6533b85cfe1ef96bd12bd0d1

RESEARCH PRODUCT

Etude de la régulation transcriptionnelle des lymphocytes T CD4 dans un contexte de cancer : application en immunothérapie anticancéreuse

subject

description

Immune surveillance of tumors is based on the ability of effector cells of the immune system to detect and eliminate the cancer cells. Notwithstanding, the complete and spontaneous regression of established cancers was observed only in very few cases. The failure of cancer resolution by the immune system could result from the combination of several factors: i) inadequate immune response related to a low tumor immunogenicity, ii) incompetent immune system consecutively to induced or acquired immunodeficiencies and iii) the selection of resistant tumor variants able to thwart immune surveillance or subverting immune responses. Developing novel cancer immunotherapy strategies leading to potentiation of the host antitumor responses is thus a key challenge in oncology.We aim to better characterize the relationships between immune response and cancer. My work is precisely to understand the molecular mechanisms involved in CD4 T cell differentiation and to determine the role of these cells in antitumor immunity. I am particularly committed to explore the molecular mechanisms underlying the Th17, Th9 and TFh cell differentiations. The goal is to better understand and adjust their effector functions to optimize antitumor responses. This work is part of a potential application in cancer immunotherapy approach, an area that is experiencing dramatic advances and is likely to grow in the years ahead.We first studied the influence of the n 3 polyunsaturated fatty acid docosahexaenoic acid (DHA) on Th17 cell differentiation. We unraveled the molecular mechanism responsible for the direct inhibition of Th17 cell polarization by DHA, explaining one way of DHA to exert its anticancer activity. TH17 cells induced in vitro displayed increased SOCS3 expression and diminished capacity to produce interleukin 17 following activation of PPARγ by DHA. In two different mouse cancer models, DHA prevented tumor outgrowth and angiogenesis in an IL 17 dependent manner. Altogether, our results uncover a novel molecular pathway by which PPARγ induced SOCS3 expression prevents IL 17 mediated cancer growth.Then, we characterized the effects of interleukin 1β (IL-1β) on Th9 cells molecular program. We found that the transcription factor IRF1 enhanced the effector functions of Th9 cells and dictated their anticancer properties. Under Th9 skewing conditions, IL-1β induced phosphorylation of the transcription factor STAT1 and subsequent expression of IRF1, which bound to Il9 and Il21 gene promoters and enhanced their secretion by Th9 cells. In addition, IL-1β induced Th9 cells exerted potent anticancer functions in an IRF1 and IL 21 dependent manner. Thus, our findings identify IRF1 as a target for controlling the function of Th9 cells.We are currently investigating the transcriptional regulation of IRF1 on follicular helper CD4 T (TFh) cell program. We address the question whether TFh cells could be beneficial in cancer immunotherapy. Our study highlights the early activation of IRF1 during the TFh cell polarization and suggests that IRF1 appears to initiate the development of these cells. Adoptive transfer approaches show that TFh lymphocytes seem to habor anticancer properties by limiting efficiently tumor outgrowth in mouse models of cancer. Finally, phenotypic characterization of TFh cells points out that they infiltrate human breast tumors and express IRF1.