Negative Regulation of NKG2D Expression by IL-4 in Memory CD8 T Cells

International audienceIL-4 is one of the main cytokines produced during Th2-inducing pathologies. This cytokine has been shown to affect a number of immune processes such as Th differentiation and innate immune responses. However, the impact of IL-4 on CD8 T cell responses remains unclear. In this study, we analyzed the effects of IL-4 on global gene expression profiles of Ag-induced memory CD8 T cells in the mouse. Gene ontology analysis of this signature revealed that IL-4 regulated most importantly genes associated with immune responses. Moreover, this IL-4 signature overlapped with the set of genes preferentially expressed by memory CD8 T cells over naive CD8 T cells. In particular, IL-4 downregulated in vitro and in vivo in a STAT6-dependent manner the memory-specific expression of NKG2D, thereby increasing the activation threshold of memory CD8 T cells. Furthermore, IL-4 impaired activation of memory cells as well as their differentiation into effector cells. This phenomenon could have an important clinical relevance as patients affected by Th2 pathologies such as parasitic infections or atopic dermatitis often suffer from viral-induced complications possibly linked to inefficient CD8 T cell responses

Development of a multi-antigenic MVA therapeutic vaccine against Tuberculosis and analysis of tuberculous antibiotics influence on its immunogenicity

La tuberculose (TB), maladie pulmonaire causée par le Mycobacterium tuberculosis (Mtb), reste la première cause de mortalité par un agent infectieux. La TB est responsable de près de 1,7 million de morts et de 10,4 millions de nouveaux cas par an dans le monde. L’émergence et la propagation de souches bactériennes multi-résistantes aux antibiotiques (MDR) représentent une menace majeure grandissante et reflètent l’efficacité partielle des thérapies actuelles. Le traitement des patients atteints de TB-MDR est constitué actuellement de combinaisons d’antibiotiques, souvent toxiques, administrés pendant une longue durée, avec une efficacité limitée. Il existe donc un besoin urgent de développer de nouveaux traitements antituberculeux. L’immunothérapie, dont l’objectif est d’améliorer la réponse immunitaire de l’hôte contre le Mtb, représente une approche complémentaire intéressante dans le but de diminuer la durée et d’augmenter l’efficacité des traitements actuels de la TB-MDR. Le premier objectif de cette thèse a été de caractériser un nouveau vaccin thérapeutique, basé sur le virus de la vaccine modifié d’Ankara (Modified Vaccinia virus Ankara, MVA), le MVATG18598, qui exprime dix antigènes représentatifs des trois phases de l’infection par Mtb. En utilisant différentes lignées de souris, nous avons montré que la vaccination par MVATG18598 entraîne l'induction de réponses spécifiques cellulaires et humorales. Les cellules T produisent plusieurs cytokines de type Th1 et présentent une activité cytolytique. Dans des modèles murins d’efficacité, le MVATG18598, associé à un traitement antibiotique, réduit significativement la charge bactérienne dans les animaux infectés ainsi que le taux de rechute de la maladie après l’arrêt du traitement. Le deuxième objectif de cette thèse a été d'analyser l'impact des antituberculeux sur l'immunogénicité du vaccin MVATG18598. Nous avons montré que les antibiotiques de première ligne, et principalement l’isoniazide, diminuent la réponse immunitaire Th1 induite par le MVATG18598. De plus, nous avons démontré que la réponse humorale induite par le candidat vaccin est modifiée et s’oriente vers une augmentation du rapport IgG1/IgG2a en présence d’antibiotiques. En conclusion, nous montrons qu'un vaccin immunothérapeutique, tel que le MVATG18598, a la capacité de contribuer au contrôle de la tuberculose en augmentant l'efficacité des traitements antituberculeux. De plus, nos résultats indiquent que les antibiotiques modulent la réponse immunitaire induite par le vaccin, données devant être prises en compte lors du développement des futures stratégies immunothérapeutiquesTuberculosis (TB), a lung disease caused by Mycobacterium tuberculosis (Mtb), remains the leading cause of death worldwide from an infectious disease. TB is responsible for an estimated 1,7 million of deaths and 10,4 million new cases annually. The emergence and spreading of multidrug resistance (MDR) Mtb strains represent a major global threat and reflect limitation of current treatments. Patients with MDR-TB are currently treated with multiple drug regimens, often toxic, given for long durations, with a limited efficacy. Therefore, developing novel TB therapies is urgently needed. Immunotherapy aiming at triggering specific immune response against Mtb represents an attractive approach to shorten the duration and increase the efficacy of current MDR-TB treatment. The first aim of this PhD project was to characterize a novel therapeutic vaccine, based on the Modified Vaccinia virus Ankara (MVA), MVATG18598, expressing ten antigens representative of the three phases of Mtb infection. Using different strains of mouse, we showed that MVATG18598 vaccination is able to trigger Mtb antigens-specific humoral and cellular responses. Both CD4 and CD8 T cells display the capacity to produce multiple Th1-cytokines together with cytolytic activity. In post-exposure mouse models, MVATG18598 combined with an antibiotic regimen decreases significantly the bacterial burden in lungs of infected mice as well as the disease relapse rate after treatment completion. The second aim of this project was to analyze the impact of TB antibiotics on the immunogenicity of the MVATG18598 vaccine. We showed that first-line antibiotic regimen, mostly isoniazid, decreases antigen-specific Th1 immune response triggered by MVATG18598 vaccination in mice. Moreover, we demonstrated that Mtb-specific antibody response induced by the vaccine candidate is modified and shifted towards an increase of IgG1/IgG2a ratio in presence of drugs. Altogether, these results illustrate that immunotherapeutic vaccine such as MVATG18598 has the capacity to contribute to the control of TB by improving efficiency of anti-TB drugs treatment. In addition, our results indicate that antibiotics are able to modulate vaccine-induced immune response, a feature to consider for the future development of immunotherapie

Développement d’un vaccin thérapeutique multi-antigénique contre la tuberculose et étude de l’influence des antibiotiques antituberculeux sur son immunogénicité

Tuberculosis (TB), a lung disease caused by Mycobacterium tuberculosis (Mtb), remains the leading cause of death worldwide from an infectious disease. TB is responsible for an estimated 1,7 million of deaths and 10,4 million new cases annually. The emergence and spreading of multidrug resistance (MDR) Mtb strains represent a major global threat and reflect limitation of current treatments. Patients with MDR-TB are currently treated with multiple drug regimens, often toxic, given for long durations, with a limited efficacy. Therefore, developing novel TB therapies is urgently needed. Immunotherapy aiming at triggering specific immune response against Mtb represents an attractive approach to shorten the duration and increase the efficacy of current MDR-TB treatment. The first aim of this PhD project was to characterize a novel therapeutic vaccine, based on the Modified Vaccinia virus Ankara (MVA), MVATG18598, expressing ten antigens representative of the three phases of Mtb infection. Using different strains of mouse, we showed that MVATG18598 vaccination is able to trigger Mtb antigens-specific humoral and cellular responses. Both CD4 and CD8 T cells display the capacity to produce multiple Th1-cytokines together with cytolytic activity. In post-exposure mouse models, MVATG18598 combined with an antibiotic regimen decreases significantly the bacterial burden in lungs of infected mice as well as the disease relapse rate after treatment completion. The second aim of this project was to analyze the impact of TB antibiotics on the immunogenicity of the MVATG18598 vaccine. We showed that first-line antibiotic regimen, mostly isoniazid, decreases antigen-specific Th1 immune response triggered by MVATG18598 vaccination in mice. Moreover, we demonstrated that Mtb-specific antibody response induced by the vaccine candidate is modified and shifted towards an increase of IgG1/IgG2a ratio in presence of drugs. Altogether, these results illustrate that immunotherapeutic vaccine such as MVATG18598 has the capacity to contribute to the control of TB by improving efficiency of anti-TB drugs treatment. In addition, our results indicate that antibiotics are able to modulate vaccine-induced immune response, a feature to consider for the future development of immunotherapiesLa tuberculose (TB), maladie pulmonaire causée par le Mycobacterium tuberculosis (Mtb), reste la première cause de mortalité par un agent infectieux. La TB est responsable de près de 1,7 million de morts et de 10,4 millions de nouveaux cas par an dans le monde. L’émergence et la propagation de souches bactériennes multi-résistantes aux antibiotiques (MDR) représentent une menace majeure grandissante et reflètent l’efficacité partielle des thérapies actuelles. Le traitement des patients atteints de TB-MDR est constitué actuellement de combinaisons d’antibiotiques, souvent toxiques, administrés pendant une longue durée, avec une efficacité limitée. Il existe donc un besoin urgent de développer de nouveaux traitements antituberculeux. L’immunothérapie, dont l’objectif est d’améliorer la réponse immunitaire de l’hôte contre le Mtb, représente une approche complémentaire intéressante dans le but de diminuer la durée et d’augmenter l’efficacité des traitements actuels de la TB-MDR. Le premier objectif de cette thèse a été de caractériser un nouveau vaccin thérapeutique, basé sur le virus de la vaccine modifié d’Ankara (Modified Vaccinia virus Ankara, MVA), le MVATG18598, qui exprime dix antigènes représentatifs des trois phases de l’infection par Mtb. En utilisant différentes lignées de souris, nous avons montré que la vaccination par MVATG18598 entraîne l'induction de réponses spécifiques cellulaires et humorales. Les cellules T produisent plusieurs cytokines de type Th1 et présentent une activité cytolytique. Dans des modèles murins d’efficacité, le MVATG18598, associé à un traitement antibiotique, réduit significativement la charge bactérienne dans les animaux infectés ainsi que le taux de rechute de la maladie après l’arrêt du traitement. Le deuxième objectif de cette thèse a été d'analyser l'impact des antituberculeux sur l'immunogénicité du vaccin MVATG18598. Nous avons montré que les antibiotiques de première ligne, et principalement l’isoniazide, diminuent la réponse immunitaire Th1 induite par le MVATG18598. De plus, nous avons démontré que la réponse humorale induite par le candidat vaccin est modifiée et s’oriente vers une augmentation du rapport IgG1/IgG2a en présence d’antibiotiques. En conclusion, nous montrons qu'un vaccin immunothérapeutique, tel que le MVATG18598, a la capacité de contribuer au contrôle de la tuberculose en augmentant l'efficacité des traitements antituberculeux. De plus, nos résultats indiquent que les antibiotiques modulent la réponse immunitaire induite par le vaccin, données devant être prises en compte lors du développement des futures stratégies immunothérapeutique

TLR2 engagement on CD8 T cells enables generation of functional memory cells in response to a suboptimal TCR signal.

International audienceTLR are involved in the detection of microbial infection as well as endogenous ligands that signal tissue and cell damage in mammals. This recognition plays an essential role in innate immune response and the initiation of adaptive immune response. We have previously shown that murine CD8 T cells express TLR2, and that costimulation of Ag-activated CD8 T cells with TLR2 ligands enhances their proliferation, survival, and effector functions. We also demonstrated that TLR2 engagement on CD8 T cells significantly reduces their need for costimulatory signals delivered by APC. We show in this study that TLR2 engagement on CD8 T cells lowers the Ag concentration required for optimal activation, and converts a partial activation into a productive process leading to a significant expansion of cells. Using altered peptide ligands, we demonstrate that TLR2 engagement increases CD8 T cell activation and enables the generation of functional memory cells in response to a low TCR signal. This increased activation is associated with an augmented activation of the PI3K. Taken together, our results demonstrate that TLR2 engagement on CD8 T cells lowers their activation threshold for TCR signal strength and enables efficient memory cell generation in response to a weak TCR signal

Intravenous injection of a novel viral immunotherapy encoding human interleukin-7 in nonhuman primates is safe and increases absolute lymphocyte count

Persistence of an immunosuppression, affecting both the innate and adaptive arms of the immune system, plays a role in sepsis patients’ morbidity and late mortality pointing to the need for broad and effective immune interventions. MVA-hIL-7-Fc is a non-replicative recombinant Modified Vaccinia virus Ankara encoding the human interleukin-7 fused to human IgG2 Fc fragment. We have shown in murine sepsis models the capacity of this new virotherapy to stimulate both arms of the immune system and increase survival. Herein, an exploratory study in nonhuman primates was performed following a single intravenous injection of the MVA-hIL-7-Fc used at the clinical dose to assess its safety and biological activities. Four cynomolgus macaques were followed for 3 weeks post-injection (p.i), without observed acute adverse reactions. Circulating hIL-7-Fc was detected during the first 3–5 days p.i with a detection peaking at 12 h p.i. IL-7 receptor engagement and downstream signal transduction were detected in T cells demonstrating functionality of the expressed IL-7. Expansion of blood lymphocytes, mainly CD4 and CD8 naïve and central memory T cells, was observed on day 7 p.i. together with a transient increase of Ki67 expression on T lymphocytes. In addition, we observed an increase in circulating B and NK cells as well as monocytes were albeit with different kinetics and levels. This study indicates that a vectorized IL-7-Fc, injected by intravenous route at a relevant clinical dose in a large animal model, is active without adverse reactions supporting the clinical development of this novel virotherapy for treatment of sepsis patients

IL-7 producing immunotherapy improves ex vivo T cell functions of immunosenescent patients, especially post hip fracture

Following acute stress such as trauma or sepsis, most of critically ill elderly patients become immunosuppressed and susceptible to secondary infections and enhanced mortality. We have developed a virus-based immunotherapy encoding human interleukin-7 (hIL-7) aiming at restoring both innate an adaptative immune homeostasis in these patients. We assessed the impact of this encoded hIL-7 on the ex vivo immune functions of T cells from PBMC of immunosenescent patients with or without hip fracture. T-cell ex vivo phenotyping was characterized in terms of senescence (CD57), IL-7 receptor (CD127) expression, and T cell differentiation profile. Then, post stimulation, activation status, and functionality (STAT5/STAT1 phosphorylation and T cell proliferation assays) were evaluated by flow cytometry. Our data show that T cells from both groups display immunosenescence features, express CD127 and are activated after stimulation by virotherapy-produced hIL-7-Fc. Interestingly, hip fracture patients exhibit a unique functional ability: An important T cell proliferation occurred compared to controls following stimulation with hIL-7-Fc. In addition, stimulation led to an increased naïve T cell as well as a decreased effector memory T cell proportions compared to controls. This preliminary study indicates that the produced hIL-7-Fc is well recognized by T cells and initiates IL-7 signaling through STAT5 and STAT1 phosphorylation. This signaling efficiently leads to T cell proliferation and activation and enables a T cell “rejuvenation.” These results are in favor of the clinical development of the hIL-7-Fc expressing virotherapy to restore or induce immune T cell responses in immunosenescent hip fracture patients

Characterization of a CD44/CD122int memory CD8 T cell subset generated under sterile inflammatory conditions.

International audienceMost memory CD8 T cell subsets that have been hitherto defined are generated in response to infectious pathogens. In this study, we have characterized the CD8 T cells that survive priming conditions, devoid of pathogen-derived danger signals. In both a TCR-transgenic model and a model of contact hypersensitivity, we show that the priming of naive CD8 T cells under sterile inflammatory conditions generates memory. The corresponding memory CD8 T cells can be identified by their intermediate expression levels of CD44 and CD122. We also show that CD44/122(int) memory CD8 T cells spontaneously develop in wild type mice and that they display intermediate levels of several other memory traits including functional (IFN-gamma secretion capacity, CCL5 messenger stores), phenotypic, and molecular (T-bet and eomesodermin expression levels) features. We finally show that they correspond to an early differentiation stage and can further differentiate in CD44/122(high) memory T cells. Altogether, our results identify a new memory CD8 T cell subset that is generated under sterile inflammatory conditions and involved in the recall contact hypersensitivity reactions that are responsible for allergic contact dermatitis