Project description:Access to the brain for treating neurological sequalae requires a craniotomy, which can be complicated by infection. T cells preferentially home to the brain, but not other tissue sites, during Staphylococcus aureus (S. aureus) craniotomy infection; however, their functional importance is unknown. CD4+ T cells were critical for bacterial containment during craniotomy infection as Rag1-/- mice and WT animals treated with anti-CD4 or VLA-4 and LFA-1 antibodies exhibited elevated bacterial burdens. scRNA-seq revealed transcriptional heterogeneity in brain CD3+ infiltrates, with CD4+ cells most prominent and typified by both Th1 and Th17 signatures, and adoptive transfer of either subset in Rag1-/- mice prevented S. aureus outgrowth. scRNA-seq revealed a profound IFN-γ signature in innate immune cells from Rag1-/- mice during craniotomy infection, supporting extensive T cell-innate immune crosstalk that was validated by immunostaining in the brain parenchyma. A cooperative role for Th1 and Th17 driven responses was demonstrated by treatment of Ifng-/- mice with IL-17A/F neutralizing Ab that recapitulated phenotypes observed in Rag1-/- animals, which were not observed following the loss of either cytokine alone. Collectively, these results implicate a critical role for CD4+ T cells in S. aureus containment during craniotomy infection by shaping the innate immune landscape.

Project description:Functionally distinct CD4+ helper T (Th) cell subsets, such as Th1, Th2, Th17, and regulatory T cells (Treg), play a pivotal role in the host-defense against pathogen invasion and the pathogenesis of inflammatory disorders. In this project, DIA-MS-based proteome analysis was performed on naïve CD4+ T, Th0, Th1, Th2, Th17 and iTreg cells using Q Exactive HF-X (Thermo Fisher Scientific) to search for proteins that differ among the cell subsets.

Project description:Single cells RNA-Seq of CD45+ cells during Staphylococcus aureus craniotomy infection

Project description:scRNA-seq of phagocytic vs. non phagocytic immune cells during acute S. aureus craniotomy infection

Project description:Neurosurgeries complicated by bacterial infection are often associated with poor clinical prognosis and prolonged treatment strategies involving multiple surgeries, placing additional morbidity on an already fragile patient population. Craniotomy is one of the most common neurosurgical procedures with an infection rate of 1-7%; however, the cellular and molecular signatures associated with craniotomy infection in human subjects have not yet been investigated. We performed a retrospective study of over 2,500 craniotomies, which revealed diversity in patient demographics, pathogen identity, and surgical landscapes associated with infection. Leukocyte profiling in tissues procured from craniotomy infection patients revealed a predominance of granulocytic myeloid-derived suppressor cells (G-MDSCs), which were absent from the blood. Single-cell transcriptomics identified immunometabolic shifts in leukocytes invading infected tissues, including a prominent hypoxia-inducible factor-1 (HIF-1) signature, whereas peripheral blood cells from the same patient were largely quiescent. The importance of HIF-1 signaling was validated using a mouse model of Staphylococcus aureus craniotomy infection, where the local delivery of HIF-1 inhibitor microparticles attenuated proinflammatory cytokine production concomitant with a significant increase in leukocyte infiltrates into the infected brain and galea. These findings establish G-MDSCs as a major infiltrate during human craniotomy infection and identify conserved transcriptional signatures across several leukocyte populations that may represent promising therapeutic targets for craniotomy infection in the face of increasing antimicrobial resistance.

Project description:We compared the methylated and non-methylated regions in the genome of ex vivo-isolated naive CD4+ T cells, Th1 cells, Th17 cells and regulatory T cells by methyl-CpG binding domain protein sequencing (MBD-seq). Naive T cells and Th1 cells share more methylated regions than naive T cells and Th17 cells or Th1 and Th17 cells. However, analysis of the non-methylated regions revealed the highest similarity between Th1 and Th17 cells. Another aim was the analysis of the Th17 lineage on the basis of the methylome. We searched for regions absent in the methylome of Th17 but present in naive T cells, Th1 cells and regulatory T cells. Here, we identified differential methylation in the loci of Il17a, Chn2, Dpp4 and Dclk1. CD4+ T effector cells were prepared ex vivo, stimulated with PMA/Ionomycin, subjected to a comercially available cytokine secretion kit (IL-17A and IFNg), stained by adding fluorescence-labeled antibodies against CD3, CD4 and CD45RB and sorted by flow cytometry. We sorted naive CD4+ T cells (CD3+CD4+CD45RB_high), Th1 cells (CD3+CD4+CD45RB_low_IFNg+IL17A-), Th17 cells (CD3+CD4+CD45RB_low_IFNg-IL17A+) and regulatory T cells (CD3+CD4+CD25++).

Project description:In this study, we examined differential gene expression in naïve human CD4+ T cells, as well as in effector Th1, Th17-negative and Th17-enriched CD4- T cell subsets. We observed a marked enrichment for increased gene expression in effector CD4+ T cells compared to naive CD4+ among immune-mediated disease oci genes. Within effector T cells, expression of disease-associated genes was increased in Th17-enriched compared to Th17-negative cells. We used microarray to examine the gene expresssion profile and level of human naïve, Th1 and effector T cell subsets. Human PBMCs were isolated and sorted to naïve, CD161-CCR6- and CD161+CCR6+ memory T cells. Naïve T cells were differentiatied to Th1 cells, and CD161-CCR6- and CD161+CCR6+ memory T cells were in vitro expanded for Th17-negative and Th17-enriched effector T cells. The gene profile was compared among naive, Th1, Th17-negative, and Th17-enriched cell subsets.

Project description:Part 1/5: It includes lipidomic analysis of CD4+ T-cell subsets(Th1,Th2,Th17 and iTreg cells)and their paired controls(Th0 cells).

Project description:CD4+ T cells differentiate into phenotypically distinct T-helper cells upon antigenic stimulation. Regulation of plasticity between these CD4+ T-cell lineages is critical for immune homeostasis and prevention of autoimmune diseases. However, the factors that regulate lineage stability are largely unknown. Here we investigate a role for retinoic acid (RA) in the regulation of lineage stability using T helper 1 (Th1) cells, traditionally considered the most phenotypically stable Th subset. We found that RA, through its receptor RARa, sustains stable expression of Th1 lineage specifying genes as well as repressing genes that instruct Th17 cell fate. RA signaling is essential for limiting Th1 cell conversion into Th17 effectors and for preventing pathogenic Th17 responses in vivo. Our studies identify RA-RARa as a key component of the regulatory network governing Th1 cell fate and define a new paradigm for the development of pathogenic Th17 cells. These findings have important implications for autoimmune diseases in which dysregulated Th1-Th17 responses are observed. IFN-gamma+ Th1 cells from IFNgeYFP reporter mouse; comparing dnRARa to WT

Project description:CD4+ T cells differentiate into phenotypically distinct T-helper cells upon antigenic stimulation. Regulation of plasticity between these CD4+ T-cell lineages is critical for immune homeostasis and prevention of autoimmune diseases. However, the factors that regulate lineage stability are largely unknown. Here we investigate a role for retinoic acid (RA) in the regulation of lineage stability using T helper 1 (Th1) cells, traditionally considered the most phenotypically stable Th subset. We found that RA, through its receptor RARa, sustains stable expression of Th1 lineage specifying genes as well as repressing genes that instruct Th17 cell fate. RA signaling is essential for limiting Th1 cell conversion into Th17 effectors and for preventing pathogenic Th17 responses in vivo. Our studies identify RA-RARa as a key component of the regulatory network governing Th1 cell fate and define a new paradigm for the development of pathogenic Th17 cells. These findings have important implications for autoimmune diseases in which dysregulated Th1-Th17 responses are observed. Identification of RARa binding in wild-type Th1 cells and mapping of enhancers using chromatin IP against p300, H3k4me1, H3k4me3, and H3k27ac in wild-type and dnRara Th1 cells.