Project description:Lower respiratory tract infections remain a leading cause of death worldwide. The increasing prevalence of antibiotic-resistant respiratory pathogens has been a key driver of efforts to develop host-directed therapies that protect patients against pneumonia. Our laboratory has previously reported discovery of an immunostimulatory therapeutic comprised of a synthetic diacetylated lipopeptide, Pam2CSK4 (Pam2), and a class C CpG oligodeoxynucleotide, ODN M362 (ODN). When delivered by inhalation, this dyad protects synergistically against pneumonias caused by Gram-positive and -negative bacteria, seasonal and pandemic viruses, and multiple fungi. Protection is achieved by manipulating the immune defense response from lung epithelial cells. Here, we dissect the lung epithelial transcriptional response to explain the observed synergistic signaling, using RNA-seq and dual transcription factor ChIP-seq. We find cooperation of RelA and cJun following Pam2+ODN treatment that synergistically confers broad inducible resistance against respiratory pathogens. Specifically, transcription factor binding site (TFBS) analysis revealed that cJun occupancy at promoter regions of Pam2+ODN-induced genes facilitated increased RelA occupancy during differential expression, demonstrating cJUN-assisted loading of RelA as a key mechanism of the synergistic signaling events. Increased or decreased RelA occupancy at promoter sites dictated gene up- or down-regulation, respectively, while increased or decreased cJun occupancy at promoter sites directed synergistic or antagonistic gene expression patterns. Together, RelA and cJun work at promoter regions to control directionality and magnitude of gene expression after Pam2+ODN stimulation, rapidly reprograming the lung epithelial transcriptome to combat respiratory infections.

Project description:Lower respiratory tract infections remain a leading cause of death worldwide. The increasing prevalence of antibiotic-resistant respiratory pathogens has been a key driver of efforts to develop host-directed therapies that protect patients against pneumonia. Our laboratory has previously reported discovery of an immunostimulatory therapeutic comprised of a synthetic diacetylated lipopeptide, Pam2CSK4 (Pam2), and a class C CpG oligodeoxynucleotide, ODN M362 (ODN). When delivered by inhalation, this dyad protects synergistically against pneumonias caused by Gram-positive and -negative bacteria, seasonal and pandemic viruses, and multiple fungi. Protection is achieved by manipulating the immune defense response from lung epithelial cells. Here, we dissect the lung epithelial transcriptional response to explain the observed synergistic signaling, using RNA-seq and dual transcription factor ChIP-seq. We find cooperation of RelA and cJun following Pam2+ODN treatment that synergistically confers broad inducible resistance against respiratory pathogens. Specifically, transcription factor binding site (TFBS) analysis revealed that cJun occupancy at promoter regions of Pam2+ODN-induced genes facilitated increased RelA occupancy during differential expression, demonstrating cJUN-assisted loading of RelA as a key mechanism of the synergistic signaling events. Increased or decreased RelA occupancy at promoter sites dictated gene up- or down-regulation, respectively, while increased or decreased cJun occupancy at promoter sites directed synergistic or antagonistic gene expression patterns. Together, RelA and cJun work at promoter regions to control directionality and magnitude of gene expression after Pam2+ODN stimulation, rapidly reprograming the lung epithelial transcriptome to combat respiratory infections.

Project description:Lower respiratory tract infections remain a leading cause of death worldwide. The increasing prevalence of antibiotic-resistant respiratory pathogens has been a key driver of efforts to develop host-directed therapies that protect patients against pneumonia. Our laboratory has previously reported discovery of an immunostimulatory therapeutic comprised of a synthetic diacetylated lipopeptide, Pam2CSK4 (Pam2), and a class C CpG oligodeoxynucleotide, ODN M362 (ODN). When delivered by inhalation, this dyad protects synergistically against pneumonias caused by Gram-positive and -negative bacteria, seasonal and pandemic viruses, and multiple fungi. Protection is achieved by manipulating the immune defense response from lung epithelial cells. Here, we dissect the lung epithelial transcriptional response to explain the observed synergistic signaling, using RNA-seq and dual transcription factor ChIP-seq. We find cooperation of RelA and cJun following Pam2+ODN treatment that synergistically confers broad inducible resistance against respiratory pathogens. Specifically, transcription factor binding site (TFBS) analysis revealed that cJun occupancy at promoter regions of Pam2+ODN-induced genes facilitated increased RelA occupancy during differential expression, demonstrating cJUN-assisted loading of RelA as a key mechanism of the synergistic signaling events. Increased or decreased RelA occupancy at promoter sites dictated gene up- or down-regulation, respectively, while increased or decreased cJun occupancy at promoter sites directed synergistic or antagonistic gene expression patterns. Together, RelA and cJun work at promoter regions to control directionality and magnitude of gene expression after Pam2+ODN stimulation, rapidly reprograming the lung epithelial transcriptome to combat respiratory infections.

Project description:We conducted a comprehensive analysis of the proteome of mouse bone marrow dendritic cells (BMDCs) infected with MHV-A59. We characterized the global gene changes at the protein levels following viral infection, identifying ten genes involved in various anti-MHV biological processes.

Project description:Impaired type I interferon (IFN) responses are predictive of severe disease during pulmonary coronavirus infection. Insufficient IFN-responsiveness is associated with viremia and hypercytokinemia, however the resolution of IFN-dependent innate immune responses in the lungs remains limited. Here, we aimed to elucidate the early dynamics of antiviral immunity and define the IFN-dependent mechanisms limiting viral spread during pulmonary infection with the murine coronavirus A59 (M-CoV-A59), a beta-coronavirus. Combining high-resolution transcriptomic analysis and genetic attenuation of interferon signaling, we delineated IFN-dependent cell-intrinsic and population-based transcriptional changes that determined viral replication and inflammatory maturation, respectively.

Project description:Primary mouse peritoneal macrophages and bone marrow derived macrophages were isolated and infected with MHV-A59.

Project description:To investigate the transcriptome differences between wild-type and ZUP1 knock-out mice in liver when they were infected with MHV, we employed MHV-A59, a hepatic and neuronal tropic murine coronavirus, to infect wild-type and Zup1 knockout mice and colleted liver tissues after MHV infection to perform RNA- sequencing.

Project description:Impaired immunometabolic response in the elderly regulates inflammation-driven COVID-19 severity which confers the greatest risk of mortality. To investigate how aging compromises defense against COVID-19, we developed a model of natural murine beta coronavirus (mCoV) infection with mouse hepatitis virus strain A59 (mCoV-A59) that recapitulated majority of hallmarks of COVID-19. Aged mCoV-A59-infected mice have increased mortality and higher systemic inflammation in the heart, adipose tissue and hypothalamus, including neutrophilia and loss of γδ T cells in lungs. Ketogenic diet increases beta-hydroxybutyrate, expands tissue protective γδ T cells, deactivates the inflammasome and decreases pathogenic monocytes in lungs during aging. These data underscore the value of mCoV-A59 model to test mechanism and establishes harnessing of ketogenic immunometabolic checkpoint as potential treatment against COVID-19 in the elderly.

Project description:Impaired immunometabolic response in the elderly regulates inflammation-driven COVID-19 severity which confers the greatest risk of mortality. To investigate how aging compromises defense against COVID-19, we developed a model of natural murine beta coronavirus (mCoV) infection with mouse hepatitis virus strain A59 (mCoV-A59) that recapitulated majority of hallmarks of COVID-19. Aged mCoV-A59-infected mice have increased mortality and higher systemic inflammation in the heart, adipose tissue and hypothalamus, including neutrophilia and loss of γδ T cells in lungs. Ketogenic diet increases beta-hydroxybutyrate, expands tissue protective γδ T cells, deactivates the inflammasome and decreases pathogenic monocytes in lungs during aging. These data underscore the value of mCoV-A59 model to test mechanism and establishes harnessing of ketogenic immunometabolic checkpoint as potential treatment against COVID-19 in the elderly.

Project description:In the present study, we have investigated the effect of CpG Oligodeoxynucleotides (CpG-ODN) on the outcome of Plasmodium infection of the mosquito vectors Anopheles stephensi and Anopheles gambiae and on the modulation of mosquito immunity to Plasmodium. Anopheles mosquitoes inoculated with CpG-ODN showed significant reduction of Plasmodium infection rate and intensity. Microarrays were used to profile transcription of fat-body from CpG-ODN-treated mosquitoes. Mosquitoes were dissected 18h after ODN inoculation (immediately before feeding). Batches of 20 to 30 fat bodies (abdomen without midgut, ovaries and malpighian tubule]) were dissected in cold DEPC-treated phosphate-buffered saline (PBS) and processed for RNA preparation. Mosquitoes treated with CpG-ODNs are less susceptible to Plasmodium infection. Transcription profile of fat body indicates that protection was associated with coagulation/wound healing, while melanization appears to be depressed.