Global ETD Search

61	T-Cell Immunogenicity and Dysfunction in Cancer and Viral Diseases January 2017 (has links) abstract: CD8+ T-lymphocytes (CTLs) are central to the immunologic control of infections and are currently at the forefront of strategies that enhance immune based treatment of a variety of tumors. Effective T-cell based vaccines and immunotherapies fundamentally rely on the interaction of CTLs with peptide-human leukocyte antigen class I (HLA-I) complexes on the infected/malignant cell surface. However, how CTLs are able to respond to antigenic peptides with high specificity is largely unknown. Also unknown, are the different mechanisms underlying tumor immune evasion from CTL-mediated cytotoxicity. In this dissertation, I investigate the immunogenicity and dysfunction of CTLs for the development of novel T-cell therapies. Project 1 explores the biochemical hallmarks associated with HLA-I binding peptides that result in a CTL-immune response. The results reveal amino acid hydrophobicity of T-cell receptor (TCR) contact residues within immunogenic CTL-epitopes as a critical parameter for CTL-self/nonself discrimination. Project 2 develops a bioinformatic and experimental methodology for the identification of CTL-epitopes from low frequency T-cells against tumor antigens and chronic viruses. This methodology is employed in Project 3 to identify novel immunogenic CTL-epitopes from human papillomavirus (HPV)-associated head and neck cancer patients. In Project 3, I further study the mechanisms of HPV-specific T-cell dysfunction, and I demonstrate that combination inhibition of Indoleamine 2, 3-dioxygenase (IDO-1) and programmed cell death protein (PD-1) can be a potential immunotherapy against HPV+ head and neck cancers. Lastly, in Project 4, I develop a single-cell assay for high-throughput identification of antigens targeted by CTLs from whole pathogenome libraries. Thus, this dissertation contributes to fundamental T-cell immunobiology by identifying rules of T-cell immunogenicity and dysfunction, as well as to translational immunology by identifying novel CTL-epitopes, and therapeutic targets for T-cell immunotherapy. / Dissertation/Thesis / Doctoral Dissertation Biological Design 2017 Immunology Oncology Virology Cancer Immunotherapy CD8+ T-cell Epitopes Head and Neck Cancer HPV Self/Non-self T-cell Exhaustion
62	Discovering Master Regulators of Single-Cell Transcriptional States in the Tumor Immune Microenvironment to Reveal Immuno-Therapeutic Targets and Synergistic Treatments Obradovic, Aleksandar January 2022 (has links) The development of checkpoint immunotherapy has been a paradigm shift in the treatment of cancer, leading to dramatic improvement in treatment outcomes across a broad range of tumor types. Nevertheless, our current understanding of the tumor immune microenvironment and mediators of resistance to therapy are limited. The recent development of high-throughput single-cell RNA-Sequencing (scRNA-Seq) technology has opened up an unprecedented window into the transcriptional states of distinct tumor-infiltrating immune and stromal cells. However, even this technology has its biological limitations, with very high levels of data dropout induced by low total mRNA molecules and capture efficiency. This thesis explores the application of a transcriptional regulatory protein activity inference approach to single-cell data in order to resolve gene dropout and more deeply characterize upstream drivers of cell state within the micro-environment of several distinct tumor types. To this end, algorithms for inference of protein activity, drug sensitivity, and cell-cell interaction have been adapted to scRNA-Seq data, along with an approach for querying enrichment of single-cell-derived population marker gene sets patient-by-patient in larger bulk-RNA-Seq cohorts. By applying these tools systematically, we have identified distinct cellular sub-populations associated with clinical outcome in different tumor types, including a novel population of C1Q+/TREM2+/APOE+ macrophages associated with post-surgical tumor recurrence in clear cell renal carcinoma, a sub-population of fibroblasts associated with improved response to immunotherapy in head and neck squamous cell carcinoma, tumor cell subpopulations with distinct inferred drug sensitivities in cholangiocarcinoma and prostate cancer, as well as tumor-specific regulatory T-cells (Tregs), active as a mechanism of immunotherapy resistance across a range of tumor types. In ongoing clinical trials from both primary and metastatic prostate cancer as well as clear cell renal carcinoma, we are able to assess which of these populations are enriched in non-responders to checkpoint immunotherapy. The proteomic master regulators of each of these single-cell types have direct utility as potential biomarkers for treatment response, but they may also be therapeutically modulated as novel targets for combination immunotherapy, potentially improving treatment response rates and treatment outcomes in future clinical trials. Finally, this thesis also presents a discovery-to-validation platform to accelerate micro-environment-directed drug repurposing in the context of immunotherapy resistance and rapid CRISPRko validation of novel therapeutic targets. This platform has been developed specifically to validate newly identified master regulators of tumor-specific immunosuppressive regulatory T-cells (Tregs), resulting in discovery of low-dose gemcitabine as a tumor-specific Treg-modulating drug synergistic with anti-PD1 checkpoint immunotherapy and TRPS1 as a proteomic master regulator with clinically significant effect on tumor Treg-infiltrating and tumor growth rate. However, the platform itself may be readily extended in future work to prioritize agents against immunosuppressive macrophage and fibroblast populations for clinical development and trials. As we have discovered, different cancers have different populations of cells driving therapy response and resistance. Taken together, the analytical and validation tools presented in this thesis represent an opportunity to tailor future immuno-therapies at the single-cell level to particular tumor types and to individual patients. Oncology Immunology Cancer--Immunotherapy Renal cell carcinoma T cells--Therapeutic use Squamous cell carcinoma Bile ducts--Cancer Prostate--Cancer--Treatment
63	Epithelial and Macrophage RON Receptor Signaling Regulates the Antitumor Immune Response in Prostate Cancer Sullivan, Camille 22 October 2020 (has links) No description available. Cellular Biology RON receptor tyrosine kinase prostate cancer immunotherapy tumor-associated macrophage macrophage activation tumor microenvironment antitumor immune response
64	Improving Adoptive Cell Therapy to Overcome Tumor Resistance / MS-275 Enhances Antitumor Immunity During Adoptive Cell Therapy to Overcome Tumor Resistance Nguyen, Andrew 20 December 2021 (has links) Cancer immunotherapy has gained attention in recent years for its successes in potentiating immune responses that can elicit tumor control. In particular, adoptive cell therapy (ACT), which involves the autologous/allogeneic transplant of ex vivo-cultivated tumor-specific T lymphocytes, can mediate potent tumor recognition and killing; however, durable clinical responses are often difficult to obtain in solid tumors. Solid tumors and their unique microenvironments have the capacity to evade and suppress antitumor immune responses and represent significant hurdles for effective ACT. Recently, we have discovered that chemical inhibition of histone deacetylases via MS-275 (Entinostat) during ACT can subvert tumor resistance to foster potent, broad-spectrum antitumor immunity. Overall, the work described supports the efficacy of ACT in the treatment of immunosuppressive, solid tumors; however, consistency in durable clinical outcomes can only be achieved through the concurrent therapeutic targeting of tumor resistance mechanisms. This thesis uses pre-clinical models to describe how tumor resistance to ACT can manifest, and demonstrates that concurrent MS-275 delivery drives extensive immunomodulation to promote sustained tumor clearance. This includes: 1) The polarization of tumor-infiltrating myeloid cells into cytotoxic effectors with the ability to reject immune escape variants 2) The inflammatory remodeling of the tumor microenvironment to potentiate epitope spreading against secondary tumor antigens 3) The transcriptional reprogramming of adoptively transferred T cells to overcome tumor-burden-dependent exhaustion We expect that the results will help facilitate the development of next-generation ACT platforms that will feature strategies for multi-mechanistic perturbation of tumor resistance. / Thesis / Doctor of Philosophy (PhD) / The host immune system has the ability to recognize and destroy tumor cells. Therapeutic platforms that leverage antitumor immune cells, specifically T cells, have shown potency in the elimination of cancer. In the clinic, cancer immunotherapies have demonstrated early success against hematological malignancies; however, are unreliable in the treatment of solid tumors. Solid tumors utilize intrinsic and adapted mechanisms of resistance to mitigate the effectiveness of cancer immunotherapy. This thesis pursues research questions aimed at understanding how tumors resist immunotherapy, what mechanisms are utilized, and how to overcome these obstacles. We anticipate that these results will contribute to the development and incorporation of strategies to subvert tumor resistance and potentiate T cells against solid tumors. Cancer Immunotherapy Adoptive Cell Therapy MS-275 HDAC Inhibitor Tumor Resistance Immunosuppression T Cell Exhaustion Epigenetic Reprogramming
65	Probiotic Neoantigen Vectors for Precision Cancer Immunotherapy Redenti, Andrew January 2024 (has links) In 1867, Dr. Wilhelm Busch decisively exposed a cancer patient to erysipelas and notedtumor regression. The practice of inoculating tumors with bacteria became more widespread with the work of Dr. William Coley, beginning in 1891, who inoculated inoperable tumors and observed complete regressions though at times notable toxicity. These microbial manipulations of immunity now form the roots of cancer immunotherapy in modern history. Alongside the blossoming of cancer immunology since, the development of techniques to alter biological systems has given rise to synthetic biology. Together, these fields allow the programming of biological systems to precisely guide the cancer-immune interplay. As mammalian immunity targets bacterially-derived antigens due to the immunostimulatory nature of microbes, and tumors express various antigens, synthetic alteration of microbes to function as safe and effective anti-tumor vaccines is a natural proposition. In this work, I describe my development of such a microbial system comprised of a synthetic tumor-antigen construct optimized for expression in bacteria, the immunotoxin Listerolysin O, and a genetically edited probiotic E. coli chassis with multi-functional protease deletions. This platform encodes and delivers high levels of diverse tumor antigens sets, remodels the tumor microenvironment, and stimulates productive and durable anti-tumor immunity to control and eliminate primary and metastatic tumors. We show that this system induces tumor antigen-specific CD4+ and CD8+ T cells, activates NK cells, recruits and activates dendritic cells, and reduces immunosuppressive regulatory T cells, B cells, and myeloid cells within the tumor microenvironment. This work thus establishes a new class of anti-tumor vaccine which modulates all arms of immunity to achieve robust anti-tumor efficacy. Immunology Cancer--Immunotherapy Cancer--Treatment Biomedical engineering Biology Escherichia coli Probiotics Science--Historiography Busch, Wilhelm, 1826-1881 Coley, William
66	Assaying T Cell Function by Morphometric Analysis and Image-Based Deep Learning Wang, Xin January 2024 (has links) Immune cell function varies tremendously between individuals, posing a major challenge to the development and success of emerging cellular immunotherapies. In the context of T cell therapy for cancer, long-term diseases such as Chronic Lymphocytic Leukemia (CLL) often induce T cell deficiencies resembling cellular exhaustion, complicating the preparation of therapeutic quantities of cells and maintaining efficacy once reintroduced to patients. The ability to rapidly estimate the responsiveness of an individual’s T cells could provide a powerful tool for tailoring treatment conditions and monitoring T cell functionality over the course of therapy. This dissertation investigates the use of short-term cellular behavior assays as a predictive indicator of long-term T cell function. Specifically, the short-term spreading of T cells on functionalized planar, elastic surfaces was quantified by 11 morphological parameters. These parameters were analyzed to discern the impact of both intrinsic factors, such as disease state, and extrinsic factors, such as substrate stiffness. This study identified morphological features that varied between T cells isolated from healthy donors and those from patients being treated for CLL. Combining multiple features through a machine learning approach such as Decision Tree or Random Forest provided an effective means for identifying whether T cells came from healthy or CLL donors. To further automate this assay and enhance the classification outcome, an image-based deep learning workflow was developed. The image-based deep learning approach notably outperformed morphometric analysis and showed great promise in classifying both intrinsic disease states and extrinsic environmental stiffness. Furthermore, we applied this imaging-based deep learning method to predict T cell proliferative capacity under different stiffness conditions, enabling rapid and efficient optimization of T cell expansion conditions to better guide cellular immunotherapy. Looking ahead, future efforts will focus on optimizing and generalizing the model to enhance its predictive accuracy and applicability across diverse patient populations. Additionally, we aim to incorporate multi-channel imaging that captures detailed T cell subset information, enabling the model to better understand the complex interactions between different cellular features and their influence on long-term proliferation. Our ultimate vision is to translate this technology into an automated device that offers a streamlined and efficient assessment of T cell functions. This device could serve as a critical tool in optimizing T cell production and monitoring T cell functions for both autologous and allogeneic cell therapies, significantly improving the effectiveness and personalization of cancer immunotherapy. Biomedical engineering T cells--Therapeutic use Deep learning (Machine learning) Chronic lymphocytic leukemia Leukemia--Treatment Cancer--Immunotherapy Decision trees
67	Shiga toxin targeted strategy for chemotherapy and cancer immunotherapy application using copper-free « Click » chemistry Kostova, Vesela 27 November 2015 (has links) Pas de résumé / Recently targeted therapies appeared as attractive alternatives to classical antitumoral treatments. The approach, developed on the concept of targeting drug to cancer cells, aims to spear normal tissues and decrease the side effects. This doctoral dissertation focuses on developing new anticancer targeted treatments in the field of chemotherapy and cancer immunotherapy by exploiting an original targeting moiety, the B subunit of Shiga toxin (STxB). Its specific properties, such as, recognition with its receptor Gb3 overexpressed in cancer cells or in antigen-presenting cells, its unconventional intracellular trafficking, guided the choice of this protein as targeting carrier. This project is based in the use of copper-free Huisgen [3+2] cycloaddition as a coupling method, which led to successful preparation of various conjugates for their respective applications. The concept was first validated by STxB-biotin conjugate. The high yield of the reaction and the compatibility between the targeting carrier and the chemical ligation promoted the design of conjugates for chemotherapy and immunotherapy. Two therapeutical optimizations of previously developed strategy in STxB drug targeting delivery were investigated: synthesis of multivalent drug-conjugates and synthesis of conjugates containing a highly potent anticancer agent. Both approaches exploited three anticancer agents: SN38, Doxorubicin and Monomethyl auristatin F. The disulfide spacer, combined with various self-immolative systems, insured drug release. Two cytotoxic conjugates STxB–doxorubicin (STxB-Doxo) and STxB-monomethyl auristatin F (STxB-MMAF) were obtained in very high yield and demonstrated strong tumor inhibition activity in the nanomolar range on Gb3-positive cells. Based on the results the STxB-MMAF conjugate was investigated on a mouse model. The project aimed also to develop STxB bioconjugates for vaccine applications. Previous studies used B subunit as a targeting carrier coupled to an antigenic protein in order to induce a more potent immune response against cancer. The conjugates were prepared using a commercial linker, requiring modifying the antigen at first place, or by oxime ligation, where slightly acidic conditions promoted the coupling. Thus, the work presented herein proposed an alternative ligation via copper-free click chemistry especially for more sensitive antigenic proteins. Various types of conjugates were synthesised and investigated for their immune stimulation properties. The STxB targeting strategy was also applied to the development of a new vaccine based on coupling the targeting carrier to alpha-GalCer, one of the most potent immune stimulating agents known. The work focused on the synthesis of functionalised alpha-Galcer with an azide handle. Pharmacochimie Cancer Targeting therapy Cancer immunotherapy Shiga toxin Conjugate Ligation Click chemistry Multivalency SN38 Doxorubicin Auristatin Vaccine Ovalbumine Alpha-GalCer 615.19
68	Intra-tumoural regulatory T cells : a potential new target for anti-cancer immunotherapy Ireland, Demelza Jane January 2007 (has links) [Truncated abstract] Previous studies in the field of tumour immunology had identified regulatory T (Treg) cells as important suppressors of the anti-tumour immune response as the presence of Treg cells in the peripheral blood of cancer patients was correlated with worse disease outcomes. Other studies had identified Treg cells to be active at sites of immune regulation such as the gut of colitis patients. It was therefore hypothesised that Treg cells would be present and active within tumours to suppress the cellular antitumour immune response. ... This treatment targeting multiple pathways of Treg cell mediated immuno-suppression and resulted in tumour regression in 50% of treated animals. Finally, the anti-tumour immune response is complex and a potentially synergistic multi-modality treatment designed to inactivate intra-tumoural Treg cells but to also induce apoptosis in tumour cells themselves was investigated. Alpha-tocopheryl succinate (α-TOS), an analogue of vitamin E, had previously been shown to induce apoptosis in human MM xenografts implanted into immuno-deficient (nude) mice. Administration of α-TOS was therefore examined as a potentially synergistic treatment to be coupled with Treg cell inactivation. At the previously published doses used to treat immuno-deficient mice, α-TOS was found to be toxic to the immuno-competent mice used in this study. A marked depleting effect on total T cells was seen in the treated animals. The results of this thesis demonstrated the high potential for an adjunct immunotherapy of MM. They did however also highlight the importance of future studies into anticancer therapies to be conducted using clinically relevant tumour models and clinically relevant treatment regimes. The need to consider synergistic multi-modal therapies was also emphasised. Asbestosis -- Toxicology Cancer -- Immunotherapy Cancer -- Treatment Carcinogenesis Immune response -- Regulation T cells -- Receptors Regulatory T cells Immunotherapy Murine model of mesothelioma Intra-tumoural
69	Etude des mécanismes moléculaires et cellulaires impliqués dans la résistance anti-tumorale in vivo induite par le cyclophosphamide Rahir, Gwendoline 23 April 2012 (has links) Malgré la découverte des antigènes tumoraux depuis quelques décennies dans les mélanomes humains, l’immunothérapie anticancéreuse reste encore relativement inefficace. En outre, les traitements anti-tumoraux classiques tels que la chimiothérapie et la radiothérapie ont longtemps été considérés comme des traitements affectant principalement les cellules tumorales en division. Actuellement, des études de plus en plus nombreuses suggèrent que le succès de la chimiothérapie dépendrait, en partie, du système immunitaire. En effet, d’une part, les agents chimio-thérapeutiques pourraient induire une mort immunogène des cellules tumorales et donc potentialiser les réponses immunitaires. D’autre part, certains rapports montrent que la présence préalable de cellules immunes dans l’environnement tumoral améliore le pronostic clinique observé après chimiothérapie notamment.<p><p>Au cours de ce travail, nous avons étudié l’effet du cyclophosphamide (CTX, un agent alkylant) sur le système immunitaire et la résistance anti-tumorale dans des souris porteuses du mastocytome P815. Nous avons remarqué qu’une seule injection de CTX dans des souris inoculées 10-20 jours plus tôt avec une dose létale de cellules tumorales induit la survie dans 100% des souris traitées. En outre, le rejet tumoral induit par le CTX est strictement dépendant des lymphocytes T CD4+ et CD8+, et permet une résistance tumorale à long terme spécifique du mastocytome P815. Le but de cette étude était d’appréhender les mécanismes cellulaires et moléculaires impliqués dans cette mémoire spécifique de la tumeur. <p><p>Nous avons premièrement montré que le CTX augmente les réponses de type Th1 et Th17 dans des souris immunisées. L’activation de ces réponses requiert l’IL-12p40 et corrèle avec une augmentation du nombre de cellules CD11b+/F4/80+/Ly6C+, suggérant que ces DCs inflammatoires présumées pourraient être une source potentielle d’IL-12 et/ou d’IL-23. Des résultats similaires ont été observés dans des souris porteuses de la tumeur P815 et traitées au CTX. Nous avons également caractérisé les cellules T anti-tumorales effectrices qui infiltrent la tumeur et en particulier, nous avons étudié le rôle des cellules T auxiliaires CD4+ dans la migration des lymphocytes T CD8+ spécifiques de la tumeur. Nous avons observé que la déplétion des cellules T CD4+ semble induire un blocage des lymphocytes T CD8+ dans les ganglions drainant la tumeur qui ne migrent alors plus vers le foyer tumoral. Nous avons donc évalué le rôle de chimiokines/récepteurs aux chimiokines qui pourraient être impliqués dans ce processus tels que les couples CXCR3/CXCL9-10-11. <p><p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Sciences exactes et naturelles Biologie Cancer -- Immunotherapy Cancer -- Radiotherapy Cancer -- Chemotherapy Antineoplastic agents Cyclophosphamide Cancer -- Immunothérapie Cancer -- Radiothérapie Cancer -- Chimiothérapie Anticancéreux Cyclophosphamide Biologie moléculaire/Molecular biology Cancer Immunologie/Immunology
70	Régulation de l’immunogénicité tumorale et activation des lymphocytes cytotoxiques anti-tumoraux pour l’immunothérapie du cancer / Regulation of tumor immunogenicity and activation of antitumor cytotoxic lymphocytes for immunotherapy of cancer Rodriguez, Galaxia Maria January 2017 (has links) Abstract : CD8 + T cells can be programmed in their naïve state with pro-inflammatory cytokines such as IL-15 and IL-21. IL-15 induces the proliferation of CD8 + T cells and allows the generation of memory cells. IL-21 programs CD8 + T cells to become more cytotoxic while retaining a memory type phenotype. In the laboratory, we studied the effect of these two cytokines in different contexts by using the mouse model MHC-I-restricted Pmel-1 transgenic TCR specific to the melanoma-derived gp10025-33 antigen, which is also expressed by normal melanocytes. First, we elucidated the effect of IL-15 on CD8 + T cells in the Pmel-1 transgenic model lacking the protein Suppressor of cytokine signaling 1 (SOCS1). SOCS1 is a critical regulator of T cell homeostasis. We have found that these mice have CD8 + T-cells expressing surface proteins characteristic of memory T cells (CD44, Ly6C, CD122 and CD62L). However, these cells decrease the expression of the TCR and increase that of CD5, indicative of TCR activation in vivo. When stimulated in vitro, these cells displayed a highly cytotoxic phenotype but very low proliferation. Adoptive cell transfer studies in Rag1 - / - mice showed that these cells can undergo homeostatic proliferation under lymphopenic conditions. This proliferation was characterized by severe inflammatory lesions in the skin, extremities and eyes. This study demonstrates the importance of IL-15 and SOCS1 in the regulation of self-reactive cells that can be activated under lymphopenic conditions and can cause autoimmune diseases. Second, we studied the synergistic effect of IL-15 and IL-21 in native CD8+ T cells for cancer immunotherapy. We used the mouse melanoma model B16-F10 (B16) which expresses very weakly MHC-I molecules. In parallel, we studied the effect of NOD-like receptor CARD domain containing 5 (NLRC5) overexpression, the trans-activator of MHC-I genes, in B16 cells in order to increase their immunogenicity and restore anti-tumor immunity. We generated stable lines of B16 cells expressing NLRC5 (B16-5); the co-stimulatory molecule of T cells, CD80 (B16-CD80), or both (B16-5 / 80). The over-expressing NLRC5 cells positively regulated the MHC-I and LMP2, LMP7 and TAP1 genes. B16-5 cells efficiently presented gp10025-33 to CD8+ Pmel-1 T cells and induced their proliferation. This proliferation was very robust when Pmel-1 naive cells were pre-stimulated with IL-15 and IL-21 prior to activation. In the presence of CD80, B16-5 cells stimulate Pmel-1 cells even without the addition of gp100, indicating that NLRC5 facilitates the treatment and presentation of endogenous tumor antigens. During subcutaneous implantation, B16-5 cells showed a significant reduction in tumor growth in C57BL/6 hosts but not in immunodeficient hosts, indicating that tumor cells expressing NLRC5 generated an anti-tumor immunity. This response is dependent on CD8 + T cells since in mice depleted of these cells, B16-5 cells formed large subcutaneous and pulmonary tumors. Finally, immunization with irradiated B16-5 cells allowed anti-tumor protection during challenge of parental B16 cells. Collectively, our results indicate that NLRC5 could be exploited to restore tumor immunogenicity and to stimulate protective antitumor immunity. / Les cellules T CD8+ peuvent être programmées à leur état naïf avec des cytokines pro-inflammatoires telles que l’IL-15 et l’IL-21. IL-15 induit la prolifération de cellules T CD8+ et permet la génération de cellules T CD8+ mémoire. IL-21 programme les cellules T CD8+ à devenir plus cytotoxiques tout en conservant un phénotype de type mémoire. Dans le laboratoire, nous avons étudié l’effet de ces deux cytokines dans différent contextes en utilisant le modèle de souris transgénique Pmel-1 qui possède des récepteurs de cellules T (TCR) spécifiques envers le peptide gp10025-33, exprimé par des cellules de mélanome et aussi par des mélanocytes. Premièrement, nous avons élucidé l’effet de l’IL-15 sur les cellules T CD8+ dans le modèle transgénique Pmel-1 déficient dans la protéine Suppressor of cytokine signaling 1 (SOCS1). SOCS1 est un régulateur critique de l’homéostasie de lymphocytes T. Nous avons trouvé que ces souris ont de cellules T CD8+ exprimant des protéines de surface caractéristique de cellules T mémoire (CD44, Ly6C, CD122 et CD62L). Cependant, ces cellules diminuent l’expression du TCR et augmentent celle de CD5, ce qui témoigne d’une activation du TCR in vivo. Lorsque stimulées in vitro, ces cellules montrent un phénotype hautement cytotoxique mais une prolifération très faible. Lorsque nous avons fait des études de transfert cellulaire adoptive dans de souris Rag1-/-, ces cellules ont proliféré de façon importante causant des lésions inflammatoires sévères dans la peau, les extrémités et les yeux. Cette étude démontre l’importance de l’IL-15 et de SOCS1 dans la régulation de cellules auto-réactives qui peuvent être activées sous des conditions lymphopéniques et qui peuvent causer de maladies auto-immunitaires. Deuxièmement, nous avons étudié l’effet synergique d’IL-15 et d’IL-21 dans les cellules T CD8+ naïves pour l’immunothérapie du cancer. Nous avons utilisé le modèle B16-F10 (B16) de mélanome de souris qui exprime très faiblement des molécules de CMH-I. En parallèle, nous avons étudié l’effet de la surexpression de NOD-like receptor CARD domain containing 5 (NLRC5), le trans-activateur de gènes de CMH-I dans les cellules B16, dans le but d’augmenter leur immunogénicité et de restaurer l’immunité anti-tumorale. Nous avons généré des lignées stables de cellules B16 exprimant NLRC5 (B16-5); la molécule co-stimulatrice de cellules T, CD80 (B16-CD80), ou les deux (B16-5 / 80). Les cellules sur-exprimant NLRC5 ont régulé positivement de manière constitutive les gènes MHC-I et LMP2, LMP7 et TAP1. Les cellules B16-5 ont efficacement présenté gp10025-33 aux cellules T CD8+ Pmel-1 et ont induit leur prolifération. Cette prolifération a été très robuste lorsque les cellules naïves Pmel-1 étaient pré-stimulées avec IL-15 et IL-21 avant leur activation. En présence de CD80, les cellules B16-5 stimulent les cellules Pmel-1 même sans l'addition de gp100, ce qui indique que NLRC5 facilite l’apprêtement et la présentation des antigènes tumoraux endogènes. Lors de l'implantation sous-cutanée, les cellules B16-5 ont montré une réduction significative de la croissance tumorale chez des hôtes C57BL/6, mais pas chez des hôtes immuno-déficients, ce qui indique que les cellules tumorales exprimant NLRC5 ont provoqué une immunité anti-tumorale. Cette réponse est dépendante de cellules T CD8+ puisque chez les souris déplétées de ces dernières, les cellules B16-5 ont formé de grandes tumeurs sous-cutanées et pulmonaires. Enfin, l'immunisation avec des cellules B16-5 irradiées a permis une protection anti-tumorale lors de la réimplantation des cellules B16 parentales. Collectivement, nos résultats indiquent que NLRC5 pourrait être exploité pour restaurer l'immunogénicité tumorale et pour stimuler l’immunité anti-tumorale protectrice. CD8+ T cells PmeI-1 SOCS1 IL-15 IL-21 B16-F10 CMH-I NLRC5 Cancer immunotherapy Cellules T CD8+ Immunothérapie du cancer

Search results