Project description:Disease tolerance is an evolutionarily conserved host defence strategy that preserves tissue integrity and physiology without affecting pathogen load. Unlike host resistance, the mechanisms underlying disease tolerance remain poorly understood. In the present study, we investigated whether an adjuvant (β-glucan) can reprogram innate immunity to provide protection against Influenza A virus (IAV) infection. Here we observe that β-glucan treatment reduced the morbidity and mortality against IAV infection, independent of host resistance (viral load). Increased survival of β-glucan treated mice against IA V is associated with the accumulation of neutrophils via RoRgt+ T cells in the lung tissue. Using gain-and-loss-of-function approaches, we demonstrate that β- glucan reprogrammed neutrophils are essential for promoting disease tolerance, limiting pulmonary tissue damage, and enhancing survival against IAV infection. β-glucan treatment promotes granulopoiesis in a type 1 interferon-dependent manner that leads to the generation of a unique subset of neutrophils, which are less mature with higher mitochondrial mass utilizing mitochondrial oxidative (OXPHOS) metabolism. Collectively, our data indicate that β-glucan reprograms hematopoietic stem cells (HSCs) to generate neutrophils with a novel “regulatory” function, which is required for promoting disease tolerance and maintaining lung tissue integrity against viral infection.

Project description:An effective immune response to influenza A virus (IAV) requires two arms: host resistance, which restricts viral replication, and disease tolerance that limits tissue damage caused by the immune response to IAV. Interestingly, fatal influenza infections are more often associated with dysregulated inflammation, rather than an inability to control viral replication, highlighting the importance of mechanisms involved in disease tolerance to IAV. Here, we show that cyclophilin D (CypD), a mitochondrial protein known to regulate cell death and cytokine production, protects against IAV infection through disease tolerance. Mice deficient in CypD (CypD-/-) exhibit enhanced susceptibility to IAV infection, despite comparable myeloid immune responses and intact antiviral immunity. Instead, CypD-/- susceptibility was due to pulmonary tissue damage, caused by a lack of the cytokine IL-22 that protects the lung epithelium. We found the necessary source of IL-22 following IAV infection to be conventional natural killer (NK) cells that failed to reach the airways of infected CypD-deficient mice, as a result of dysregulated lymphopoiesis in the bone marrow. Importantly, following infection, a single administration of recombinant IL-22 in the airways abrogated pulmonary damage and rescued CypD-/- mice. Thus, the CypD/IL-22/NK cell axis is critical in immunity to IAV by promoting disease tolerance, limiting lung tissue damage and maintaining pulmonary function.

Project description:Neutrophils are essential cells of host innate immunity. Although the role of neutrophils in defense against bacterial and fungal infections is well characterized, there is relative paucity of information about their role against viral infections. Influenza A virus (IAV) infection can be associated with secondary bacterial co-infection, and it has long been posited that the ability of IAV to alter normal neutrophil function predisposes individuals to secondary bacterial infections. To better understand this phenomenon, we evaluated the interaction of pandemic or seasonal H1N1 IAV with human neutrophils isolated from healthy subjects. These viruses were ingested by human neutrophils and elicited changes in neutrophil gene expression that are consistent with an interferon-mediated immune response. Viability of neutrophils following co-culture with either pandemic and seasonal H1N1 IAV was similar for up to 18 h of culture. Notably, neutrophil exposure to seasonal IAV (but not pandemic IAV) primed these leukocytes for enhanced functions, including production of reactive oxygen species and bactericidal activity. Taken together, our results are at variance with the universal idea that IAV impairs neutrophil function directly to predispose individuals to secondary bacterial infections. Rather, we suggest some strains of IAV prime neutrophils for enhanced bacterial clearance.

Project description:When challenged with an invading pathogen, host defense mechanisms are engaged to eliminate the pathogen (resistance) and limit tissue damage that results from host-pathogen interactions (disease tolerance). We identified Arhgdia as a driver of the molecular disease-tolerance response in epithelial cells. The effect of Arhgdia on disease tolerance and resistance was evaluated at early stages of influenza A virus (IAV) infection. Our observations indicates that Arhgdia has an effect on disease tolerance during IAV infection.

Project description:Influenza A virus (IAV) infection is a global respiratory disease, which annually leads to 3-5 million cases of severe illness, resulting in 290,000-650,000 deaths. Additionally, during the past century, four global IAV pandemics have claimed millions of human lives. The epithelial lining of the trachea plays a vital role during IAV infection, both as point of viral entry and replication as well as in the antiviral immune response. Tracheal tissue is generally inaccessible from human patients, which makes animal models crucial for the study of the tracheal host immune response. In this study, pigs were inoculated with swine- or human-adapted H1N1 IAV to gain insight into how host adaptation of IAV shapes the innate immune response during infection. In-depth multi-omics analysis (global proteomics and RNA sequencing) of the host response in upper and lower tracheal tissue was conducted, and results were validated by microfluidic qPCR. Additionally, a subset of samples was selected for histopathological examination. A classical innate antiviral immune response was induced in both upper and lower trachea after infection with either swine- or human-adapted IAV with upregulation of genes and higher abundance of proteins associated with viral infection and recognition, accompanied by a significant induction of interferon stimulated genes with corresponding higher proteins concentrations. Infection with the swine-adapted virus induced a much stronger immune response compared to infection with a human-adapted IAV strain in the lower trachea, which could be a consequence of a higher viral load and a higher degree of inflammation. Central components of the JAK-STAT pathway, apoptosis, pyrimidine metabolism, and the cytoskeleton were significantly altered depending on infection with swine- or human-adapted virus and might be relevant mechanisms in relation to antiviral immunity against putative zoonotic IAV. Based on our findings, we hypothesize that during host adaptation, IAV evolve to modulate important host cell elements to favor viral infectivity and replication.

Project description:Influenza A virus (IAV) infection is a global respiratory disease, which annually leads to 3-5 million cases of severe illness, resulting in 290,000-650,000 deaths. Additionally, during the past century, four global IAV pandemics have claimed millions of human lives. The epithelial lining of the trachea plays a vital role during IAV infection, both as point of viral entry and replication as well as in the antiviral immune response. Tracheal tissue is generally inaccessible from human patients, which makes animal models crucial for the study of the tracheal host immune response. In this study, pigs were inoculated with swine- or human-adapted H1N1 IAV to gain insight into how host adaptation of IAV shapes the innate immune response during infection. In-depth multi-omics analysis (global proteomics and RNA sequencing) of the host response in upper and lower tracheal tissue was conducted, and results were validated by microfluidic qPCR. Additionally, a subset of samples was selected for histopathological examination. A classical innate antiviral immune response was induced in both upper and lower trachea after infection with either swine- or human-adapted IAV with upregulation of genes and higher abundance of proteins associated with viral infection and recognition, accompanied by a significant induction of interferon stimulated genes with corresponding higher proteins concentrations. Infection with the swine-adapted virus induced a much stronger immune response compared to infection with a human-adapted IAV strain in the lower trachea, which could be a consequence of a higher viral load and a higher degree of inflammation. Central components of the JAK-STAT pathway, apoptosis, pyrimidine metabolism, and the cytoskeleton were significantly altered depending on infection with swine- or human-adapted virus and might be relevant mechanisms in relation to antiviral immunity against putative zoonotic IAV. Based on our findings, we hypothesize that during host adaptation, IAV evolve to modulate important host cell elements to favor viral infectivity and replication.

Project description:The immune protection against invading pathogens is governed by pathogen elimination (‘resistance’) and by limitation of tissue damage that results from host-pathogen interactions (‘tolerance’). However, distinct molecular states of resistance and tolerance remain obscure. Here, we collected longitudinal lung transcriptomes and clinical phenotypes of disease severity during influenza A virus (IAV) infection across 39 genetically-distinct mouse strains (32 strains of time series data and additional 7 strains with selected time points). Using transcriptional diversity in this data, we uncovered two key programs that together describe the cellular states for resistance and tolerance. The identified programs offer an unprecedented comprehensive view on shared and distinct roles of resistance and tolerance for the regulation of immune defense – for instance, we identified an antagonistic regulation of resistance and tolerance on protein production. Importantly, the framework reveals that both inflammatory states and the healthy steady state are remarkably diverse in resistance and tolerance levels, with implications on disease severity: a baseline state (before infection) of high tolerance and low resistance results in increased severity of IAV infection. Overall, our work provides a framework for the study of resistance and tolerance that could aid in clinical diagnosis and disease management.

Project description:Lung neutrophils are causally associated with IAV-induced disease severity. Less is known about the repertoire of lethal IAV-associated neutrophil proteins or about how global changes in different neutrophil compartments are coordinated following lethal IAV infection. Here, we use semi-quantitative proteomics to characterize dynamic alterations in BM, blood and lung neutrophils at homeostasis or following a lethal IAV infection, with a secondary aim of identifying lung neutrophil-derived proteins which are selectively induced following IAV infection. Our findings identify bone marrow neutrophil maturation as the key site of anti-viral activity induction, with further upregulation or release of both anti-viral and antimicrobial effectors occurring following lung tissue infiltration.

Project description:Induction of trained immunity by beta-glucan has been shown to promote transcriptomic alterations in myeloid cells. Neutrophils are involved in the immune response against tumors and can promote or inhibit tumor growth. In this study, we performed RNA sequencing in TAN from mice in order to investigate the impact of trained immunity on the transcriptomic profile of neutrophils in the tumor setting.

Project description:Current therapeutic strategies against bacterial infections focus on reduction of pathogen load using antibiotics; however, stimulation of host tolerance to infection in the presence of pathogens might offer an alternative approach. We used computational transcriptomics and Xenopus laevis embryos to discover infection response pathways, identify potential tolerance inducer drugs, and validate their ability to induce broad tolerance. Xenopus exhibits natural tolerance to Acinetobacter baumanii, Klebsiella pneumoniae, Staphylococcus aureus, and Streptococcus pneumoniae bacteria, whereas Aeromonas hydrophila and Pseudomonas aeruginosa produce lethal infections. Transcriptional profiling led to definition of a 20-gene signature that discriminates between tolerant and susceptible states, as well as identification of a more active tolerance response to gram negative compared to gram positive bacteria. Gene pathways associated with active tolerance in Xenopus, including some involved in metal ion binding and hypoxia, were found to be conserved across species, including mammals, and administration of a metal chelator (deferoxamine) or a HIF-1 agonist (1,4-DPCA) in embryos infected with lethal A. hydrophila increased survival despite high pathogen load. These data demonstrate the value of combining the Xenopus embryo infection model with computational multi-omics analyses for mechanistic discovery and drug repurposing to induce host tolerance to bacterial infections.