Project description:The emerging alphavirus chikungunya virus (CHIKV) has infected millions of people. However, the factors modulating disease outcome remain poorly understood. We show that depletion of the gut microbiota in oral antibiotic-treated or germ-free mice leads to greater CHIKV infection and spread within one day of virus inoculation. Perturbation of the gut microbiota alters TLR7-MyD88 signaling in plasmacytoid dendritic cells (pDCs) and blunts systemic production of type I interferon (IFN). Consequently, circulating monocytes express fewer IFN-stimulated genes and become permissive for CHIKV infection. Reconstitution with a single commensal bacterial species, Clostridium scindens, or its derived metabolite, the bile acid deoxycholic acid, can restore pDC- and MyD88-dependent type I IFN responses to restrict systemic CHIKV infection and transmission back to vector mosquitoes. Thus, commensal gut bacteria modulate antiviral immunity and levels of circulating alphaviruses within hours of infection through a bile acid-pDC-IFN signaling axis, which affects virus dissemination and potentially, epidemic spread 3 biological replicates were processed per time point and group

Project description:Plasmacytoid dendritic cells (pDC) are the major source of type I interferons (IFN-I) during viral infections, in response to triggering of endosomal Toll Like Receptors (TLR) 7 or 9 by viral single-stranded RNA or unmethylated CpG DNA, respectively. IFN-I production in pDC occurs in specialized endosomes encompassing preformed signaling complexes of TLR7 or 9 with their adaptor molecule MyD88 and the transcription factor interferon regulatory factor 7 (IRF7). The triggering of TLR leads to IRF7 phosphorylation, nuclear translocation and binding to the promoters of the genes encoding IFN-I to initiate their transcription. pDC express uniquely high levels of IRF7 at steady state and this expression is further enhanced by positive IFN-I feedback signaling during viral infections. However, the specific cell-intrinsic roles of MyD88 versus IFN-I signaling in pDC responses to a viral infection have not been rigorously dissected. To achieve this aim, we generated mixed bone marrow chimera mice (MBMC) allowing to rigorously compare the gene expression profiles of WT versus Ifnar1-KO or MyD88-KO pDC isolated from the same animals at steady state or after infection with the mouse cytomegalovirus (MCMV). Our results indicate that, in vivo during MCMV infection, pDC undergo a major transcriptional reprogramming, under combined instruction of IFN-I, IFN-γ and direct TLR triggering. However, these different stimuli drive specific, largely distinct, gene expression programs. We rigorously determined which gene modules require cell-intrinsic IFN-I signaling for their induction in pDC during a physiological viral infection in vivo. We delineated non-redundant versus shared versus antagonistic responses with IFN-γ. We demonstrated that cell-intrinsic IFN-I responsiveness is dispensable for induction of the expression of all IFN-I/III genes and many cytokines or chemokines in pDC during MCMV infection, contrary to MyD88 signaling.

Project description:Plasmacytoid dendritic cells (pDC) are the major source of type I IFN (IFN-I) in vivo during Murine Cytomegalovirus (MCMV) infection. This response requires pDC-intrinsic MyD88-dependent signaling by Toll Like Receptors 7/9. Provided that they express appropriate recognition receptors such as Ly49H, Natural Killer (NK) cells can directly sense and kill MCMV-infected cells. While MyD88- and Ly49H-dependent responses can contribute to MCMV control, the objective is to understand the relative importance of these 3 mechanisms. In order to decipher the relative impact of MyD88- and Ly49H-dependent mechanisms during MCMV infection, we performed a genome-wide expression analysis on total spleen of Ly49H-/-MyD88+/+, Ly49H-/-MyD88-/-, Ly49H+/+MyD88+/+ and Ly49H+/+MyD88-/- BALB/c mice at different time points after MCMV infection (d0, d1,5, d2, d3 and d6).

Project description:Chikungunya virus (CHIKV) infection has been associated with severe cardiac manifestations. However, how CHIKV infection leads to heart disease remains unknown. Here, using C57BL/6 mice we show that cardiac fibroblasts are the main target of CHIKV infection in the heart, and that cardiac tissue infection induces activation of the type I interferon (IFN-I) pathway in both infected and non-infected cardiac cells. The loss of IFN-I signaling results in increased CHIKV infection, virus spreading, and apoptosis in cardiac tissue. Importantly, signaling through the mitochondrial antiviral-signaling protein (MAVS) is essential for efficient CHIKV clearance from the heart. Indeed, persistent infection in cardiac tissue of MAVS-deficient mice leads to cardiac damage characterized by focal myocarditis and major vessel vasculitis. This study provides mechanistic insight on how CHIKV can lead to cardiac damage, underscoring the importance of monitoring cardiac function in patients with CHIKV infections.

Project description:Plasmacytoid dendritic cells (pDC) are the major source of type I IFN (IFN-I) in vivo during Murine Cytomegalovirus (MCMV) infection. This response requires pDC-intrinsic MyD88-dependent signaling by Toll Like Receptors 7/9. Provided that they express appropriate recognition receptors such as Ly49H, Natural Killer (NK) cells can directly sense and kill MCMV-infected cells. While MyD88- and Ly49H-dependent responses can contribute to MCMV control, the objective is to understand the relative importance of these 3 mechanisms. In order to decipher the relative impact of MyD88- and Ly49H-dependent mechanisms during MCMV infection, we performed a genome-wide expression analysis on total spleen of Ly49H-/-MyD88+/+, Ly49H-/-MyD88-/-, Ly49H+/+MyD88+/+ and Ly49H+/+MyD88-/- BALB/c mice at different time points after MCMV infection (d0, d1,5, d2, d3 and d6). This study includes data from the spleen BALB/c mice, under steady-state or MCMV condition at different time points. 2 to 5 mice for each mouse strain for each time point were used, and were hybridized on 5 separate batches of gene chips.

Project description:The purpose of this study is to compare the gene profiles of chikungunya virus (CHIKV) capsid transfected and CHIKV infected Huh7 cells to identify the genes differentially expressed in the presence of the capsid protein during CHIKV infection

Project description:Chikungunya virus (CHIKV) is a mosquito-borne virus that causes acute, subacute, and chronic human diseases and can cause neurological complications and death. Here, we combined epidemiological, virological, histopathological, cytokine, molecular dynamics, metabolomics, proteomics, and genomic analyses to investigate viral and pathophysiologic factors that contribute to deaths caused by chikungunya (CHIK). Our results indicate that CHIK-deaths presented multiple organs infection, central nervous system damage, and exhibited significantly elevated serum levels of pro-inflammatory cytokines and chemokines compared to survivors. The histopathology, metabolite, and proteomic signatures of CHIK-deaths revealed hemodynamic disorders and dysregulated immune system response. CHIKV East-Central-South-African lineage caused fatal and survivor cases, and CHIKV crosses the blood–brain barrier without tight junction alterations. IFN-λ3 was highly expressed in fatal cases but did not present a direct antiviral effect on CHIKV replication in vitro. In summary, our results reveal insights to improve understanding of CHIK pathogenesis, especially the pathophysiology of fatal infections.

Project description:Plasmacytoid dendritic cells (pDCs) are key components of the innate immune response that are capable of synthesizing and rapidly releasing vast amounts of type I interferons (IFNs), particularly IFN-alpha. Here we investigated whether pDCs, often regarded as a mere source of IFN, discriminate between various functionally discrete stimuli and to what extent this reflects differences in pDC responses other than IFN-alpha release. To examine the ability of pDCs to differentially respond to various doses of intact and infectious HIV, hepatitis C virus, and H1N1 influenza virus, whole-genome gene expression analysis, enzyme-linked immunosorbent assays, and flow cytometry were used to investigate pDC responses at the transcriptional, protein, and cellular levels. Our data demonstrate that pDCs respond differentially to various viral stimuli with significant changes in gene expression, including those involved in pDC activation, migration, viral endocytosis, survival, or apoptosis. In some cases, the expression of these genes was induced even at levels comparable to that of IFN-alpha. Interestingly, we also found that depending on the viral entity and the viral titer used for stimulation, induction of IFN-alpha gene expression and the actual release of IFN-alpha are not necessarily temporally coordinated. In addition, our data suggest that high-titer influenza A (H1N1) virus infection can stimulate rapid pDC apoptosis.

Project description:IFN-I suppresses the number of pre-pDCs and pDC development after infection, and the mechanisms underlying these changes remain unclear. To address this problem, we investigated the chromatin landscapes of bone marrow DC progenitors from mice infected with lymphocytic choriomeningitis virus (LCMV) after IFN-I receptor blockade with neutralizing antibodies.

Project description:How viruses, such as the emerging mosquito-borne Chikungunya virus (CHIKV), express their genomes at high levels despite an enrichment in suboptimal codons remains a puzzling question. By integrating subcellular fractionation and transcriptome-wide analyses of translation in CHIKV-infected human cells, we demonstrate an unanticipated virus-induced reprogramming of the host translation machinery to favor translation of viral RNA over cellular genes featuring optimal codon usage. This reprogramming was specifically apparent at the endoplasmic reticulum (ER), the preferred translation compartment of CHIKV RNA, and it is mediated by the wobble uridine 34 tRNA modification enzyme KIAA1456 whose expression is enhanced upon viral infection. Since KIAA1456 itself is encoded by a CHIKV-like codon usage, infection triggers a positive feed-back loop that ensures efficient virus protein production. Our findings demonstrate an unprecedented interplay of viruses with the host tRNA epitranscriptome to favor viral protein expression.