Project description:We studied the opposing effects of exercise training and high-fat diet at single-cell resolution to reveal changes in cell type abundance, cell-type-specific gene expression/pathway/regulatory network changes, and changes in cell-cell communication both within and across tissues. We profiled scRNA-seq in 204,883 cells, grouped into 53 distinct cell sub-types/states across 22 major cell types, from subcutaneous white adipose tissue, visceral white adipose tissue, and skeletal muscle across 16 lean and 15 obese mice with both diet and exercise interventions. Changes in both cell proportion and transcriptional state were most strongly pronounced in adipose stem cells in fat, consistent with roles of adipogenesis in thermogenesis-vs-lipogenesis and hyperplasia-vs-hypertrophy in obesity. For immune cells, exercise training decreases obesity-associated inflammatory tissue-resident cell populations, including myeloid and regulatory T cells, and promotes beige-cell-inducing populations, including NKT cells. These changes clustered in common pathways across tissues for both exercise and obesity, including extracellular matrix remodelling and circadian rhythm in mesenchymal stem cells and cell activation/migration in immune cells.

Project description:Global deficiency of catalytic subunit Ppp3cb, and tissue-specific ablation of regulatory subunit Ppp3r1 from skeletal muscle but not adipose tissue or liver led to protection from high-fat diet induced obesity and comorbid sequelæ. Ser637 hyperphosphorylation of dynamin-related protein 1 (Drp1) in skeletal muscle of calcineurin-deficient mice was associated with mitochondrial elongation into power-cable shaped filaments, increased mitochondrial respiration, but attenuated exercise performance.

Project description:Global deficiency of catalytic subunit Ppp3cb, and tissue-specific ablation of regulatory subunit Ppp3r1 from skeletal muscle but not adipose tissue or liver led to protection from high-fat diet induced obesity and comorbid sequelæ. Ser637 hyperphosphorylation of dynamin-related protein 1 (Drp1) in skeletal muscle of calcineurin-deficient mice was associated with mitochondrial elongation into power-cable shaped filaments, increased mitochondrial respiration, but attenuated exercise performance. Mice used for microarray analyses were all male, and chronically exposed to HFD for at least 8 weeks.

Project description:Background and aim: Diacylglycerol kinase (DGK) isoforms catalyze an enzymatic reaction that removes diacylglycerol (DAG) and thereby terminates protein kinase C (PKC) signaling by converting DAG to phosphatidic acid (PA). We have reported that downregulation of DGKδ (type II isozyme) causes peripheral insulin resistance, metabolic inflexibility, and obesity. Our aim was to determine whether overexpression of DGKδ protects against the development of metabolic impairments and obesity. Methods: We generated a transgenic mouse model overexpressing the human DGKδ2 isoform under the myosin light change promoter (DGKδ TG). We performed deep metabolic phenotyping of DGKδ TG and wild-type mice fed chow or high-fat diet. Mice were also given free access to running wheels to examine the effects of DGKδ overexpression on exercise-induced metabolic outcomes. Results: DGKδ TG mice were leaner than wild-type littermates, with improved glucose tolerance, increased glycogen storage in skeletal muscle, and enhanced glucose uptake in white adipose tissue. Moreover, DGKδ TG mice were protected against high fat diet (HFD)-induced glucose intolerance and obesity. DGKδ TG mice had reduced epididymal fat pad weight, and enhanced lipolysis. Strikingly, DGKδ overexpression recapitulates the beneficial effects exercise on metabolic outcomes. DGKδ overexpression and exercise have a synergistic effect on body weight reduction. Microarray analysis of skeletal muscle confirmed an overlap between genes associated with exercise and DGKδ overexpression. Gene ontology signatures of exercise and DGKδ overexpression were related to lipid storage, extracellular matrix, and glycogen biosynthesis pathways. Conclusion: We identify a role for DGKδ in glucose and energy homeostasis. Overexpression of DGKδ induces adaptive changes in both skeletal muscle and adipose tissue, resulting in protection against high fat diet-induced obesity. DGKδ overexpression recapitulates exercise-induced adaptations on energy homeostasis and skeletal muscle gene expression profiles.

Project description:We demonstrate whole body inflammation (miR146a-/-) exacerbated inactivity-induced fat gain and glucose dysregulation, while muscle specific MyD88 KO mitigated these outcomes in female mice. Higher gene expression of Igf1 and decreased expression of Ip6k3 in muscle of MyD88 KO female mice may explain enhancement of glucose uptake in the soleus. Whereas protection from fat accumulation may be related to visceral fat gene changes in adipose tissue expansion (Prc1↓, Gulp1↑, Anxa2↓, Cav2↓, EHD1↓), adipose beiging (Fgf10↑), metainflammation (Hmox1↓), and genes involved in perfusion. Of noteworthy to mention, two genes decreased in common between muscle and fat with the ablation of muscle MyD88. These were expression of the negative regulator for GLUT4 translocation, Ralgapa2, and uncharacterized 993011J21Rik2, a potential interferon interacting gene. We conclude that future therapeutic strategies for prevention or treatment of obesity and metabolic disturbances in populations unable to be physically active should focus on further understanding how skeletal muscle inflammation communicates with fat storage depots, and how this cross-talk is influenced by sex hormones.

Project description:Following 20wk of either chow or high fat feeding, tissues were collected from C57BL/6J mice. Gene expression in four tissues that have been associated with obesity-related metabolic complications: white adipose tissue (WAT), skeletal muscle, the liver, and the heart were examined. Data suggest that some tissues may be attempting to reduce the metabolic perturbations that occur in the early stages of obesity. Also, many identified genes were associated with a variety of disorders, thereby serving as potential links between obesity and related health risks.

Project description:This experiment was conducted to identify mRNA transcripts alteration in muscle from skeletal muscle-sepcific Fundc1-knockout mice. The following abstract from the submitted manuscript describes the major findings of this work. Mitophagy directs muscle-adipose crosstalk to alleviate dietary obesity. Tingting Fu, Zhisheng Xu, Lin Liu, Qiqi Guo, Hao Wu, Xijun Liang, Danxia Zhou, Liwei Xiao, Lei Liu, Yong Liu, Min-Sheng Zhu, Quan Chen and Zhenji Gan. The quality of mitochondria in skeletal muscle is essential for maintaining metabolic homeostasis during adaptive stress responses. However, the precise control mechanism of muscle mitochondrial quality and its physiological impacts remain unclear. Here, we demonstrate that FUNDC1, a mediator of mitophagy, plays a critical role in controlling muscle mitochondrial quality as well as metabolic homeostasis. Skeletal muscle-specific ablation of FUNDC1 in mice resulted in LC3-mediated mitophagy defect, leading to impaired mitochondrial energetics. This caused decreased muscle fat utilization and endurance capacity during exercise. Interestingly, mice lacking muscle FUNDC1 were protected against high-fat diet-induced obesity with improved systemic insulin sensitivity and glucose tolerance despite reduced muscle mitochondrial energetics. Mechanistically, FUNDC1 deficiency elicited a retrograde response in muscle that upregulated FGF21 expression, thereby promoting the thermogenic remodeling of adipose tissue. Thus, these findings reveal a pivotal role of FUNDC1-dependent mitochondrial quality-control in mediating the muscle-adipose dialogue to regulate systemic metabolism.

Project description:Domestic broiler chickens rapidly accumulate adipose tissue due to intensive genetic selection for rapid growth and are naturally hyperglycemic and insulin resistant, making them an attractive addition to the suite of rodent models used for studies of obesity and type 2 diabetes in humans. Furthermore, chicken adipose tissue is considered as poorly sensitive to insulin and lipolysis is under glucagon control. Excessive fat accumulation is also an economic and environmental concern for the broiler industry due to the loss of feed efficiency and excessive nitrogen wasting, as well as a negative trait for consumers who are increasingly conscious of dietary fat intake. Understanding the control of avian adipose tissue metabolism would both enhance the utility of chicken as a model organism for human obesity and insulin resistance and highlight new approaches to reduce fat deposition in commercial chickens. In the present study we simultaneously characterized the effects of a short term (5 hours) fast or neutralization of insulin action (5 hours) on adipose tissue of young (16-17 day-old), fed commercial broiler chickens.

Project description:We treated obese mice being fed a high-fat diet with exosomes transfected with a combination of inhibitors of obesity-associated miR-122 and miR-192 and a mimic of exercise-associated miR-133b. We used microarrays to detail the global changes of gene expression induced by the exosomal treatment in liver, adipose and muscle tissues in comparison with HIIT.

Project description:Exercise training improves whole body glucose homeostasis through effects largely attributed to adaptations in skeletal muscle; however, training also affects other tissues including adipose tissue. To determine if exercise-induced adaptations to adipose tissue contribute to training-induced improvements in glucose homeostasis, subcutaneous white adipose tissue (scWAT) from trained or sedentary donor mice was transplanted into the visceral cavity of sedentary recipients. Remarkably, nine days post-transplantation, mice receiving trained scWAT had improved glucose tolerance and enhanced insulin sensitivity compared to mice transplanted with sedentary scWAT or sham-treated mice. Mice transplanted with trained scWAT had increased insulin-stimulated glucose uptake in tibialis anterior and soleus muscles and brown adipose tissue, suggesting that the transplanted scWAT exerted endocrine effects. Furthermore, the deleterious effects of high-fat feeding on glucose tolerance and insulin sensitivity were completely reversed if high-fat fed recipient mice were transplanted with trained scWAT. In additional experiments, voluntary exercise training by wheel running for only 11 days resulted in profound changes in scWAT including increased expression of ∼1550 genes involved in numerous cellular functions, including metabolism. Exercise training causes adaptations to scWAT that elicit metabolic improvements in other tissues, demonstrating a previously unrecognized role for adipose tissue in the beneficial effects of exercise on systemic glucose homeostasis. Microarray analysis of scWAT obtained from a cohort of mice that were housed in wheel cages for 11 days compared to sedentary control mice.