Project description:Human newborns exhibit increased vulnerability and risk of mortality from infection. Increased susceptibility to infection during the neonatal period reflects key differences in the innate and adaptive immune responses relative to those in adult cells. We have previously shown an increase in the pleiotropic immune suppressive cytokine, IL-27, in macrophages derived from human umbilical cord blood compared with those obtained from adult peripheral blood. Similar findings exist in the neonatal murine system, as well as elevated splenic transcripts and serum levels. Recently, we established a murine model of neonatal sepsis to explore the impact of early life IL-27 levels on the host response to infection. In this model, neonatal mice deficient in IL-27 signaling exhibit reduced mortality, increased weight gain, and better control of the bacterial burden with reduced systemic inflammation. These results suggest that there is a reprogramming of the host response in the presence of IL-27 signaling. To explore this hypothesis, we profiled the neonatal transcriptome of the spleen in the presence or absence of Escherichia coli-induced sepsis in wild-type (WT) and IL-27Rα-deficient mice. The spleen, a known site of infection, exhibits increased IL-27 expression and bacterial burdens in WT pups that were significantly lower in IL-27Rα KO pups during infection. We identified 549 genes that were differentially expressed in WT neonates in response to E. coli infection. The upregulated genes were associated with inflammation, cytokine signaling, and G protein coupled receptor ligand binding and signaling. The expression level of these genes generally failed to increase in IL-27Rα KO mice upon the E. coli infection. We observed similar changes in gene expression, aligned with changes in chromatin accessibility, for macrophages isolated from the spleens of control and infected neonates with or without IL-27Rα KO, supporting macrophages as an innate myeloid population contributing to the inflammatory profile in septic WT pups. Collectively, our findings highlight a less inflammatory environment in KO pups that is not expected given the anti-inflammatory/suppressive activity of IL-27. However, it is consistent with a lower bacterial burden. This suggests that improved bacterial clearance in the absence of IL-27 signaling does not require a heightened inflammatory state, and instead, there is a direct relationship between IL-27 signaling and bacterial killing. An improved response to infection that is not reliant upon heightened levels of inflammation offers new promise to the potential of antagonizing IL-27 as a host-directed therapy for neonates without concern for driving inflammatory responses that are pathological to host tissues.

Project description:Human newborns exhibit increased vulnerability and risk of mortality from infection. Increased susceptibility to infection during the neonatal period reflects key differences in the innate and adaptive immune responses relative to those in adult cells. We have previously shown an increase in the pleiotropic immune suppressive cytokine, IL-27, in macrophages derived from human umbilical cord blood compared with those obtained from adult peripheral blood. Similar findings exist in the neonatal murine system, as well as elevated splenic transcripts and serum levels. Recently, we established a murine model of neonatal sepsis to explore the impact of early life IL-27 levels on the host response to infection. In this model, neonatal mice deficient in IL-27 signaling exhibit reduced mortality, increased weight gain, and better control of the bacterial burden with reduced systemic inflammation. These results suggest that there is a reprogramming of the host response in the presence of IL-27 signaling. To explore this hypothesis, we profiled the neonatal transcriptome of the spleen in the presence or absence of Escherichia coli-induced sepsis in wild-type (WT) and IL-27Rα-deficient mice. The spleen, a known site of infection, exhibits increased IL-27 expression and bacterial burdens in WT pups that were significantly lower in IL-27Rα KO pups during infection. We identified 549 genes that were differentially expressed in WT neonates in response to E. coli infection. The upregulated genes were associated with inflammation, cytokine signaling, and G protein coupled receptor ligand binding and signaling. The expression level of these genes generally failed to increase in IL-27Rα KO mice upon the E. coli infection. We observed similar changes in gene expression, aligned with changes in chromatin accessibility, for macrophages isolated from the spleens of control and infected neonates with or without IL-27Rα KO, supporting macrophages as an innate myeloid population contributing to the inflammatory profile in septic WT pups. Collectively, our findings highlight a less inflammatory environment in KO pups that is not expected given the anti-inflammatory/suppressive activity of IL-27. However, it is consistent with a lower bacterial burden. This suggests that improved bacterial clearance in the absence of IL-27 signaling does not require a heightened inflammatory state, and instead, there is a direct relationship between IL-27 signaling and bacterial killing. An improved response to infection that is not reliant upon heightened levels of inflammation offers new promise to the potential of antagonizing IL-27 as a host-directed therapy for neonates without concern for driving inflammatory responses that are pathological to host tissues.

Project description:Human neonates are predisposed to an increased risk of mortality from infection due to fundamental differences in the framework of innate and adaptive immune responses relative to those in the adult population. As one key difference from neonates, an increase in the immunosuppressive cytokine, IL-27, is responsible for poor outcomes in a murine neonatal model of bacterial sepsis. In our model, the absence of IL-27 signaling during infection is associated with improved maintenance of body mass, increased bacterial clearance with reduced systemic inflammation, and decreased mortality rates that correlate to preservation of glucose homeostasis and insulin production. To further elucidate the mechanisms associated with IL-27 signaling and metabolic fitness, we analyzed global transcriptomes from spleen, liver, pancreas, and hindlimb muscle during Escherichia coli-induced sepsis in wild-type (WT) and IL-27Rα-deficient (KO) mice. Metabolically important tissues such as the liver, pancreas, and hindlimb muscle exhibit a shift in differential gene expression of pathways involved in oxidative phosphorylation, glycolysis, gluconeogenesis, lipid metabolism, and fatty acid beta oxidation. The hindlimb muscle of KO pups demonstrated a significant reduction in all these pathways during infection. The KO liver showed a significant down-regulation in gluconeogenesis and glycolytic pathways. Collectively, these findings suggest a positive influence of IL-27 on the metabolic profile during early life infection. This is an important consideration for antagonization of IL-27 as a potential host-directed therapeutic opportunity and our findings point to an overall improvement in infectious disease parameters and metabolic fitness.

Project description:Tuberculosis (TB) is a serious public health concern in many regions of the world and the only approved vaccine to prevent TB is the live-attenuated BCG vaccine. Despite being widely used, the BCG vaccine fails to prevent pulmonary TB in adults. The BCG vaccine is administered during the neonatal period when levels of the immunosuppressive cytokine interleukin (IL)-27 are elevated, and previous studies have demonstrated that the source of IL-27 can impact downstream immune responses. We therefore sought to characterize the specific subpopulations of myeloid cells that produce IL-27 following BCG vaccination. To investigate this, we administered the BCG vaccine to neonatal IL-27p28eGFP mice that report IL-27 production. Our studies demonstrated that BCG vaccination steadily increased IL-27 production throughout the weeks post-vaccination. We also showed that a predominantly CD11b+ F4/80+population of IL-27 producers increased MHC class II expression following BCG vaccination in both the spleen and the lung. However, producers of IL-27 in these tissues differ, with a population of CD11c+ MHC II+ cells emerging in the spleen and a subset of Ly6G/C+ MHC II+ emerging in the lung. 10x scMultiome analysis further validated the increase in MHC class II expression and demonstrated improved antigen presentation functionality following vaccination. The sequencing analysis also revealed subpopulations of IL-27 producers with immunosuppressive functions such as a population of macrophages with increased Mrc1 expression post-vaccination. Our findings suggest that IL-27 producers are a heterogenous population of myeloid cells that impact the development of protective immune responses induced by the BCG vaccine.

Project description:Regulatory T (Treg) cells are instrumental in establishing immunological tolerance. However, the precise effector mechanisms by which Treg cells control a specific type of immune response in a given tissue remains unresolved. By simultaneously studying Treg cells from different tissue origins under systemic autoimmunity, here we show that IL-27 is specifically produced by intestinal Treg cells to regulate Th17 immunity. Selectively increased intestinal Th17 responses in mice with Treg cell-specific IL-27 ablation led to exacerbated intestinal inflammation and colitis-associated cancer, but also helped protect against enteric bacterial infection. Furthermore, single-cell transcriptomic analysis has identified a CD83+TCF1+ Treg cell subset that is distinct from previously characterized intestinal Treg cell populations as the main IL-27 producers. Collectively, our study uncovers a novel Treg cell suppression mechanism crucial for controlling a specific type of immune response in a particular tissue, and provides further mechanistic insights into tissue-specific Treg cell-mediated immune regulation.

Project description:Regulatory T (Treg) cells are instrumental in establishing immunological tolerance. However, the precise effector mechanisms by which Treg cells control a specific type of immune response in a given tissue remains unresolved. By simultaneously studying Treg cells from different tissue origins under systemic autoimmunity, here we show that IL-27 is specifically produced by intestinal Treg cells to regulate Th17 immunity. Selectively increased intestinal Th17 responses in mice with Treg cell-specific IL-27 ablation led to exacerbated intestinal inflammation and colitis-associated cancer, but also helped protect against enteric bacterial infection. Furthermore, single-cell transcriptomic analysis has identified a CD83+TCF1+ Treg cell subset that is distinct from previously characterized intestinal Treg cell populations as the main IL-27 producers. Collectively, our study uncovers a novel Treg cell suppression mechanism crucial for controlling a specific type of immune response in a particular tissue, and provides further mechanistic insights into tissue-specific Treg cell-mediated immune regulation.

Project description:Regulatory T cells (Treg cells) are instrumental in establishing immunological tolerance. However, the precise effector mechanisms by which Treg cells control a specific type of immune response in a given tissue remains unresolved. By simultaneously studying Treg cells from different tissue origins under systemic autoimmunity, in the present study we show that interleukin (IL)-27 is specifically produced by intestinal Treg cells to regulate helper T17 cell (TH17 cell) immunity. Selectively increased intestinal TH17 cell responses in mice with Treg cell-specific IL-27 ablation led to exacerbated intestinal inflammation and colitis-associated cancer, but also helped protect against enteric bacterial infection. Furthermore, single-cell transcriptomic analysis has identified a CD83+CD62Llo Treg cell subset that is distinct from previously characterized intestinal Treg cell populations as the main IL-27 producers. Collectively, our study uncovers a new Treg cell suppression mechanism crucial for controlling a specific type of immune response in a particular tissue and provides further mechanistic insights into tissue-specific Treg cell-mediated immune regulation.

Project description:The pleiotropic cytokine IL-27 is essential for the clearance of the persistent LCMV strain Clone 13, however the cellular sources of IL-27 during viral infection are incompletely mapped and their relative importance unknown. Here we utilised single-cell RNA-sequencing of splenocytes from IL27-p28-GFP mice infected with Clone 13 to quantify the temporal patterns of IL-27 p28 production. IL-27-p28-GFP+ and IL-27-p28-GFP- splenocytes were sorted at 4 timepoints during Clone 13 infection and analysed by 3' single-cell transcriptome sequencing. Dendritic cells were major producers of early IL-27 with macrophages and monocytes being the predominant IL-27 producers during acute and persistent phases of infection. Interestingly, we also identified activated B cells and plasma cells as a prominent subset of IL-27-producing splenocytes and through B-cell-specific deletion of IL-27-p28 demonstrated that B-cell derived IL-27 is essential for sustained function of CD4 T cells and eventual clearance of Clone 13.

Project description:Escherichia coli and Staphylococcus are among the most common causes of bacterial sepsis, a deadly syndrome characterized by uncontrolled activation of coagulation and complement enzymatic cascades an exaggerated immune response. We performed in vivo experimental sepsis in baboons to characterize the host response to bacterial infection in blood cells. We demonstrate that bacterial infection leads to early induction of proinflammatory genes followed by a delayed activation of anti-inflammatory pathways. In addition, we observe changes in genes and pathways associated coagulation and complement as well as with leukocyte adhesion, migration and cell death. Our study provides important insights into the temporal kinetics of gene expression in leukocytes during bacterial sepsis.

Project description:Background: Neonatal infection and sepsis are common for preterm infants due to their immature immune system. Early diagnosis is important for effective treatment but few early markers of systemic and neuro-inflammatory responses in neonates are known. We hypothesized that systemic infection with Gram-positive Staphylococcus epidermidis (SE) induces acute changes to proteins in plasma and cerebrospinal fluid (CSF), potentially affecting the immature brain of preterm neonates. Methods: Using preterm pigs as model for preterm infants, plasma and CSF samples were collected up to 24 h after SE infection and investigated by untargeted mass spectrometry (MS)-based proteomics. Selected differential proteins were further studied in vitro assays. Results: The clinical signs of sepsis and neuroinflammation in SE-infected piglets were associated with changes in multiple CSF and plasma proteins. Eight plasma proteins, including APOA4, haptoglobin, MBL1, vWF, LBP and sCD14, were affected already 6 h after infection. Likewise, acute phase reactants, including complement components, showed a time-dependent activation pattern after infection. Feeding bovine colostrum reduced the sepsis-related change in clinical parameters as well as plasma proteins. Neuroinflammation-related neuropeptide Y (NPY), IL-18 and MMP-14 showed distinct changes in the CSF and several brain regions (prefrontal cortex, PVWM, hippocampus) 24 h after infection. These changes were verified in TLR2 agonist-challenged primary microglia cells, where exogenous NPY suppressed the inflammatory response. Conclusion: Systemic infection with Gram-positive SE induces inflammation with rapid proteome changes in plasma and CSF in preterm newborn pigs. The observed early markers of sepsis and neuroinflammation in preterm pigs may serve as novel biomarkers for sepsis in preterm infants.