Project description:Regulatory T (Treg) cells are highly enriched in the visceral adipose tissue (VAT) to maintain metabolic homeostasis, but they are lost during obesity. VAT Treg cells exhibit enhanced Srebf2-dependent cholesterol metabolism compared lymphoid tissue Tregs at steady state, but this metabolic pathway is disrupted during obesity. Therefore, the goal of this study is to determine the impact of Treg-specific Srebf2 deletion on the transcriptional phenotype of bulk Foxp3+ VAT or splenic Tregs.

Project description:Tregs are highly enriched in the eVAT of male mice. We show that ST2+ VAT Tregs preferentially upregulate and depend on Srebf2-mediated cholesterol metabolism compared their spleen Treg or ST2- VAT Treg counterparts. However, it is unclear whether this increased reliance on cholesterol metabolism is a consequence elevated IL-33 signaling in ST2+ Tregs. Therefore, the goal of experiment is to determine whether IL-33 signaling influences Srebf2-dependent cholesterol gene expression in ST2+ eVAT Tregs in vivo.

Project description:Visceral adipose tissue (VAT) regulatory T cells (Tregs) control inflammation and metabolism. Diet-induced obesity causes hyperinsulinemia and diminishes VAT Treg number and function, but whether these two phenomena were mechanistically linked was unknown. We hypothesized that excessive insulin signaling in obesity negatively impact VAT Tregs. Using Treg-specific insulin receptor deletion (Foxp3-cre;Insr-fl/fl) mice, we compared the gene expression of VAT Tregs from control and knockout mice in obesity and aging, two models of hyperinsulinemia. We found that genes associated with Treg functions were altered in Tregs lacking insulin receptor.

Project description:Regulatory T cells (Tregs) are key brakes on the VAT inflammation that regulates local and systemic metabolic tenor. The cytokine, IL-33, expands and sustains the unique Treg population residing within VAT. Making use of single-cell RNA sequencing, we identified the major IL-33 producers in VAT to be particular mSC subtypes, related to but distinct from adipocyte progenitor cells. We further characterize these subsets by individually isolating them and performing bulk-RNA sequencing. We explored modulation of the VAT-mSC (VmSC) landscape with physiologic variables such as age and sex, as well as pathogenic states like obesity. We uncovered a VAT Treg:stromal-cell negative regulatory loop that keeps the potent effect of IL-33 under rein.

Project description:Regulatory T cells (Tregs) are key brakes on the VAT inflammation that regulates local and systemic metabolic tenor. The cytokine, IL-33, expands and sustains the unique Treg population residing within VAT. Making use of single-cell RNA sequencing, we identified the major IL-33 producers in VAT to be particular mSC subtypes, related to but distinct from adipocyte progenitor cells. We further characterize these subsets by individually isolating them and performing bulk-RNA sequencing. We explored modulation of the VAT-mSC (VmSC) landscape with physiologic variables such as age and sex, as well as pathogenic states like obesity. We uncovered a VAT Treg:stromal-cell negative regulatory loop that keeps the potent effect of IL-33 under rein.

Project description:We reported transcriptional characterization of vTreg53 TCR transgenic Treg cells from splenic and visceral adipose tissue (VAT) in mice fed with normal chow diet (NCD) or high fat diet (HFD) for different durations. We also reported transcriptional profile of VAT Treg cells stimulated by IFNa in vitro. Through this analysis, we found that the reduction of VAT Treg cells during obesity is driven by increased production of IFNa in VAT.

Project description:Visceral adipose tissue (VAT) is an endocrine organ critical for energy storage and metabolic homeostasis. Its function, at least in part, is controlled by immune cells, including Foxp3+ regulatory T (Treg) cells, which restrain VAT inflammation and glucose intolerance. Here we uncover that the VAT harbours two distinct Treg cell populations, prototypical ST2+ Treg cells, that are enriched in males and depend on the cytokine IL-33 and the transcription factor PPAR and a previously uncharacterized population of VAT Treg cells that express the chemokine receptor CXCR3+, are enriched in females and depend on the transcription factor T-bet. We further show that the transcription factor GATA3 promoted differentiation of ST2+ VAT Treg cells and together with PPAR and IL-33 repressed the differentiation of CXCR3+ Treg cells. CXCR3+ VAT Treg cells developed from naïve Treg cells in a cytokine IFN- dependent manner. Finally, we demonstrate that ST2+ Treg cells promoted glucose tolerance, while CXCR3+ Treg cells limited VAT inflammation in a sex specific manner. This study for the first time establishes how inflammation determines the developmental trajectories of two functionally and molecularly distinct Treg cell types in the VAT.

Project description:Visceral adipose tissue (VAT) is an endocrine organ critical for energy storage and metabolic homeostasis. Its function, at least in part, is controlled by immune cells, including Foxp3+ regulatory T (Treg) cells, which restrain VAT inflammation and glucose intolerance. Here we uncover that the VAT harbours two distinct Treg cell populations, prototypical ST2+ Treg cells, that are enriched in males and depend on the cytokine IL-33 and the transcription factor PPAR and a previously uncharacterized population of VAT Treg cells that express the chemokine receptor CXCR3+, are enriched in females and depend on the transcription factor T-bet. We further show that the transcription factor GATA3 promoted differentiation of ST2+ VAT Treg cells and together with PPAR and IL-33 repressed the differentiation of CXCR3+ Treg cells. CXCR3+ VAT Treg cells developed from naïve Treg cells in a cytokine IFN- dependent manner. Finally, we demonstrate that ST2+ Treg cells promoted glucose tolerance, while CXCR3+ Treg cells limited VAT inflammation in a sex specific manner. This study for the first time establishes how inflammation determines the developmental trajectories of two functionally and molecularly distinct Treg cell types in the VAT.

Project description:Visceral adipose tissue (VAT) is an endocrine organ critical for energy storage and metabolic homeostasis. Its function, at least in part, is controlled by immune cells, including Foxp3+ regulatory T (Treg) cells, which restrain VAT inflammation and glucose intolerance. Here we uncover that the VAT harbours two distinct Treg cell populations, prototypical ST2+ Treg cells, that are enriched in males and depend on the cytokine IL-33 and the transcription factor PPAR and a previously uncharacterized population of VAT Treg cells that express the chemokine receptor CXCR3+, are enriched in females and depend on the transcription factor T-bet. We further show that the transcription factor GATA3 promoted differentiation of ST2+ VAT Treg cells and together with PPAR and IL-33 repressed the differentiation of CXCR3+ Treg cells. CXCR3+ VAT Treg cells developed from naïve Treg cells in a cytokine IFN- dependent manner. Finally, we demonstrate that ST2+ Treg cells promoted glucose tolerance, while CXCR3+ Treg cells limited VAT inflammation in a sex specific manner. This study for the first time establishes how inflammation determines the developmental trajectories of two functionally and molecularly distinct Treg cell types in the VAT.

Project description:Obesity can lead to type 2 diabetes and is an epidemic. A major contributor to its adverse effects is inflammation of the visceral adipose tisse (VAT). Life-long caloric restriction (CR), in contrast, results in extended lifespan, enhanced glucose tolerance/ insulin sensitivity, and other favorable phenotypes. The effects of CR following obesity are incompletely established, but studies show multiple benefits. Many leukocyte types, macrophages predominantly, reside in VAT in homeostatic and pathological states. CR following obesity transiently increases VAT macrophage content prior to resolution of inflammation and obesity, suggesting that macrophage content and phenotype play critical roles. Here, we examined the heterogeneity of VAT leukocytes and the effects of obesity and CR. In general, our single-cell RNA-sequencing data demonstrate that macrophages are the most abundant and diverse subpopulation of leukocytes in VAT. Obesity induced significant transcriptional changes in all 15 leukocyte subpopulations, with many genes showing coordinated changes in expression across leukocyte subpopulations. Additionally, obese VAT displayed expansion of one major macrophage subpopulation, which, in silico was enriched in lipid binding and metabolic processes. This subpopulation returned from dominance in obesity to lean proportions after only 2 weeks of CR, although the pattern of gene expression overall remained similar. Surprisingly, CR VAT is dominated by a different macrophage subpopulation, which is absent in lean conditions. This subpopulation is enriched in genes related to phagocytosis and we postulate that its function includes clearance of dead cells as well as excess lipids, contributing to limiting VAT inflammation and restoration of the homeostatic state.