BMC Biology BMC Biology The toxoplasma-host cell junction is anchored to the cell cortex to sustain parasite invasive force

International audienceBackgroundThe public health threats imposed by toxoplasmosis worldwide and by malaria in sub-Saharan countries are directly associated with the capacity of their closely related causative agents Toxoplasma and Plasmodium, respectively to colonize and expand inside host cells. Therefore, deciphering how these two Apicomplexan protozoan parasites access their hosting cells has been highlighted as a high priority research with the relevant perspective of designing anti-invasive molecules to prevent diseases. Central to the mechanistic base of invasion for both genera is mechanical force, which is thought to be applied by the parasite at the interface between the two cells following assembly of a unique cell junction but this model lacks direct evidence and has been challenged by recent genetic and cell biology studies. In this work, using parasites expressing the fluorescent core component of this junction, we analyse characteristic features of the kinematics of penetration of more than 1000 invasion events.ResultsThe majority of invasion events occur with a typical forward rotational progression of the parasite through a static junction into a vacuole formed from the invaginating host cell plasma membrane, in which the parasite subsequently replicates. However, if parasites encounter resistance and if the junction is not strongly anchored to the host cell cortex, as when parasites do not secrete the toxofilin protein and therefore are unable to locally remodel the cortical actin cytoskeleton, the junction is capped backwards and travels retrogradely with the host cell membrane along the parasite surface as it is enclosed within a functional vacuole. Kinetic measurements of the invasive trajectories strongly support a similar parasite driven force in both static and capped junctions, both of which lead to successful invasion. However about 20% of toxofilin mutants fail to enter and eventually disengage from the host cell membrane while the secreted RON2 molecules are capped at the posterior pole before being cleaved and released in the medium. By contrast in cells characterized by low cortex tension and high cortical actin dynamics, junction capping and entry failure are drastically reduced.ConclusionThis kinematic analysis of pre-invasive and invasive T. gondii tachyzoite behaviors newly highlights that to invade cells, parasites need to engage their motor with the junction molecular complex where force is efficiently applied only upon proper anchorage to the host cell membrane and cortex

More rapid blood interferon α2 decline in fatal versus surviving COVID-19 patients

BackgroundThe clinical outcome of COVID-19 pneumonia is highly variable. Few biological predictive factors have been identified. Genetic and immunological studies suggest that type 1 interferons (IFN) are essential to control SARS-CoV-2 infection.ObjectiveTo study the link between change in blood IFN-α2 level and plasma SARS-Cov2 viral load over time and subsequent death in patients with severe and critical COVID-19.MethodsOne hundred and forty patients from the CORIMUNO-19 cohort hospitalized with severe or critical COVID-19 pneumonia, all requiring oxygen or ventilation, were prospectively studied. Blood IFN-α2 was evaluated using the Single Molecule Array technology. Anti-IFN-α2 auto-Abs were determined with a reporter luciferase activity. Plasma SARS-Cov2 viral load was measured using droplet digital PCR targeting the Nucleocapsid gene of the SARS-CoV-2 positive-strand RNA genome.ResultsAlthough the percentage of plasmacytoid dendritic cells was low, the blood IFN-α2 level was higher in patients than in healthy controls and was correlated to SARS-CoV-2 plasma viral load at entry. Neutralizing anti-IFN-α2 auto-antibodies were detected in 5% of patients, associated with a lower baseline level of blood IFN-α2. A longitudinal analysis found that a more rapid decline of blood IFN-α2 was observed in fatal versus surviving patients: mortality HR=3.15 (95% CI 1.14–8.66) in rapid versus slow decliners. Likewise, a high level of plasma SARS-CoV-2 RNA was associated with death risk in patients with severe COVID-19.ConclusionThese findings could suggest an interest in evaluating type 1 IFN treatment in patients with severe COVID-19 and type 1 IFN decline, eventually combined with anti-inflammatory drugs.Clinical trial registrationhttps://clinicaltrials.gov, identifiers NCT04324073, NCT04331808, NCT04341584

Dynamic of local and systemic cellular responses after vaccination in the skin

La vaccination est considérée comme l’un des plus grandes découvertes de l’histoire des maladies infectieuses, ayant permis le déclin et l’éradication de plusieurs pathogènes. Cependant, nous ignorons encore tous les mécanismes impliqués dans la protection contre les pathogènes. Cette méconnaissance est la cause de notre incapacité à formuler des nouveaux vaccins contre le VIH, la tuberculose, le paludisme et les pathogènes émergents. Récemment, on note des efforts pour induire une réponse cellulaire efficace après une vaccination, qui joue un rôle crucial dans la clairance des pathogènes.Cette thèse s’appuie sur un modèle de vaccin vivant atténue issu du virus de la vaccine : le MVA (Modified Vaccinia Ankara) et sur le modèle de primate non-humain. Nous avons caractérisé la réponse cellulaire après une immunisation intradermique suivant un schéma en prime-boost homologue, avec un boost à 2, suivi d’un boost à 9 mois. Le MVA a induit une infiltration massive de Lymphocytes T CD8 au niveau du site d’injection, 7 jours après l’immunisation. La réponse cellulaire systémique était modérée et ne reflétait pas l’amplitude de la réponse locale. Les injections du prime et du boost ont orienté la réponse cellulaire de façon différente, ce qui a mené à une importante induction de cellules T CD4 et CD8, persistantes, spécifiques de l’antigène et polyfonctionnelles après l’injection du boost à 9 mois.Cette étude souligne la différence entre les réponses systémiques et locales, démontrant l’importance de se focaliser sur la réponse tissulaire. Elle a également mis en lumière l’impact du schéma d’immunisation sur la qualité de la réponse cellulaire.Vaccination has been considered as one of the greatest discoveries in the history of infectious diseases by allowing pathogens decline or eradication. However, we still ignore all the mechanism that lead to protection and therefore, fail to elaborate new vaccines against HIV, tuberculosis, malaria and emergent pathogens. Recently, efforts have been made to elicit effective cellular response after vaccination, which is crucial for pathogen clearance.This thesis relied on live-attenuated vaccine model derived from the vaccinia virus: the MVA (Modified Vaccinia Ankara) and a non-human primate model. We characterized the cellular immune response triggered by a homologous prime-boost intradermal injection of MVA, with a 2 months and 9 months boost. The MVA induced a massive infiltration of CD8 T cells at the injection site 7 days post immunization. In comparison, the systemic cellular response was mild and did not reflect the magnitude of the local response. The prime and boost injections elicited distinct orientation of the systemic and local T cells, which led to an important induction of a persistent, antigen-specific and polyfunctional CD8 and CD4 T cell responses after the 9 months boost.This work emphasizes the difference between local and systemic response, demonstrating the importance of the focus on tissue immunity. It also highlights the impact of the immunization schedule on the quality of the cellular response

Dynamique des réponses lymphocytaires T locales et systémiques à l'injection d'un vaccin dans la peau

Vaccination has been considered as one of the greatest discoveries in the history of infectious diseases by allowing pathogens decline or eradication. However, we still ignore all the mechanism that lead to protection and therefore, fail to elaborate new vaccines against HIV, tuberculosis, malaria and emergent pathogens. Recently, efforts have been made to elicit effective cellular response after vaccination, which is crucial for pathogen clearance.This thesis relied on live-attenuated vaccine model derived from the vaccinia virus: the MVA (Modified Vaccinia Ankara) and a non-human primate model. We characterized the cellular immune response triggered by a homologous prime-boost intradermal injection of MVA, with a 2 months and 9 months boost. The MVA induced a massive infiltration of CD8 T cells at the injection site 7 days post immunization. In comparison, the systemic cellular response was mild and did not reflect the magnitude of the local response. The prime and boost injections elicited distinct orientation of the systemic and local T cells, which led to an important induction of a persistent, antigen-specific and polyfunctional CD8 and CD4 T cell responses after the 9 months boost.This work emphasizes the difference between local and systemic response, demonstrating the importance of the focus on tissue immunity. It also highlights the impact of the immunization schedule on the quality of the cellular response.La vaccination est considérée comme l’un des plus grandes découvertes de l’histoire des maladies infectieuses, ayant permis le déclin et l’éradication de plusieurs pathogènes. Cependant, nous ignorons encore tous les mécanismes impliqués dans la protection contre les pathogènes. Cette méconnaissance est la cause de notre incapacité à formuler des nouveaux vaccins contre le VIH, la tuberculose, le paludisme et les pathogènes émergents. Récemment, on note des efforts pour induire une réponse cellulaire efficace après une vaccination, qui joue un rôle crucial dans la clairance des pathogènes.Cette thèse s’appuie sur un modèle de vaccin vivant atténue issu du virus de la vaccine : le MVA (Modified Vaccinia Ankara) et sur le modèle de primate non-humain. Nous avons caractérisé la réponse cellulaire après une immunisation intradermique suivant un schéma en prime-boost homologue, avec un boost à 2, suivi d’un boost à 9 mois. Le MVA a induit une infiltration massive de Lymphocytes T CD8 au niveau du site d’injection, 7 jours après l’immunisation. La réponse cellulaire systémique était modérée et ne reflétait pas l’amplitude de la réponse locale. Les injections du prime et du boost ont orienté la réponse cellulaire de façon différente, ce qui a mené à une importante induction de cellules T CD4 et CD8, persistantes, spécifiques de l’antigène et polyfonctionnelles après l’injection du boost à 9 mois.Cette étude souligne la différence entre les réponses systémiques et locales, démontrant l’importance de se focaliser sur la réponse tissulaire. Elle a également mis en lumière l’impact du schéma d’immunisation sur la qualité de la réponse cellulaire

Optimize Prime/Boost Vaccine Strategies: Trained Immunity as a New Player in the Game

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Innate Molecular and Cellular Signature in the Skin Preceding Long-Lasting T Cell Responses After Electroporated DNA Vaccination

International audienceDNA vaccines delivered with electroporation (EP) have shown promising results in preclinical models and are evaluated in clinical trials. In this study, we aim to characterize early mechanisms occurring in the skin after intradermal injection and EP of the auxoGTUmultiSIV DNA vaccine in nonhuman primates. First, we show that EP acts as an adjuvant by enhancing local inflammation, notably via granulocytes, monocytes/macrophages, and CD1aint-expressing cell recruitment. EP also induced Langerhans cell maturation, illustrated by CD86, CD83, and HLA-DR upregulation and their migration out of the epidermis. Second, we demonstrate the crucial role of the DNA vaccine in soluble factors release, such as MCP-1 or IL-15. Transcriptomic analysis showed that EP played a major role in gene expression changes postvaccination. However, the DNA vaccine is required to strongly upregulate several genes involved in inflammatory responses (e.g., Saa4), cell migration (e.g., Ccl3, Ccl5, or Cxcl10), APC activation (e.g., Cd86), and IFN-inducible genes (e.g., Ifit3, Ifit5, Irf7, Isg15, orMx1), illustrating an antiviral response signature. Also, AIM-2, a cytosolic DNA sensor, appeared to be strongly upregulated only in the presence of the DNA vaccine and trends to positively correlate with several IFN-inducible genes, suggesting the potential role of AIM-2 in vaccine sensing and the subsequent innate response activation leading to strong adaptive T cell responses. Overall, these results demonstrate that a combined stimulation of the immune response, in which EP and the auxoGTUmultiSIV vaccine triggered different components of the innate immunity, led to strong and persistent cellular recall responses

Innate Molecular and Cellular Signature in the Skin Preceding Long-Lasting T Cell Responses after Electroporated DNA Vaccination

Abstract DNA vaccines delivered with electroporation (EP) have shown promising results in preclinical models and are evaluated in clinical trials. In this study, we aim to characterize early mechanisms occurring in the skin after intradermal injection and EP of the auxoGTUmultiSIV DNA vaccine in nonhuman primates. First, we show that EP acts as an adjuvant by enhancing local inflammation, notably via granulocytes, monocytes/macrophages, and CD1aint-expressing cell recruitment. EP also induced Langerhans cell maturation, illustrated by CD86, CD83, and HLA-DR upregulation and their migration out of the epidermis. Second, we demonstrate the crucial role of the DNA vaccine in soluble factors release, such as MCP-1 or IL-15. Transcriptomic analysis showed that EP played a major role in gene expression changes postvaccination. However, the DNA vaccine is required to strongly upregulate several genes involved in inflammatory responses (e.g., Saa4), cell migration (e.g., Ccl3, Ccl5, or Cxcl10), APC activation (e.g., Cd86), and IFN-inducible genes (e.g., Ifit3, Ifit5, Irf7, Isg15, orMx1), illustrating an antiviral response signature. Also, AIM-2, a cytosolic DNA sensor, appeared to be strongly upregulated only in the presence of the DNA vaccine and trends to positively correlate with several IFN-inducible genes, suggesting the potential role of AIM-2 in vaccine sensing and the subsequent innate response activation leading to strong adaptive T cell responses. Overall, these results demonstrate that a combined stimulation of the immune response, in which EP and the auxoGTUmultiSIV vaccine triggered different components of the innate immunity, led to strong and persistent cellular recall responses

Molecular and Cellular Dynamics in the Skin, the Lymph Nodes, and the Blood of the Immune Response to Intradermal Injection of Modified Vaccinia Ankara Vaccine

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The route of vaccine administration determines whether blood neutrophils undergo long-term phenotypic modifications

International audienceInnate immunity modulates adaptive immunity and defines the magnitude, quality, and longevity of antigen-specific T-and B-cell immune memory. Various vaccine and administration factors influence the immune response to vaccination, including the route of vaccine delivery. We studied the dynamics of innate cell responses in blood using a preclinical model of non-human primates immunized with a live attenuated vaccinia virus, a recombinant Modified vaccinia virus Ankara (MVA) expressing a gagpol-nef fusion of HIV-1, and mass cytometry. We previously showed that it induces a strong, early, and transient innate response, but also late phenotypic modifications of blood myeloid cells after two months when injected subcutaneously. Here, we show that the early innate effector cell responses and plasma inflammatory cytokine profiles differ between subcutaneous and intradermal vaccine injection. Additionally, we show that the intradermal administration fails to induce more highly activated/mature neutrophils long after immunization, in contrast to subcutaneous administration. Different batches of antibodies, staining protocols and generations of mass cytometers were used to generate the two datasets. Mass cytometry data were analyzed in parallel using the same analytical pipeline based on three successive clustering steps, including SPADE, and categorical heatmaps were compared using the Manhattan distance to measure the similarity between cell cluster phenotypes. Overall, we show that the vaccine per se is not sufficient for the late phenotypic modifications of innate myeloid cells, which are evocative of innate immune training. Its route of administration is also crucial, likely by influencing the early innate response, and systemic inflammation, and vaccine biodistribution