Project description:The circadian clock component REVERBα is considered a dominant regulator of lipid metabolism, with global Reverbα deletion driving dysregulation of white adipose tissue (WAT) lipogenesis and obesity. However, a similar phenotype is not observed under adipocyte-selective deletion (ReverbαFlox2-6AdipoCre), and transcriptional profiling demonstrates that, under basal conditions, direct targets of REVERBα regulation are limited, and include the circadian clock and collagen dynamics. Under high-fat diet (HFD) feeding, ReverbαFlox2-6AdipoCre mice do manifest profound obesity, yet without the accompanying WAT inflammation and fibrosis exhibited by controls. Integration of the WAT REVERBα cistrome with differential gene expression reveals broad control of metabolic processes by REVERBα which is unmasked in the obese state.

Project description:The nuclear receptor REVERBα is a core component of the circadian clock and proposed to be a dominant regulator of hepatic lipid metabolism. We perform in vivo antibody-independent ChIP-sequencing of endogenously-expressed REVERBα, in order to map its cistrome and so define its repressive targets. We find that REVERBα binding sites harbour consensus RORE or RevDR2 motifs, and overlap with corepressor complex binding, without over-representation of putative tethering factors. When Reverbα is deleted in a hepatocyte-selective fashion, only modest physiological and transcriptional effects are seen, with de-repressed target genes tightly associating with REVERBα binding sites. Thus, contrary to previous reports, REVERBα does not repress lipogenesis under basal conditions. REVERBα control of a more extensive transcriptional programme is revealed only by perturbation (the metabolically abnormal global Reverbα-/- mouse, or acutely mistimed feeding), supporting instead a role for this core clock protein in buffering against metabolic challenge.

Project description:The nuclear receptor REVERBα is a core component of the circadian clock and proposed to be a dominant regulator of hepatic lipid metabolism. We perform in vivo antibody-independent ChIP-sequencing of endogenously-expressed REVERBα, in order to map its cistrome and so define its repressive targets. We find that REVERBα binding sites harbour consensus RORE or RevDR2 motifs, and overlap with corepressor complex binding, without over-representation of putative tethering factors. When Reverbα is deleted in a hepatocyte-selective fashion, only modest physiological and transcriptional effects are seen, with de-repressed target genes tightly associating with REVERBα binding sites. Thus, contrary to previous reports, REVERBα does not repress lipogenesis under basal conditions. REVERBα control of a more extensive transcriptional programme is revealed only by perturbation (the metabolically abnormal global Reverbα-/- mouse, or acutely mistimed feeding), supporting instead a role for this core clock protein in buffering against metabolic challenge.

Project description:We identified differentially expressed genes in epididymal white adipose tissue of high fat diet(HFD)-fed mice compared to low fat diet-fed mice using microarray analysis. Microarray analysis revealed that genes related to lipolysis, fatty acid metabolism, mitochondrial energy transduction, oxidation-reduction, insulin sensitivity, and skeletal system development were downregulated in HFD-fed mice, and genes associated with extracellular matrix (ECM) components, ECM remodeling, and inflammation were upregulated. The top 10 up- or downregulated genes include Acsm3, mt-Nd6, Fam13a, Cyp2e1, Rgs1, and Gpnmb, whose roles in obesity-associated adipose tissue deterioration are poorly understood. Total RNA of epididymal white adipose tissue was obtained from low fat diet (10 kcal% fat)- and high fat diet(45 kcal% fat)-fed mice and mRNA expression was measured using microarray analysis.

Project description:Adipose tissues display a remarkable ability to adapt to the dietary status. Here, we have applied single-nucleus RNA-seq to map the plasticity of mouse epididymal white adipose tissue at single cell resolution in response to high-fat diet-induced obesity. The single-nucleus approach allowed us to recover all major cell types and to reveal distinct transcriptional stages along the entire adipogenic trajectory from preadipocyte commitment to mature adipocytes. We demonstrate the existence of different adipocyte subpopulations and show that obesity leads to disappearance of the lipogenic subpopulation and increased abundance of the stressed lipid scavenging subpopulation. Moreover, obesity is associated with major changes in the abundance and gene expression of other cell populations, including a dramatic increase in lipid handling genes in macrophages at the expense of macrophage-specific genes. The data provide a powerful resource for future hypothesis-driven investigations of the mechanisms of adipocyte differentiation and adipose tissue plasticity.  

Project description:Beneficial effects have been reported in individuals undergoing fasting to treat excessive weight gain and obesity. To better understand the effects of starvation on the transcriptome and lipid metabolism of white adipose tissue, we established a mouse model of 24-hour fasting using wild type C57BL/6J mice, and performed RNA-seq analysis of the white adipose tissue from the epididymis of fasted mice and control mice. Compared with the control fed mice, these fasted mice showed suppressed lipid synthesis and inhibited insulin signaling, while the lipolysis and gluconeogenesis were enhanced to maintain blood sugar stability. Specifically, the fasted mice had reduced volume of adipose tissues, increased levels of serum NEFA and ANP. In epididymal white adipose tissue, starvation increased the NEFA content, up-regulated the mRNA levels of Atgl, Adrb2, Anp, and Npr1, and promoted the phosphorylation of Hsl. Notably, bioinformatics analysis of the RNA-seq data showed that 24-hour fasting-induced alterations in lipid metabolism was associated with suppressed AMPK signaling and enhanced PPAR signaling in white adipose tissue, which was verified by quantitative PCR. Collectively, these findings supported that starvation promoted the conversion of energy-supplying substrates from glucose to fat. Our work sheds new light on harnessing the plasticity of adipose tissues and the AMPK/PPAR signaling pathways to develop potential strategies to combat obesity and other glucose/lipid metabolisms-associated human diseases.

Project description:Background/Objectives: The aim of the current study was to elucidate the effects of long-term supplementation with dietary ursolic acid (UR) on obesity and associated comorbidities, such as hepatic fibrosis, by analyzing transcriptional and metabolic responses, focusing on the role of UR in the modulation of the circadian rhythm pathway in particular. Subjects/Methods: C57BL/6J mice were divided into three groups and fed a normal diet, high-fat diet (HFD), or high-fat + 0.05% (w/w) UR diet for 16 weeks. Results: Oligonucleotide microarray profiling revealed that the liver transcriptome was more significantly altered by UR supplementation than that of the skeletal muscle and epididymal white adipose tissue, suggesting that UR is an effective regulator of the liver transcriptome. Furthermore, Kyoto Encyclopedia of Genes and Genomes pathway mapper analyses showed that canonical pathways associated with the “circadian rhythm” and “extracellular matrix (ECM)-receptor interactions” were effectively regulated by UR in the liver. UR altered the expression of various clock and clock-controlled genes (CCGs), which may be linked to the improvement of hepatic steatosis and fibrosis via lipid metabolism control and detoxification enhancement. UR reduced excessive reactive oxygen species production via an increase in plasma paraoxonase activity, adipokine/cytokine dysregulation, and ECM accumulation in the liver, which also contributed to improve hepatic lipotoxicity and fibrosis. In addition, UR treatment improved and normalized pancreatic islet dysfunction, and suppressed hepatic gluconeogenesis, thereby reducing obesity-associated insulin resistance in HFD-fed mice. Conclusions: Therapeutic approaches targeting hepatic circadian clock and CCGs using UR may ameliorate the deleterious effects of diet-induced obesity and associated complications such as hepatic fibrosis.

Project description:Colorectal cancer (CRC) is one of the most common cancers in the world, and its causes are related to diet and obesity. Currently, crosstalk between fat metabolism and CRC has been reported, but the specific mechanism of crosstalk remains to be further studied. In this study, we screened Differentially Expressed lncRNAs and mRNAs from primary cancer tissue, paracancer tissue and white adipose tissue of patients with CRC.Then, by screening and analyzing the genes which differed between primary and paracancer tissues, as well as between paracancer tissues and white adipose tissue, but not between primary and white adipose tissue, we found that lncRNA (MIR503HG) may be involved in the cross-talk between CRC and lipid metabolism through exosome delivery. Although our sample were limited, this study raises the possibility of cross-talk between lipid metabolism and CRC through exosome delivery of lncRNAs.

Project description:We identified differentially expressed genes in epididymal white adipose tissue of high fat diet(HFD)-fed mice compared to low fat diet-fed mice using microarray analysis. Microarray analysis revealed that genes related to lipolysis, fatty acid metabolism, mitochondrial energy transduction, oxidation-reduction, insulin sensitivity, and skeletal system development were downregulated in HFD-fed mice, and genes associated with extracellular matrix (ECM) components, ECM remodeling, and inflammation were upregulated. The top 10 up- or downregulated genes include Acsm3, mt-Nd6, Fam13a, Cyp2e1, Rgs1, and Gpnmb, whose roles in obesity-associated adipose tissue deterioration are poorly understood.

Project description:The pleiotropic function of long noncoding RNAs is well recognized, but their direct role in governing metabolic homeostasis is less understood. Here, we describe a human adipocyte-specific lncRNA, ADIPINT, that regulates pyruvate carboxylase , a pivotal enzyme in energy metabolism. With a novel approach, Targeted RNA-protein identification using Orthogonal Organic Phase Separation, and validation with electron microscopy, we show that ADIPINT binds to PC. ADIPINT knockdown alters the interactome and decreases the abundance and enzymatic activty of PC in the mitochondria. Reduced ADIPINT or PC expression lowers adipocyte lipid synthesis, breakdown, and lipid content. In human white adipose tissue, ADIPINT expression is increased in obesity and linked to fat cell size, adipose insulin resistance, and PC activity. Thus, we identify ADIPINT as a regulator of lipid metabolism in human white adipocytes, which at least in part is mediated through its interaction with PC.