Project description:Elevated infant fecal concentrations of bacterial-derived lipid 12,13-diHOME increases risk for atopy and asthma development in childhood, mechanistically how this lipid may contribute to disease susceptibility is unknown. Here we demonstrate macrophages exposed to 12,13-diHOME exhibit inflammatory IL-1highCD206low M1-like polarization, reduce bacterial phagocytic capacity. In co-culture assays, antigens in the presence of 12,13-diHOME further amplifies M1-like frequency, promotes CD20+CD38-IgD-CD27+ memory B cells expansion and IgE production. Epigenetic analyses indicates 12,13-diHOME exposure promotes DNA methylation, chromatin compaction, specifically diminishing access to interferon-stimulated response elements and transcription factor binding sites. In vivo, in murine airway allergic sensitization model, gut bacterial-derived 12,13-diHOME exacerbated both airway allergic inflammation and IL-1, IL-7, one-carbon metabolism and Toll-like receptor signaling. Our data suggests that 12,13-diHOME reprograms macrophage effector function, B-cell interactions and epigenetic modifications promoting phenotypes plausibly play a role in shaping early life microbiome development and innate immune dysfunction related to allergic sensitization in childhood.

Project description:Elevated infant fecal concentrations of bacterial-derived lipid 12,13-diHOME increases risk for atopy and asthma development in childhood, mechanistically how this lipid may contribute to disease susceptibility is unknown. Here we demonstrate macrophages exposed to 12,13-diHOME exhibit inflammatory IL-1highCD206low M1-like polarization, reduce bacterial phagocytic capacity. In co-culture assays, antigens in the presence of 12,13-diHOME further amplifies M1-like frequency, promotes CD20+CD38-IgD-CD27+ memory B cells expansion and IgE production. Epigenetic analyses indicates 12,13-diHOME exposure promotes DNA methylation, chromatin compaction, specifically diminishing access to interferon-stimulated response elements and transcription factor binding sites. In vivo, in murine airway allergic sensitization model, gut bacterial-derived 12,13-diHOME exacerbated both airway allergic inflammation and IL-1, IL-7, one-carbon metabolism and Toll-like receptor signaling. Our data suggests that 12,13-diHOME reprograms macrophage effector function, B-cell interactions and epigenetic modifications promoting phenotypes plausibly play a role in shaping early life microbiome development and innate immune dysfunction related to allergic sensitization in childhood.

Project description:We have demonstrated that allergic airway inflammation (induced by an ovalbumin sensitization and aerosol challenge protocol) decreases lung bacterial burden following lung infection with Klebsiella pneumoniae. The goals of this study are to indentify novel targets that are expressed during allergic airway inflammation in this model that contribute to enhanced lung bacterial immunity.

Project description:In the first decade of life, high-asthma risk urban children develop stable phenotypes of respiratory health versus disease that link early life environmental exposures to childhood allergic sensitization and asthma. Moreover, unique patterns of nasal gene expression demonstrate how specific molecular pathways underlie distinct respiratory phenotypes, including allergic and non-allergic asthma.

Project description:Allergic asthma is a chronic disease of the airways characterized by eosinophilic and neutrophilic inflammation. MYD88, the adaptor molecule for TLR and IL-1 family member signaling, is required for allergic sensitization through the airway in animal models of allergic asthma. We generated conditionally mutant mice separately lacking Myd88 in airway epithelial cells (ECs) or dendritic cells (DCs) to define the contribution of Myd88 expression in each of these cell types. To examine crosstalk from ECs to conventional (c)DCs in vivo, we examined transcriptional profiles from lung cDCs sorted at baseline or following 6h in vivo lung allergic sensitization through the airways from WT MyD88 fx/fx, SPC cre+ MyD88 fx/fx (EC-MYD88 KO), CD11c cre+ MyD88 fx/fx (DC-MYD88 KO), and full MyD88 KO mice. We observed specific transcriptional changes in cDCs that were cell-intrinsic as well as resulting from in vivo crosstalk from ECs. We also observed epigenetic changes in chromatin conformation in cDCs by ATAC-seq (linked data set) as well as changes in immune-specific whole lung RNA, sorted EC RNA, sorted alveolar macrophage RNA, and sorted cDC by Nanostring nCounter Immunology Codeset Analysis (additional linked files).

Project description:Allergic asthma is a chronic disease of the airways characterized by eosinophilic and neutrophilic inflammation. MYD88, the adaptor molecule for TLR and IL-1 family member signaling, is required for allergic sensitization through the airway in animal models of allergic asthma. We generated conditionally mutant mice separately lacking Myd88 in airway epithelial cells (ECs) or dendritic cells (DCs) to define the contribution of Myd88 expression in each of these cell types. To examine crosstalk from ECs to conventional (c)DCs in vivo, we examined immune-specific transcriptional profiles from lung cDCs sorted following 6h in vivo lung allergic sensitization through the airways from WT MyD88 fx/fx, SPC cre+ MyD88 fx/fx (EC-MYD88 KO), CD11c cre+ MyD88 fx/fx (DC-MYD88 KO), and full MyD88 KO mice. We observed immune-specific transcriptional changes in cDCs that were cell-intrinsic as well as resulting from in vivo crosstalk from ECs. We also observed transcriptional (linked data set) and epigenetic changes in chromatin conformation in cDCs by ATAC-seq (linked data set) as well as changes in immune-specific whole lung RNA, sorted EC RNA, and sorted alveolar macrophage (AM) RNA by Nanostring nCounter Immunology Codeset Analysis (additional linked files).

Project description:Allergic asthma is a chronic disease of the airways characterized by eosinophilic and neutrophilic inflammation. MYD88, the adaptor molecule for TLR and IL-1 family member signaling, is required for allergic sensitization through the airway in animal models of allergic asthma. We generated conditionally mutant mice separately lacking Myd88 in airway epithelial cells (ECs) or dendritic cells (DCs) and alveolar macrophages (AMs) to define the contribution of Myd88 expression in each of these cell types. To examine crosstalk from ECs to AMs in vivo, we examined transcriptional profiles from lung AMs sorted following 6h in vivo lung allergic sensitization through the airways from WT MyD88 fx/fx, SPC cre+ MyD88 fx/fx (EC-MYD88 KO), CD11c cre+ MyD88 fx/fx (DC-MYD88 KO), and full MyD88 KO mice. We observed immune-specific transcriptional changes in AMs that were cell-intrinsic as well as resulting from in vivo crosstalk from ECs. We also observed transcriptional (linked data set) and epigenetic changes in chromatin conformation in cDCs by ATAC-seq (linked data set) as well as changes in immune-specific whole lung RNA, sorted EC RNA, and sorted cDC RNA by Nanostring nCounter Immunology Codeset Analysis (additional linked files).

Project description:Allergic asthma is a chronic disease of the airways characterized by eosinophilic and neutrophilic inflammation. MYD88, the adaptor molecule for TLR and IL-1 family member signaling, is required for allergic sensitization through the airway in animal models of allergic asthma. We generated conditionally mutant mice separately lacking Myd88 in airway epithelial cells (ECs) or dendritic cells (DCs) and alveolar macrophages (AMs) to define the contribution of Myd88 expression in each of these cell types. To examine crosstalk between ECs and CD11c-expressing cells in vivo, we examined transcriptional profiles from whole lung RNA at baseline, or following 2h or 6h in vivo lung allergic sensitization through the airways from WT MyD88 fx/fx, SPC cre+ MyD88 fx/fx (EC-MYD88 KO), CD11c cre+ MyD88 fx/fx (DC-MYD88 KO), and full MyD88 KO mice. We observed immune-specific transcriptional changes in whole lung RNA that were altered based on EC- or CD11c-specific deletion of MYD88. We also observed transcriptional (linked data set) and epigenetic changes in chromatin conformation in cDCs by ATAC-seq (linked data set) as well as changes in immune-specific sorted EC RNA, sorted AM RNA, and sorted cDC RNA by Nanostring nCounter Immunology Codeset Analysis (additional linked files).

Project description:Allergic asthma is a chronic disease of the airways characterized by eosinophilic and neutrophilic inflammation. MYD88, the adaptor molecule for TLR and IL-1 family member signaling, is required for allergic sensitization through the airway in animal models of allergic asthma. We generated conditionally mutant mice separately lacking Myd88 in airway epithelial cells (ECs) or dendritic cells (DCs) and alveolar macrophages (AMs) to define the contribution of Myd88 expression in each of these cell types. To examine crosstalk from CD11c-expressing cells to ECs in vivo, we examined immune-specific transcriptional profiles from lung ECs sorted following 2h in vivo lung allergic sensitization through the airways from WT MyD88 fx/fx, SPC cre+ MyD88 fx/fx (EC-MYD88 KO), CD11c cre+ MyD88 fx/fx (DC-MYD88 KO), and full MyD88 KO mice. We observed immune-specific transcriptional changes in ECs that were cell-intrinsic but none resulting from in vivo crosstalk from CD11c-expressing cells. We also observed transcriptional (linked data set) and epigenetic changes in chromatin conformation in cDCs by ATAC-seq (linked data set) as well as changes in immune-specific whole lung RNA, sorted AM RNA, and sorted cDC RNA by Nanostring nCounter Immunology Codeset Analysis (additional linked files).

Project description:Allergic asthma is a chronic disease of the airways characterized by eosinophilic and neutrophilic inflammation. MYD88, the adaptor molecule for TLR and IL-1 family member signaling, is required for allergic sensitization through the airway in animal models of allergic asthma. We generated conditionally mutant mice separately lacking Myd88 in airway epithelial cells (ECs) or dendritic cells (DCs) to define the contribution of Myd88 expression in each of these cell types. To examine epigenetic crosstalk from ECs to conventional (c)DCs in vivo, we examined ATAC-seq data from lung cDCs sorted at baseline or following 6h in vivo lung allergic sensitization through the airways from WT MyD88 fx/fx, SPC cre+ MyD88 fx/fx (EC-MYD88 KO), CD11c cre+ MyD88 fx/fx (DC-MYD88 KO), and full MyD88 KO mice. We observed specific epigenetic changes in chromatin conformation in cDCs that were cell-intrinsic as well as resulting from in vivo crosstalk from ECs. We also observed transcriptional changes in cDCs by Affymetrix Whole Transcriptome Array (linked data set) as well as changes in immune-specific whole lung RNA, sorted EC RNA, sorted alveolar macrophage RNA, and sorted cDC RNA changes by Nanostring nCounter Immunology Codeset Analysis (additional linked files).