Interaction entre les lymphocytes T Vγ9Vδ2 et les stades sanguins de P. falciparum : de l'activation aux fonctions effectrices

Le développement d'un vaccin anti-paludique est limité par notre connaissance incomplète des effecteurs agissant contre P.falciparum. Nous avons mis en évidence que les cellules T Vγ9Vδ2 sont activées par la forme intra-érythrocytaire (schizonte) et par les phosphoantigènes de P.falciparum, et peuvent inhiber la croissance du parasite in vitro par un mécanisme dépendant de la granulysine ciblant la forme invasive du parasite (mérozoïte). Ces résultats suggérent que les lymphocytes T Vγ9Vδ2 jouent un rôle dans le contrôle précoce de la charge parasitaire. Cependant, le mécanisme médiant l’interaction entre les schizontes, les mérozoïtes les cellules T Vγ9Vδ2 et reste élusif. L'objectif de cette thèse est d’étudier les interactions entre les stades sanguins de P. falciparum et les cellules T Vγ9Vδ2, afin de mieux comprendre leurs activités anti-parasitaires, dans le but à long terme d’une utilisation clinique. Dans ce travail, nous étudions l'importance du contact direct avec les parasites dans l’activation et les activités anti-parasitaires des cellules T Vγ9Vδ2, par des approches de microscopie confocale et de cytométrie en flux. Nous suggérons que les cellules T Vγ9Vδ2 forment peu ou pas de contacts avec les mérozoïtes, et très peu de contacts avec le schizonte. De plus, nous montrons que, contrairement à une lignée cellulaire tumorale cible (Daudi), le contact avec les schizontes n'affecte pas l'activation des cellules T Vγ9Vδ2, suggérant que les phosphoantigenes du parasite sont libérés dans le milieu. Nous démontrons que les phosphoantigènes produits par la voie DOXP sont probablement libérés par un processus actif, dépendant des new permeation pathways (NPP). Ensembles, ces résultats suggèrent que l'activation et l'activité antiparasitaire des cellules T Vγ9Vδ2 n’est pas dépendante du contact, mais est médié par des facteurs solubles.The limited knowledge of immune effector against Plasmodium falciparum precludes the development of a malaria efficient vaccine. We have recently evidenced that Vγ9Vδ2 T cells act as a new immune effector early in malaria infection. These cells are activated by the mature intraerythrocytic form (schizont) and by parasite-derived antigens (phosphoantigens). After activation, they inhibit in vitro parasite growth by targeting the extraerythrocytic invasive form (merozoite), by a granulysin-dependent mechanism. However, the mechanism by which Vγ9Vδ2 T cells are activated by schizonts and target merozoites remains elusive. The aim of this PhD project is to describe the interactions between P.falciparum blood stages and γδ T cells, in order to better understand their anti-parasitic activities and in the long term goal to manipulate these cells to prevent malaria. In the work, we investigate the importance of cell to parasite contact in Vγ9Vδ2 T cell activation and anti-parasitic activity by time-lapse and fixed confocal imaging, and cytometry. We suggest that Vγ9Vδ2 T cells form little or no contacts with merozoites, and very few contacts with the mature intraerythrocytic (schizont) form of the parasite. Moreover, we show that cytotoxic activities are elicited by schizonts, but that contrary to a known tumor cell line (Daudi cells), contact has no effect on the level of activation, suggesting that parasite-derived phosphoantigens are secreted in the microenvironment. We pursue the characterization of the parasite-derived phosphoantigens and demonstrate that they are produced by the DOXP pathway. Lastly, we show that phosphoantigens are most likely released by an active process, dependent on the new permeation pathways. Altogether, these results shed light on an unconventional mode of activation by P.falciparum blood stages and antiparasitic activity of Vγ9Vδ2 T cells, which is not contact-dependent, but rather is mediated by soluble factors

Interaction entre les lymphocytes T Vγ9Vδ2 et les stades sanguins de P. falciparum : de l'activation aux fonctions effectrices

Le développement d'un vaccin anti-paludique est limité par notre connaissance incomplète des effecteurs agissant contre P.falciparum. Nous avons mis en évidence que les cellules T Vγ9Vδ2 sont activées par la forme intra-érythrocytaire (schizonte) et par les phosphoantigènes de P.falciparum, et peuvent inhiber la croissance du parasite in vitro par un mécanisme dépendant de la granulysine ciblant la forme invasive du parasite (mérozoïte). Ces résultats suggérent que les lymphocytes T Vγ9Vδ2 jouent un rôle dans le contrôle précoce de la charge parasitaire. Cependant, le mécanisme médiant l’interaction entre les schizontes, les mérozoïtes les cellules T Vγ9Vδ2 et reste élusif. L'objectif de cette thèse est d’étudier les interactions entre les stades sanguins de P. falciparum et les cellules T Vγ9Vδ2, afin de mieux comprendre leurs activités anti-parasitaires, dans le but à long terme d’une utilisation clinique. Dans ce travail, nous étudions l'importance du contact direct avec les parasites dans l’activation et les activités anti-parasitaires des cellules T Vγ9Vδ2, par des approches de microscopie confocale et de cytométrie en flux. Nous suggérons que les cellules T Vγ9Vδ2 forment peu ou pas de contacts avec les mérozoïtes, et très peu de contacts avec le schizonte. De plus, nous montrons que, contrairement à une lignée cellulaire tumorale cible (Daudi), le contact avec les schizontes n'affecte pas l'activation des cellules T Vγ9Vδ2, suggérant que les phosphoantigenes du parasite sont libérés dans le milieu. Nous démontrons que les phosphoantigènes produits par la voie DOXP sont probablement libérés par un processus actif, dépendant des new permeation pathways (NPP). Ensembles, ces résultats suggèrent que l'activation et l'activité antiparasitaire des cellules T Vγ9Vδ2 n’est pas dépendante du contact, mais est médié par des facteurs solubles.The limited knowledge of immune effector against Plasmodium falciparum precludes the development of a malaria efficient vaccine. We have recently evidenced that Vγ9Vδ2 T cells act as a new immune effector early in malaria infection. These cells are activated by the mature intraerythrocytic form (schizont) and by parasite-derived antigens (phosphoantigens). After activation, they inhibit in vitro parasite growth by targeting the extraerythrocytic invasive form (merozoite), by a granulysin-dependent mechanism. However, the mechanism by which Vγ9Vδ2 T cells are activated by schizonts and target merozoites remains elusive. The aim of this PhD project is to describe the interactions between P.falciparum blood stages and γδ T cells, in order to better understand their anti-parasitic activities and in the long term goal to manipulate these cells to prevent malaria. In the work, we investigate the importance of cell to parasite contact in Vγ9Vδ2 T cell activation and anti-parasitic activity by time-lapse and fixed confocal imaging, and cytometry. We suggest that Vγ9Vδ2 T cells form little or no contacts with merozoites, and very few contacts with the mature intraerythrocytic (schizont) form of the parasite. Moreover, we show that cytotoxic activities are elicited by schizonts, but that contrary to a known tumor cell line (Daudi cells), contact has no effect on the level of activation, suggesting that parasite-derived phosphoantigens are secreted in the microenvironment. We pursue the characterization of the parasite-derived phosphoantigens and demonstrate that they are produced by the DOXP pathway. Lastly, we show that phosphoantigens are most likely released by an active process, dependent on the new permeation pathways. Altogether, these results shed light on an unconventional mode of activation by P.falciparum blood stages and antiparasitic activity of Vγ9Vδ2 T cells, which is not contact-dependent, but rather is mediated by soluble factors

Tir Triggers Expression of CXCL1 in Enterocytes and Neutrophil Recruitment during Citrobacter rodentium Infection.

The hallmarks of enteropathogenic Escherichia coli (EPEC) infection are formation of attaching and effacing (A/E) lesions on mucosal surfaces and actin-rich pedestals on cultured cells, both of which are dependent on the type III secretion system effector Tir. Following translocation into cultured cells and clustering by intimin, Tir Y474 is phosphorylated, leading to recruitment of Nck, activation of N-WASP, and actin polymerization via the Arp2/3 complex. A secondary, weak, actin polymerization pathway is triggered via an NPY motif (Y454). Importantly, Y454 and Y474 play no role in A/E lesion formation on mucosal surfaces following infection with the EPEC-like mouse pathogen Citrobacter rodentium. In this study, we investigated the roles of Tir segments located upstream of Y451 and downstream of Y471 in C. rodentium colonization and A/E lesion formation. We also tested the role that Tir residues Y451 and Y471 play in host immune responses to C. rodentium infection. We found that deletion of amino acids 382 to 462 or 478 to 547 had no impact on the ability of Tir to mediate A/E lesion formation, although deletion of amino acids 478 to 547 affected Tir translocation. Examination of enterocytes isolated from infected mice revealed that a C. rodentium strain expressing Tir_Y451A/Y471A recruited significantly fewer neutrophils to the colon and triggered less colonic hyperplasia on day 14 postinfection than the wild-type strain. Consistently, enterocytes isolated from mice infected with C. rodentium expressing Tir_Y451A/Y471A expressed significantly less CXCL1. These result show that Tir-induced actin remodeling plays a direct role in modulation of immune responses to C. rodentium infection

Phosphoantigen Burst upon Plasmodium falciparum Schizont Rupture Can Distantly Activate Vγ9Vδ2 T Cells

International audienceMalaria induces potent activation and expansion of the V9V2 subpopulation of T cells, which inhibit the Plasmodium fal-ciparum blood cycle through soluble cytotoxic mediators, abrogating merozoite invasion capacity. Intraerythrocytic stages efficiently trigger V9V2 T-cell activation and degranulation through poorly understood mechanisms. P. falciparum blood-stage extracts are known to contain phosphoantigens able to stimulate V9V2 T cells, but how these are presented by intact infected red blood cells (iRBCs) remains elusive. Here we show that, unlike activation by phosphoantigen-expressing cells, V9V2 T-cell activation by intact iRBCs is independent of butyrophilin expression by the iRBC, and contact with an intact iRBC is not required. Moreover, blood-stage culture supernatants proved to be as potent activators of V9V2 T cells as iRBCs. Bioactivity in the microenvironment is attributable to phosphoantigens, as it is dependent on the parasite DOXP pathway, on V9V2 TCR signaling, and on butyrophilin expression by V9V2 T cells. Kinetic studies showed that the phosphoantigens were released at the end of the intraerythrocytic cycle at the time of parasite egress. We document exquisite sensitivity of V9V2 T cells, which respond to a few thousand parasites. These data unravel a novel framework, whereby release of phosphoantigens into the extra-cellular milieu by sequestered parasites likely promotes activation of distant V9V2 T cells that in turn exert remote antipara-sitic functions