KO had no impact on any of the phenotypes analysed.
After a 16 hours post thaw recovery period, T cells genetically modified as indicated in Table 9 were mixed with H226-Luc/GFP cells at 1:3, 1:1, 3:1, 10:1 effector-to-target (E:T) ratios. Cocultures were then incubated overnight at 37° C. and bioluminescence was measured to quantify the lysis of H226 cells. Alternatively, after the post thawing recovery period, these genetically modified T cells were resuspended in culture medium and seeded at a density of 200000 cells/well in 96 well untreated or previously coated with 75 ng/well of His-tagged recombinant mesothelin protein plates. Following a 24 hours incubation period, cell supernatants were collected and analyzed by ELISA to quantify the production of IFNg.
As shown in
In order to determine the impact of TGFB pathway inactivation either by KO or by overexpression of a dnTGFBRII, the genetically modified T cells as described in Table 9 were exposed to TGFb for one hour and were analyzed by flow cytometry to evaluate the fraction of pSMAD2/3 positive vs pSMAD2/3 negative cells among CAR positive cells. In another set of experiment, the produced UCART cells were exposed to recombinant mesothelin protein in presence or not of TGFb and were counted 7 days later to assess proliferation.
Number | Date | Country | Kind |
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PA 2019 70835 | Dec 2019 | DK | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/087673 | 12/22/2020 | WO |