Développement d'outils innovants et sécurisés de thérapie cellulaire et génique basés sur la reprogrammation de lymphocytes T dans un contexte d'immunothérapie anti-tumorale / Development of innovant engineering T cells for cancer immunotherapy

Bôle-Richard, Elodie

24 June 2016

La thérapie cellulaire est basée sur l'administration de cellules immunocompétentes dans le but d'induire une réponse thérapeutique. Le transfert de gène est un moyen d'optimiser et de sécuriser la thérapie cellulaire. Récemment, plusieurs essais cliniques d'immunothérapie ont montré l'efficacité de lymphocytes T reprogrammés pour le traitement des cancers. De plus, le transfert de gène « suicide » permet de sécuriser les effecteurs immunitaires utilisés en thérapie cellulaire. Cependant, les capacités des cellules pourraient encore être améliorées par l'expression de cytokines et de récepteurs aux chémiokines. Dans ce contexte, l'objectif de ce projet de thèse était le développement et la caractérisation d'outil innovants de thérapie génique. Ce travail a demandé le développement de vecteurs sécurisés pour 1 reprogrammation des lymphocytes T avec un CAR et leur persistance in vivo. Ces outils pourront par la suite être mis à la disposition de la recherche clinique afin de promouvoir de nouvelles stratégies de thérapi cellulaire anti-tumorale. / Cell therapy is based on administration of immunocompetent cells in order to induce a therapeutic response. Gene transfer can optimize and secure the cell therapy. Recently, several clinical trials of immunotherapy have shown the efficacy of reprogrammed T cells for the treatment of cancers. Moreover, the transfer of suicide gene enables th use of secure immune effectors in cell therapy. However, capacities of cells could be further improved by the expression of cytokines and receptors chemiokines. ln this context, the aim of this thesis project was the development and the characterization of innovative tools for gene therapy. This work required the development of safe retroviral vectors for reprogramming T cells with Chi me rie Antigen Receptor (CAR). These tools will be made available for clinical research in order to promote new anti-tumor cell therapy strategies.

Thérapie génique

Thérapie cellulaire

Récepteurs chimérique à l'antigène

Gène suicide

Gene therapy

Cell therapy

CART cell

Suicide gene transfer

616.9

PHARMACOLOGICAL TARGETING OF FGFR SIGNALING TO INHIBIT BREAST CANCER RECURRENCE AND METASTASIS

Saeed Salehin Akhand (8771426)

29 April 2020

Breast cancer (BC) is one of the deadliest forms of cancers with high incidence and mortality rates, especially in women. Encouragingly, targeted therapies have improved the overall<br>survival and quality of life in patients with various subtypes of BC. Unfortunately, these first-line therapies often fail due to inherent as well as acquired resistance of cancer cells. Treatment evading cancer cells can exhibit systemic dormancy in patients over a long period of time without manifesting any symptoms. In a suitable environment, these undetected disseminated tumor cells can relapse in the form of metastasis. Therefore, it is essential to understand the mechanisms of<br><div>BC recurrence and to develop durable therapeutic interventions to improve patient’s survival. In this dissertation work, we studied fibroblast growth factor receptors (FGFR), as therapeutic targets to treat the recurrence of drug-resistant and immune-dormant BC metastasis. <br></div><div><br></div><div>The HER2 subtype of BC is characterized by the overexpression of human epidermal growth factor receptor 2 (HER2), which drives elevated downstream signaling promoting tumorigenesis. Trastuzumab emtansine (T-DM1) is an antibody-drug conjugate in which an anti-HER2 antibody targets HER2 overexpressing tumor cells and delivers a highly potent microtubule inhibitor. Using novel models of minimal residual disease (MRD) following T-DM1 treatments, we found that epithelial to mesenchymal transition is a critical process for cells to persist the TDM1 treatments. The upregulation of FGFR1 may facilitate insensitivity to T-DM1. Our data also showed that FGFR1 overexpression in HER2+ tumors leads to a higher incidence of recurrence, and these recurrent tumors show sensitivity towards covalent inhibition of FGFR. <br></div><div><br></div><div>In addition to drug-induced MRD in the primary tumor sites, disseminated tumor cells (DTCs) can demonstrate dormant phenotype via maintaining an equilibrium with immunemediated tumor clearance. Factors affecting such equilibrium may contribute to the recurrence of breast cancers metastasis. We show that such immune-mediated dormancy can be modeled with the 4T07 tumors. These tumors display immune-exclusion phenotypes in metastatic pulmonary organs. The inhibition of FGFR modulates the immune cell compositions of pulmonary organs favoring anti-tumor immunity. However, inhibition of FGFR may also affect T cell receptor downstream signaling, resulting in the inhibition of cytolytic T cell’s function. Finally, we report that combination therapy using the FGFR kinase inhibitor and an immune checkpoint blockade showed effective targeting of metastatic 4T07 tumors. <br></div><div><br></div><div>FGFR signaling as a therapeutic target in various tumors has been an active focus of cancer research. In this dissertation work, we have expanded our understanding of the role of FGFR in the recurrence of drug-resistant breast cancers as well as in the maintenance of an immune evasive microenvironment promoting pulmonary growth of tumors. Moreover, we presented evidence that it is possible to repurpose FGFR targeted therapy alone or in combination with checkpoint blockades to target recurrent metastatic BCs. In the future, our novel models of minimal residual diseases and systemic immune dormancy may act as valuable biological tools to expand our understanding of the minimal residual disease and dormant tumor cells.</div>

Pharmacology

Cancer

Cellular Immunology

Tumour Immunology

breast cancer biology

immuno regulation

Cancer dormancy

Drug Resistance

FGFR 1 inhibitor

FGFR signaling

EMT

T cell

immunooncology

Immune oncology

Cellular Therapy

CART Cell