Project description:The role of peroxisome proliferator-activated receptor M-NM-4 (PPARM-NM-4) activation on global gene expression and mitochondrial fuel utilization were investigated in human myotubes. Only 21 genes were up-regulated and 3 genes were down-regulated after activation by the PPARM-NM-4 agonist GW501516. Pathway analysis showed up-regulated mitochondrial fatty acid oxidation, TCA cycle and cholesterol biosynthesis. GW501516 increased oleic acid oxidation and mitochondrial oxidative capacity by 2-fold. Glucose uptake and oxidation were reduced, but total substrate oxidation was not affected, indicating a fuel switch from glucose to fatty acid. Cholesterol biosynthesis was increased, but lipid biosynthesis and mitochondrial content were not affected. This study confirmed that the principal effect of PPARM-NM-4 activation was to increase mitochondrial fatty acid oxidative capacity. Our results further suggest that PPARM-NM-4 activation reduced glucose utilization through a switch in mitochondrial substrate preference by up-regulating pyruvate dehydrogenase kinase isozyme 4 and genes involved in lipid metabolism and fatty acid oxidation. Keywords: Expression profiling by array Human myotubes from four donors were exposed to a PPARM-NM-4 agonist or control for 96 h after which gene expression was profiled.

Project description:The role of peroxisome proliferator-activated receptor δ (PPARδ) activation on global gene expression and mitochondrial fuel utilization were investigated in human myotubes. Only 21 genes were up-regulated and 3 genes were down-regulated after activation by the PPARδ agonist GW501516. Pathway analysis showed up-regulated mitochondrial fatty acid oxidation, TCA cycle and cholesterol biosynthesis. GW501516 increased oleic acid oxidation and mitochondrial oxidative capacity by 2-fold. Glucose uptake and oxidation were reduced, but total substrate oxidation was not affected, indicating a fuel switch from glucose to fatty acid. Cholesterol biosynthesis was increased, but lipid biosynthesis and mitochondrial content were not affected. This study confirmed that the principal effect of PPARδ activation was to increase mitochondrial fatty acid oxidative capacity. Our results further suggest that PPARδ activation reduced glucose utilization through a switch in mitochondrial substrate preference by up-regulating pyruvate dehydrogenase kinase isozyme 4 and genes involved in lipid metabolism and fatty acid oxidation. Keywords: Expression profiling by array

Project description:Chronic stress episodes increase metabolic disease risk even after recovery. We propose that persistent stress detrimentally impacts hepatic metabolic reprogramming, particularly mitochondrial function. In male C57BL/6 mice chronic variable stress (Cvs) reduced energy expenditure (EE) and body mass despite increased energy intake versus controls. This coincided with decreased glucose metabolism and increased lipid β-oxidation, correlating with EE. After Cvs, mitochondrial function revealed increased thermodynamic efficiency (ƞ-opt) of complex CI, positively correlating with blood glucose and NEFA and inversely with EE. After Cvs recovery, the metabolic flexibility of hepatocytes was lost. Reduced CI-driving NAD+/NADH ratio, and diminished methylation-related one-carbon cycle components hinted at epigenetic regulation. Although initial DNA methylation differences were minimal after Cvs, they diverged during the recovery phase. Here, the altered enrichment of mitochondrial DNA methylation and linked transcriptional networks were observed. In conclusion, Cvs rapidly initiates the reprogramming of hepatic energy metabolism, supported by lasting epigenetic modifications.

Project description:Chronic stress episodes increase metabolic disease risk even after recovery. We propose that persistent stress detrimentally impacts hepatic metabolic reprogramming, particularly mitochondrial function. In male C57BL/6 mice chronic variable stress (Cvs) reduced energy expenditure (EE) and body mass despite increased energy intake versus controls. This coincided with decreased glucose metabolism and increased lipid β-oxidation, correlating with EE. After Cvs, mitochondrial function revealed increased thermodynamic efficiency (ƞ-opt) of complex CI, positively correlating with blood glucose and NEFA and inversely with EE. After Cvs recovery, the metabolic flexibility of hepatocytes was lost. Reduced CI-driving NAD+/NADH ratio, and diminished methylation-related one-carbon cycle components hinted at epigenetic regulation. Although initial DNA methylation differences were minimal after Cvs, they diverged during the recovery phase. Here, the altered enrichment of mitochondrial DNA methylation and linked transcriptional networks were observed. In conclusion, Cvs rapidly initiates the reprogramming of hepatic energy metabolism, supported by lasting epigenetic modifications.

Project description:Resistin has been originally identified as an adipokine that links obesity to insulin resistance in mice. In our previous studies in spontaneously hypertensive rats (SHR) expressing a nonsecreted form of mouse resistin (Retn) transgene specifically in adipose tissue (SHR-Retn), we observed an increased lipolysis and serum free fatty acids, ectopic fat accumulation in muscles and insulin resistance. Recently, brown adipose tissue (BAT) has been suggested to play an important role in the pathogenesis of metabolic disturbances by its ability to dissipate energy excess. In the current study, we analyzed autocrine effects of transgenic resistin on BAT glucose and lipid metabolism and mitochondrial function in the SHR-Retn versus nontransgenic SHR controls. We observed that interscapular BAT isolated from SHR-Retn transgenic rats when compared to SHR controls showed a lower relative weight, significantly reduced both basal and insulin stimulated incorporation of palmitate into BAT lipids, and significantly decreased palmitate oxidation and glucose oxidation. In addition, in vivo microPET imaging revealed significantly reduced 18F-FDG uptake in BAT induced by exposure to cold in SHR-Retn versus control SHR. Gene expression profiles identified differentially expressed genes involved in skeletal muscle and connective tissue developmental and inflammation, as well as MAPK and insulin signaling. These results provide compelling evidence that autocrine effects of resisitin in BAT play an important role in the pathogenesis of insulin resistance in the rat.

Project description:Glucose-stimulated insulin secretion (GSIS) is suppressed through α-adrenergic receptor stimulation by catecholamines, epinephrine and norepinephrine, in pancreatic β-cells. Previous work has elucidated a bevy of adrenergic regulatory mechanisms beyond traditional Gi-coupled signaling including regulation of ion channels and interactions with exocytotic machinery. Glucose oxidation may also be an important site for adrenergic regulation of GSIS, but the link between epinephrine and glucose oxidation in β-cells is undefined. Here, we evaluate whether adrenergic stimulation decreases oxidative metabolism in β cells. Oxygen consumption rates were determined for Min6 and isolated rat islets in 20mM glucose complete media, then epinephrine was added at either 0 nM (vehicle control) or 100nM, followed by 10uM yohimbine (a selective Adrα2A antagonist). To identify glucose oxidation as the primary metabolic pathway affected by epinephrine, oxidation of 14C(U)-labeled glucose was determined in Min6 cells with epinephrine or vehicle. Oxygen consumption and glucose oxidation experiments were conducted in the presence of cAMP and insulin secretion blockers, respectively. Proteomics was performed on Min6 cells exposed to epinephrine for 4 hours and compared to controls. Epinephrine, but not vehicle, reduced (P<0.01) oxygen consumption rates in rat islets and Min6 cells to 64 ± 6% and 65 ± 1% of baseline, respectively, and yohimbine restored oxygen consumption to rates not different from baseline. In Min6 cells incubated with epinephrine rates of 14C glucose oxidation were reduced (P<0.01) 66 ± 4% compared to vehicle controls. These results demonstrate that acute epinephrine exposure suppresses glucose oxidation in β cells via the specific adrenergic receptor, Adrα2A, and indicate a new role for adrenergic regulation in GSIS.

Project description:Cardiac glucose delivery and utilization are reduced in diabetes despite hyperglycemia. Mitochondrial dysfunction contributes to heart failure in diabetic patients. The loss of mitochondrial substrate flexibility in regulating cellular and cardiac function is actively under investigation.

Project description:Dietary polyunsaturated fatty acids (PUFA) act as potent natural hypolipidemics and are linked to many health benefits in humans and in animal models. Mice fed long-term a high fat diet, in which medium-chain alpha linoleic acid (ALA) was partially replaced by long-chain docosahexaenoic (DHA) and eicosapentaenoic (EPA) fatty acids, showed reduced accumulation of body fat and prevention of insulin resistance, besides increased mitochondrial beta-oxidation in white adipose tissue and decreased plasma lipids. ALA, EPA and DHA all belong to PUFA of n-3 series. The intestine is a gatekeeper organ for ingested lipids. To examine the potential contribution of the intestine in the beneficial effects of EPA and DHA, this study assessed gene expression changes using whole genome microarray analysis on small intestinal scrapings. The main biological process affected was lipid metabolism. Fatty acid uptake, peroxisomal and mitochondrial beta-oxidation, and omega-oxidation of fatty acids were all increased. Quantitative real time PCR and intestinal fatty acid oxidation measurements ([14C(U)]-palmitate) confirmed significant gene expression differences in a dose-dependent manner. Furthermore, no major changes in the expression of lipid metabolism genes were observed in colonic scrapings. In conclusion, we show that marine n-3 fatty acids regulate small intestinal gene expression patterns. Since this organ contributes significantly to whole organism energy use, this adaptation of the small intestine may contribute to the complex and observed beneficial physiological effects of these natural compounds under conditions that will normally lead to development of obesity and diabetes.

Project description:Semaglutide (Sema) is a novel glucagon-like peptide-1 receptor (GLP-1R) agonist that is used clinically as a hypoglycemic and bariatric agent, as it regulates the energy metabolic process. In heart failure, mitochondrial oxidative phosphorylation substrates are altered, glycolysis is increased, and intracellular energy production is decreased. However, the responsiveness of Sema-regulated energy metabolism to the metabolic environment of cardiomyocytes stimulated by pressure burden remains unclear. Herein, we used transverse aortic constriction (TAC) surgery as the disease model. We found that Sema improved cardiac dysfunction and attenuated myocardial hypertrophy and fibrosis. This is manifested by reduced myocyte volume and interstitial collagen deposition. We found that Sema treatment maintains mitochondrial morphology and function under conditions of chronic stress load-mediated damage. Untargeted metabolomics analysis revealed that Sema ameliorated mitochondrial lesions and reduced lipid accumulation and ATP insufficiency by promoting glycolytic species products enter the tricarboxylic acid cycle (TCA) and increasing β-oxidation. Transcriptional profiling results revealed that Sema exerted its effects on myocardial energy metabolism by regulating Creb5/NR4a1 in the canonical PI3K/AKT pathway. Specifically, Sema reduced the expression of NR4a1 and its translocation from the nucleus to mitochondria. The disorders of mitochondrial function and myocardial glucolipid metabolism were significantly ameliorated after NR4a1 knockdown. Overall, Sema ameliorates myocardial glucose, lipid, and energy metabolism disorders by regulating Creb5/NR4a1, thereby protecting against pathological myocardial remodeling. This finding provides a new therapeutic agent for improving pathological myocardial remodeling based on energy metabolic switching.

Project description:The number of circulating endothelial progenitor cells (EPCs) predicts future development of atherosclerotic cardiovascular disease (ASCVD) and is reduced in patients with type 2 diabetes (T2DM) or impaired glucose tolerance (IGT). Recent studies revealed the contribution of tight control of glycolysis and mitochondrial oxidative phosphorylation (OXPHOS), as well as fatty acid oxidation in the regulation of stem cell behavior. In this study, we show that how dysregulated glucose and triglyceride metabolism in T2DM/IGT affects the homeostasis of EPCs, i.e. bone marrow stem/progenitor cells (BMSCs). In our clinical study, consistent with previous reports, the patients with IGT or T2DM showed reduced level of circulating EPCs, as compared normal glucose tolerance. On the other hand, fasting or postprandial hypertriglyceridemia (hTG) itself did not affect the level of circulating EPCs. However, further analysis using single and multiple regression analyses strongly suggested that, in the presence of postprandial hTG, postprandial hyperglycemia exerts devastating effect on EPC homeostasis. We therefore carried out the proof of concept study in mice. Our experimental study revealed that repetitive glucose+lipid (G+L) spikes, but not repetitive glucose (G) spikes or lipid (L) spikes, rapidly upregulated p53 in BMSCs and induced premature aging phenotype of bone marrow cells, i.e. the impairment of BMSC quiescence and function, and myeloid-biased differentiation. Subsequent analysis implicated that p53-mediated augmentation of mitochondrial OXPHOS plays pivotal role for the impairment of BMSC quiescence and function. On the other hand, it is still not clear how repetitive G+L injection induced myeloid-biased differentiation. Because cell-fate decisions are executed by transcription factors in response to extracellular signals, and the best-known function of p53 is as a transcription factor, we asked to what extent repetitive glucose spikes and repetitive glucose+TG spikes affect transcriptional regulation in LSK cells.