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Developing TCR gene therapy for multiple myeloma

Developing TCR gene therapy for multiple myeloma. Gavin Bendle LLR Bennett Senior Fellow School of Cancer Sciences University of Birmingham. Overview. Introduction to TCR gene therapy of cancer Assessing the value of TCR gene therapy in a autochthonous mouse cancer model

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Developing TCR gene therapy for multiple myeloma

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  1. Developing TCR gene therapy for multiple myeloma Gavin Bendle LLR Bennett Senior Fellow School of Cancer Sciences University of Birmingham

  2. Overview • Introduction to TCR gene therapy of cancer • Assessing the value of TCR gene therapy in a autochthonous mouse cancer model • Pre-clinical development of TCR gene therapy of MM

  3. Multiple myeloma • Plasma cell malignancy that is the second most common haematological malignancy worldwide • Novel agents (e.g. lenalidomide, bortezomib) have contributed to increase in average survival times from 4 to 8 years in the last decade • Despite these advances MM remains largely incurable Need for new therapeutic approaches that not only increase survival times but are also ultimately curative

  4. Adoptive T cell therapy • T cell immunity to tumours can be induced by adoptive T cell therapy: • Transfer of T cells • T cell replete allogeneic-HSCT & DLI for haematological malignancies • Mortality/morbidity due to GVHD limits use • Transfer of genes encoding the TCR • Ag-specificity of a T cell determined by TCR • Endow patient T cells with tumour-reactivity of a defined Ag-specificity • Destroy tumours without damaging normal tissues

  5. TCR gene therapy Cancer patient Removal of peripheral blood lymphocytes Infusion of autologous TCR gene modified T cells Ex vivo transduction process • TCR gene transfer is conceptually attractive: • Generate large numbers of defined antigen-specific patient T cells • Generate tumor-reactive specificities not present in pre-existing T cell repertoire

  6. Clinical trials shown feasibility and potential of TCR gene therapy CT scan of liver metastasis in patient treated with TCR-modified T cells

  7. Clinical testing of TCR gene therapy for MM has commenced

  8. Safety risks associated with TCR gene therapy • Most targets of TCR gene therapy are tumor-associated self-antigens • Toxicity may occur if target antigen is also expressed by some normal tissues • If vital normal tissues express target antigen toxicity can be severe or even fatal Expression profile of target antigen in normal tissues: the critical parameter determining the safety of TCR gene therapy

  9. Additional genetic modification of T cells as a strategy to enhance TCR gene therapy efficacy

  10. Can additional genetic modification of TCR transduced T cells be used to obtain durable clinical responses with TCR gene therapy? • TCR gene transfer endows patient T cells with desired antigen-specificity • Can additional genetic modification endow these cells with optimal functional properties? Used a mouse model of prostate carcinoma to assess if additional genetic modification of T cells enhances TCR gene therapy efficacy

  11. 3 8-12 16 24 Invasive carcinoma expression Large T Microinvasive carcinoma intraepithelial neoplasia (PIN) TRAMP mice: prostate tumour model TRansgenic Adenocarcinoma of the Mouse Prostate (Greenberg et al, PNAS 1995) SV40 large T antigen under control of a rat probasin promoter

  12. Does TGF- signalling blockade in TCR transduced T cells promote tumour regression in TRAMP mice? • Block by co-transducing TCR Td T cells with dnTGFRII • Rationale for blockade of TGF- signalling in TCR transduced T cells: • TGF- signalling inhibits CTL proliferation & effector functions • Elevated TGF-expression in human malignancies including prostate cancer • Elevated levels of TGF- in prostate of TRAMP mice with advanced prostate cancer

  13. 3 8-12 16 24 Invasive carcinoma Microinvasive carcinoma expression Large T intraepithelial neoplasia (PIN) Does blockade of TGF- signalling in TCR transduced T cells lead to tumour regression in TRAMP mice? Histopathology Week 24 28 Group I: Pre-conditioning (5Gy TBI) + non Td T cells Group II: Pre-conditioning (5Gy TBI) + SV40TCR Td T cells Group III: Pre-conditioning (5Gy TBI) + dnTGFRII Td T cells Group IV: Pre-conditioning (5Gy TBI) + SV40TCR & dnTGFRII co-Td T cells

  14. Regression of advanced prostate cancer in TRAMP mice after TCR gene therapy and blockade of TGF- signalling

  15. TGF-1 Immunostaining Tumour regression in TRAMP mice after TCR gene therapy & TGF- blockade SV40 TCR & dnTGFRII co-Td Non-Td SV40 TCR Td SV40 Large T Ag Immunostaining Ki67 Immunostaining Is the tumour regression observed at 28 wks of age sustained?

  16. Sustained regression of advanced prostate cancer in TRAMP mice after TCR gene therapy and blockade of TGF- signalling Does the observed tumor regression lead to enhanced survival?

  17. Enhanced survival of TRAMP mice after TCR gene therapy & TGF- blockade

  18. Summary • Blockade of TGF- signalling in TCR transduced T cells promotes tumour regression in TRAMP mice with advanced prostate cancer • Demonstrates potential of additional genetic modification of TCR transduced T cells to enhance TCR gene therapy efficacy • Elevated expression of TGF- in many human malignancies including MM suggest that this approach warrants clinical testing

  19. Pre-clinical development of TCR gene therapy for MM

  20. TCR a- & b-chains are generated by genetic rearrangement TCR α-chain TCR β-chain • Sequence information in TCR a- & b-chain genes that defines TCR specificity: • V element used • J element used • Nucleotide sequence at the junction between V-J elements • Cloning of TCR genes is a bottleneck in production of new TCRs • Developed high throughput strategy to isolate TCR gene sequences for TCR gene therapy

  21. TCR gene capture technology Shear gDNA & enrich for gDNA fragments encoding TCR a & b loci Reconstruction of TCR a- & b-chain genes Identify potentially clinically relevant T cell specificities in biological materialusing multiplexing technology Align sequence pairs to reference genome to identify rearrangements at TCR a & b loci FACS sort single T cells of desired specificity, expand in vitro for 14 days and extract gDNA Paired-end deep sequencing Linnemann et al. Nature Med in press

  22. A library of cancer-testis antigen-specific TCRs assembled using TCR gene capture Rapidly assembled a panel of tumor-reactive TCRs with the potential to be used for TCR gene therapy of a variety of malignancies

  23. Cancer-testis antigens • Cancer-testis (C/T) antigens: • Expressed in human germ line & variety of human malignancies • Attractive targets for TCR gene therapy of MM: • Expression in MM cells in a high frequency of patients • Examples: • MAGE C1: ~ 70% • MAGE C2: ~ 50% • Absent from normal tissues accessible to immune system

  24. Validation and characterisation of C/T Ag-specific TCRs C/T Ag-specific TCRs isolated to date • Assess which C/T Ag-specific TCRs are best suited to clinical translation of TCR gene therapy for MM: • C/T Ag expression frequency in MM patient population • Efficacy & safety of T cells transduced with different C/T Ag-specific TCRs

  25. Blockade of TGF-b signalling in C/T Ag-specific TCR transduced T cells • Additional genetic modification of TCR transduced T cells to tailor their activity can enhance TCR gene therapy efficacy • TGF-b in MM microenvironment leads to myeloma-induced T cell dysregulation • Selectively block TGF-b signalling in C/T Ag-specific TCR transduced T cells • Generate and validate a retroviral construct encoding the relevant C/T Ag-specific TCR and a dominant-negative TGF-b receptor Primary benefit: novel clinical trials of TCR gene therapy in MM patients in B’ham

  26. Summary • TCR gene therapy holds promise as a treatment for cancer • Additional genetic modification of TCR transduced T cells to tailor their activity and enhance therapeutic efficacy • TCR gene capture utilized to assemble a library of C/T Ag-specific TCRs that can be used for TCR gene therapy of various cancers • Assessing which TCRs are best suited to clinical translation of TCR gene therapy for multiple myeloma • Pre-clinical development will be followed by clinical testing in B’ham

  27. Acknowledgements • NKI, Amsterdam • Carsten Linnemann • Laura Bies • Kaspar Bresser • Bianca Heemskerk • Pia Kvistborg • Roel Kluin • Ron Kerkhoven • Marja Nieuwland • Ji-Ying Song • John Haanen • Ton Schumacher • Cancer Sciences, B’ham • Guy Pratt • Paul Moss • Shemyakin & Ovchinnikov Institute, Moscow • Dmitriy Chudakov • Dmitriy Bolotin • MDC, Berlin • Xioajing Chen • Thomas Blankenstein

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