Project description:Obesity-induced inflammation metabolic dysfunction, but the mechanisms remain elusive. Here we showed that the innate immune factor IRF3 is a direct transcriptional regulator of glucose homeostasis through induction of endogenous FAHFA hydrolase Aig1 in adipocytes. Adipocyte-specific knockout IRF3 protects mice against high-fat diet-induced insulin resistance, whereas overexpression of IRF3 in adipocytes promotes insulin resistance on a high-fat diet. Furthermore, pharmacological inhibition of AIG1 reversed obesity-induced insulin resistance and restored glucose homeostasis in the setting of adipocyte IRF3 overexpression. We therefore, identify the adipocyte IRF3/AIG1 axis as a crucial link between obesity-induced inflammation and insulin resistance and suggest an approach for limiting the metabolic dysfunction accompanying obesity.

Project description:Brown adipose tissue (BAT) is a major site of nonshivering thermogenesis (NST) in mammals and might play an important role in human obesity and energy homeostasis. Recent single-cell/nucleus RNA-sequencing studies have revealed heterogeneity in thermogenesis among brown adipocytes, such as the findings of low thermogenesis and regulated thermogenesis in brown adipocytes. Activating and enhancing function adipocytes (BAC) has acquired attention as a possible therapeutic intervention for metabolic diseases. Nuclear factor-erythroid 2-related factor 1 (NFE2L1, also known as Nrf1), a CNC-bZIP protein, is a master regulator of multiple cellular functions and responds to various stress in many cells and tissues. NFE2L1 acts as a guardian role in BAC function providing increased proteometabolic quality control for adapting to cold or obesity. Our previous studies demonstrated that NFE2L1-dependent lipolytic activity is crucial for white adipose tissue (WAT) plasticity and lipid homeostasis. ​To further clarify the role of NFE2L1 in adipocytes, we focused on the phenotype and gene expression profiling of BAT in adipocyte-specific Nfe2l1-knockout [Nfe2l1(f)-KO] mice. We found that deletion of Nfe2l1 decreased core body temperature and cold intolerance under cold exposure. Compared with floxed mice, the BAT of Nfe2l1(f)-KO mice expressed substantially lower levels of many genes related to lipolysis, thermogenesis, oxidative capacity of mitochondria, cellular respiration while higher genes related to inflammation, pyroptosis. By snRNA-seq, we found that Nfe2l1-knockout resulted in increased antigen processing and presentation (APP), necroptosis and NOD-like receptor signal pathway (NOD) signaling pathways in most subpopulations of BAC, with devastating effects on a normal subpopulation of BAC with low thermogenesis and high necroptosis genes expression. Absent of Nfe2l1 impairs the function of BAC, causing a morphological “whitening” phenotype with adipocyte hypertrophy and severe inflammation. Moreover, the adipose inflammation and pyroptosis in Nfe2l1(f)-KO mice could be mitigated by cold exposure or β3-agonist treatment. These findings provided a deeper insight into the function of NFE2L1 in the metabolic programming of brown adipocytes.

Project description:Brown adipose tissue (BAT) is a major site of nonshivering thermogenesis (NST) in mammals and might play an important role in human obesity and energy homeostasis. Recent single-cell/nucleus RNA-sequencing studies have revealed heterogeneity in thermogenesis among brown adipocytes, such as the findings of low thermogenesis and regulated thermogenesis in brown adipocytes. Activating and enhancing function adipocytes (BAC) has acquired attention as a possible therapeutic intervention for metabolic diseases. Nuclear factor-erythroid 2-related factor 1 (NFE2L1, also known as Nrf1), a CNC-bZIP protein, is a master regulator of multiple cellular functions and responds to various stress in many cells and tissues. NFE2L1 acts as a guardian role in BAC function providing increased proteometabolic quality control for adapting to cold or obesity. Our previous studies demonstrated that NFE2L1-dependent lipolytic activity is crucial for white adipose tissue (WAT) plasticity and lipid homeostasis. ​To further clarify the role of NFE2L1 in adipocytes, we focused on the phenotype and gene expression profiling of BAT in adipocyte-specific Nfe2l1-knockout [Nfe2l1(f)-KO] mice. We found that deletion of Nfe2l1 decreased core body temperature and cold intolerance under cold exposure. Compared with floxed mice, the BAT of Nfe2l1(f)-KO mice expressed substantially lower levels of many genes related to lipolysis, thermogenesis, oxidative capacity of mitochondria, cellular respiration while higher genes related to inflammation, pyroptosis. By snRNA-seq, we found that Nfe2l1-knockout resulted in increased antigen processing and presentation (APP), necroptosis and NOD-like receptor signal pathway (NOD) signaling pathways in most subpopulations of BAC, with devastating effects on a normal subpopulation of BAC with low thermogenesis and high necroptosis genes expression. Absent of Nfe2l1 impairs the function of BAC, causing a morphological “whitening” phenotype with adipocyte hypertrophy and severe inflammation. Moreover, the adipose inflammation and pyroptosis in Nfe2l1(f)-KO mice could be mitigated by cold exposure or β3-agonist treatment. These findings provided a deeper insight into the function of NFE2L1 in the metabolic programming of brown adipocytes.

Project description:Lipid overload and adipocyte dysfunction are key to the development of insulin resistance and can be induced by a high-fat diet. CD1d-restricted invariant natural killer T (iNKT) cells have been proposed as mediators between lipid overload and insulin resistance, but recent studies found decreased iNKT cell numbers and marginal effects of iNKT cell depletion on insulin resistance under high-fat diet conditions. Here, we focused on the role of iNKT cells under normal conditions. We showed that iNKT cell–deficient mice on a low-fat diet, considered a normal diet for mice, displayed a distinctive insulin resistance phenotype without overt adipose tissue inflammation. Insulin resistance was characterized by adipocyte dysfunction, including adipocyte hypertrophy, increased leptin, and decreased adiponectin levels. The lack of liver abnormalities in CD1d-null mice together with the enrichment of CD1d-restricted iNKT cells in both mouse and human adipose tissue indicated a specific role for adipose tissue–resident iNKT cells in the development of insulin resistance. Strikingly, iNKT cell function was directly modulated by adipocytes, which acted as lipid antigen-presenting cells in a CD1d-mediated fashion. Based on these findings, we propose that, especially under low-fat diet conditions, adipose tissue–resident iNKT cells maintain healthy adipose tissue through direct interplay with adipocytes and prevent insulin resistance. four samples

Project description:Transcription factor NRF1 (NFE2L1) has been reported to be activated by proteasome disfunction, although the target genes are poorly understood. We used microarrays to identify NRF3-regulated gene expression network related to proteostasis.

Project description:Lipid overload and adipocyte dysfunction are key to the development of insulin resistance and can be induced by a high-fat diet. CD1d-restricted invariant natural killer T (iNKT) cells have been proposed as mediators between lipid overload and insulin resistance, but recent studies found decreased iNKT cell numbers and marginal effects of iNKT cell depletion on insulin resistance under high-fat diet conditions. Here, we focused on the role of iNKT cells under normal conditions. We showed that iNKT cell–deficient mice on a low-fat diet, considered a normal diet for mice, displayed a distinctive insulin resistance phenotype without overt adipose tissue inflammation. Insulin resistance was characterized by adipocyte dysfunction, including adipocyte hypertrophy, increased leptin, and decreased adiponectin levels. The lack of liver abnormalities in CD1d-null mice together with the enrichment of CD1d-restricted iNKT cells in both mouse and human adipose tissue indicated a specific role for adipose tissue–resident iNKT cells in the development of insulin resistance. Strikingly, iNKT cell function was directly modulated by adipocytes, which acted as lipid antigen-presenting cells in a CD1d-mediated fashion. Based on these findings, we propose that, especially under low-fat diet conditions, adipose tissue–resident iNKT cells maintain healthy adipose tissue through direct interplay with adipocytes and prevent insulin resistance.

Project description:Toll-like receptors/Interleukin-1 receptor (IL-1R) signaling plays an important role in High-fat diet (HFD)-induced adipose tissue dysfunction contributing to obesity-associated metabolic syndromes. Here, we show an unconventional IL-1R-IRAKM (IL-1R-associated kinase M)-Slc25a1 signaling axis in adipocytes that reprograms lipogenesis to promote diet-induced obesity. Adipocyte-specific deficiency of IRAKM reduced HFD-induced body weight gain, increased whole body energy expenditure and improved insulin resistance, associated with decreased lipid accumulation and adipocyte cell sizes. IL-1β stimulation induced the translocation of IRAKM Myddosome to mitochondria to promote de novo lipogenesis in adipocytes. Mechanistically, IRAKM interacts with and phosphorylates mitochondrial citrate carrier Slc25a1 to promote IL-1β-induced mitochondrial citrate transport to cytosol and de novo lipogenesis. Moreover, IRAKM-Slc25a1 axis mediates IL-1β induced Pgc1a acetylation to regulate thermogenic gene expression in adipocytes. IRAKM kinase-inactivation also attenuated HFD-induced obesity. Taken together, our study suggests that the IL-1R-IRAKM-Slc25a1 signaling axis tightly links inflammation and adipocyte metabolism, indicating a novel therapeutic target for obesity.

Project description:The maintenance of protein homeostasis is an essential characteristic of life. Transcription factor NRF1 (NFE2L1) has been reported to be activated by proteasome dysfunction, although the genome-wide target genes are poorly understood. Using ChIP-seq analysis, we found a potential association between NRF1 and autophagy. Our findings highlight the new activation mechanism of autophagy through gene regulation under proteasome dysfunction.

Project description:We developed a novel network inference approach, Biologically Anchored Knowledge Expansion (BAKE), to analyze large volume gene expression data obtained from a mouse model of insulin resistance progression. Both genetic aspects and dietary factors, specifically high caloric high-fat high-sugar diets, contribute to the progression of insulin resistance. To mimic genetic predisposition, we used a mouse model with double heterozygous deletion of early insulin signaling pathway intermediates, insulin receptor (IR) and insulin receptor substrate 1 (IRS1) genes. These mice were fed with high-fat (Western) or low-fat (Chow) diet for 8 and 16 weeks starting at 8 weeks of age. Gene expression data was collected from adipocytes isolated from these mice. Applying BAKE analysis to the adipocyte gene expression data, we demonstrate that we can accurately discover a novel regulatory gene in the insulin signaling pathway. The mouse model of double heterozygous deletion of insulin receptor (IR) and insulin receptor substrate 1 (IRS1) was originally introduced as a polygenic model to study the development of type 2 diabetes. This mouse model, on an atherosclerosis-prone ApoE null background (IR+/- IRS1+/- ApoE-/-), also shows increased atherosclerotic lesions due to impaired insulin signaling. For our study we used female double heterozygous mice (IR+/- IRS1+/-, 'Dhet' mice or 'D’ mice) on an ApoE null background (ApoE-/-, ‘E’) fed with a Western (high-fat) diet for 8 (DW8, n=5) and 16 (DW16, n=9) weeks starting at 8 weeks of age or with a Chow (low-fat) diet (DC8, n=7; DC16, n=5). There were also ApoE null mice (ApoE-/-, 'E’) fed either Western diet for 8 (EW8, n=6) and 16 (EW16, n=8) weeks or Chow diet for 16 weeks (EC16, n=5) starting at 8 weeks of age.

Project description:Adipocytes are key regulators of human metabolism, and their dysfunction in insulin signaling is central to metabolic diseases including type II diabetes mellitus (T2D). However, the progression of insulin resistance into T2D is still poorly understood. This limited understanding is due, in part, to the dearth of suitable models of insulin signaling in human adipocytes. Traditionally, adipocyte models fail to recapitulate in vivo insulin signaling, possibly due to exposure to supraphysiological nutrient and hormone conditions. We developed a protocol for hPSC-derived adipocytes that uses physiological nutrient conditions to produce a potent insulin response comparable to in vivo adipocytes. After systematic optimization, this protocol allows robust insulin-stimulated glucose uptake and transcriptional insulin response. Furthermore, exposure of sensitized adipocytes to physiological hyperinsulinemia dampens insulin-stimulated glucose uptake and dysregulates insulin-responsive transcription. Overall, our methodology provides a novel platform for the mechanistic study of insulin signaling and resistance using human pluripotent stem cell-derived adipocytes.