Project description:Enhancers play central role in controlling gene expression in time and space. Primed enhancers are marked by histone H3 lysine 4 (H3K4) mono/di-methylation (H3K4me1/2). Mixed-lineage leukemia 4 (MLL4/KMT2D) is an evolutionarily conserved H3K4me1/2 methyltransferase that is required for enhancer activation. To investigate the physiological importance of MLL4 in skeletal muscle nutrient handling, skeletal muscle-specific Mll4-knockout (MLL4SETf/fHSA-Cre) and wild-type (WT) littermates were placed on HFD (60% kcal from fat). Remarkably, muscle-specific deletion of MLL4 protects against high-fat diet-induced obesity and improves systemic glucose homeostasis. To dissect the underline mechanism, we conducted a comprehensive study of the muscle transcriptome induced by MLL4 deletion, HFD feeding, or the combination. Comparison of gene expression profiles in MLL4SETf/f muscle revealed 638 genes in total whose expression was significantly regulated by HFD, and comparison between WT and MLL4SETf/fHSA-Cre muscle showed 1430 and 1490 genes that were influenced by MLL4 abrogation on CD and HFD, respectively. Categorized into four subgroups, gene ontology (GO) pathway analysis not only showed HFD-induced immune and inflammatory pathways that were suppressed by MLL4 deficiency, but also revealed muscle metabolic and contractile gene networks that were substantially altered by MLL4 abrogation.

Project description:Individuals with hepatic steatosis often display several metabolic abnormalities including insulin resistance and muscle atrophy. Previously, we found that hepatic steatosis results in an altered hepatokine secretion profile, thereby inducing skeletal muscle insulin resistance via inter-organ crosstalk. In this study, we aimed to investigate whether the altered secretion profile in the state of hepatic steatosis also induces skeletal muscle atrophy via effects on muscle protein turnover. To investigate this, eight-week-old male C57BL/6J mice were fed a chow (4.5% fat) or a high-fat diet (HFD; 45% fat) for 12 weeks to induce hepatic steatosis, after which the livers were excised and cut into ~200 µm slices. Slices were cultured to collect secretion products (conditioned medium; CM). Differentiated L6-GLUT4myc myotubes were incubated with chow or HFD CM to measure glucose uptake. Differentiated C2C12 myotubes were incubated with chow or HFD CM to measure protein synthesis and breakdown, and gene expression via RNA sequencing. Furthermore, proteomics analysis was performed in chow and HFD CM. It was found that HFD CM caused insulin resistance in L6-GLUT4myc myotubes compared with chow CM, as indicated by a blunted insulin-stimulated increase in glucose uptake. Furthermore, protein breakdown was increased in C2C12 cells incubated with HFD CM, while there was no effect on protein synthesis. RNA profiling of C2C12 cells indicated that 197 genes were differentially expressed after incubation with HFD CM, compared with chow CM, and pathway analysis showed that pathways related to anatomical structure and function were enriched. Proteomic analysis of the CM showed that 32 proteins were differentially expressed in HFD CM compared with chow CM. Pathway enrichment analysis indicated that these proteins had important functions with respect to insulin-like Growth Factor transport and uptake, and affect post-translational processes, including protein folding, protein secretion and protein phosphorylation. In conclusion, the results of this study support the hypothesis that secretion products from the liver contribute to the development of muscle atrophy in individuals with hepatic steatosis.

Project description:Dysfunctional adipose tissue is believed to promote the development of hepatic steatosis and systemic insulin resistance, but many of the mechanisms involved are still unclear. Lipin 1 catalyzes the conversion of phosphatidic acid to diacylglycerol (DAG), the penultimate step of triglyceride synthesis, which is essential for lipid storage. Herein we found that adipose tissue LPIN1 expression is decreased in people with obesity compared to lean subjects and low LPIN1 expression correlated with multi-tissue insulin resistance and increased rates of hepatic de novo lipogenesis. Comprehensive metabolic and multi-omic phenotyping demonstrated that adipocyte-specific Lpin1-/- mice had a metabolically-unhealthy phenotype, including liver and skeletal muscle insulin resistance, hepatic steatosis, increased hepatic de novo lipogenesis, and transcriptomic signatures of nonalcoholic steatohepatitis that was exacerbated by high-fat diets. We conclude that adipocyte lipin 1-mediated lipid storage is vital for preserving adipose tissue and systemic metabolic health and its loss predisposes mice to nonalcoholic steatohepatitis.

Project description:Perfluorooctanesulfonic acid (PFOS) is a persistent, bio-accumulative pollutant that has been used for the last 60+ years in numerous industrial and commercial applications. In mice, PFOS administration is known to induce hepatomegaly and hepatic steatosis. The aim of the present study was to evaluate potential PFOS and diet interactions and explore the mechanism of PFOS induced liver lipid accumulation. Prior to PFOS administration, mice were fed either a standard chow diet (SD) or 60% kCal high fat diet (HFD) for 4 weeks to establish significant body weight increase. After 4 weeks of diet acclimation, the treatment groups received 0.0003% PFOS in diet for an additional 10 weeks. In addition, a subset of the mice fed HFD were switched to a SD (H-SD) to mimic weight-loss induced improvement of hepatic steatosis. A total of six treatment groups: i) SD, ii) HSD, iii) HFD (H), iv) SD +PFOS(SDP), v) H-SD +PFOS (HSDP), and vi) HFD +PFOS (HP) were included. PFOS and lipid concentrations were measured in both serum and liver. Relative liver mRNA expression was determined by targeted bead array and proteins were quantified using untargeted mass spectrometry. PFOS exposure increased liver weight, and in the HFD increased liver triglycerides and liver cholesterol content. Gene and protein expression in the liver demonstrated that PFOS exposure induced lipid utilization and xenobiotic metabolism pathways, and in a HFD, induced lipid synthesis. The data suggests that PFOS exposure acts on lipid utilization genes and exacerbates hepatic steatosis in mice fed a HFD.

Project description:The pathophysiologic continuum of non-alcoholic fatty liver disease begins with steatosis. Despite great progress in understanding the gene regulatory program directing steatosis, how it is orchestrated epigenetically is unclear. Here we show that the histone H3-lysine-4-methyltransferase, MLL4/KMT2D, plays critical roles in overnutrition-induced murine steatosis via dual mechanisms. First, in response to high fat diet (HFD), MLL4 activates the expression of PPARγ2, an overnutrition-induced steatotic transcription factor. Second, HFD enables the coactivator function of MLL4 for PPARγ2, as overnutrition-activated ABL1 kinase phosphorylates PPARγ2 and enhances its association with MLL4, facilitating recruitment of MLL4 to steatotic target genes of PPARγ2, including the PPARγ2-encoding gene itself, and their transactivation via H3-lysine-4-methylation. Consistently, inhibition of ABL1 improves the fatty liver condition of ob/ob mice by suppressing the pro-steatotic action of MLL4. Our results uncover a critical regulatory axis in overnutrition-directed steatosis, and present this ABL1-PPARγ2-MLL4 axis as a new target for anti-steatosis drug development.

Project description:A high-fructose diet (HFrD) fed rat model of hypertriglyceridemia, dyslipidemia, insulin resistance and hepatic steatosis was employed to investigate the global transcriptional changes in the lipid metabolizing pathways in three insulin sensitive tissues:, liver, skeletal muscle and adipose tissue in response to chronic dietary administration of NDGA.

Project description:Alternative mRNA splicing provides transcript diversity and has been proposed to contribute to several human diseases. Here, we demonstrate that expression of genes regulating RNA processing is decreased in both liver and skeletal muscle of obese humans. To determine the metabolic impact of reduced splicing factor expression, we further evaluated the splicing factor, SFRS10, identified as down-regulated in obese human liver and skeletal muscle and in high fat fed rodents. siRNA-mediated reductions in SFRS10 expression induced lipogenesis and lipid accumulation in cultured hepatocytes. Moreover, SFRS10 heterozygous mice have both increased hepatic lipogenic gene expression and hypertriglyceridemia. We also demonstrate that LPIN1, a key regulator of lipid metabolism, is a splicing target of SFRS10, with reduced SFRS10 levels favoring the lipogenic β isoform of LPIN1. Importantly, LPIN1β-specific siRNA abolished the lipogenic effects of decreased SFRS10 expression. Together, our results indicate reduced expression of SFRS10 alters LPIN1 splicing and induces lipogenesis, demonstrating that reduced splicing factor expression observed in human tissues may contribute to metabolic phenotypes associated with human obesity. Skeletal muscle samples were obtained from 10 lean control subjects and 7 obese subjects with either IGT or DM2 undergoing elective cholecystectomy. Data for liver samples presented in the same manuscript are available at GEO GSE15653. In this analysis RNA was isolated for cRNA preparation and hybridized to Affymetrix Human Genome U133 Plus 2.0 microarrays.

Project description:High Fructose Corn Syrup (HFCS), a sweetener rich in glucose and fructose, is nowadays widely used in beverages and processed foods, and its consumption has been correlated to the emergence and progression of Non-Alcoholic Fatty Liver Disease (NAFLD). Nevertheless, the exact molecular mechanisms by which HFCS impacts hepatic metabolism are still unclear, especially in the context of obesity. In contrast, the vast majority of current studies in the field focus either on the detrimental role of fructose on NAFLD or compare the additive impact of fructose versus glucose in this process. Besides, studies elaborating on the role of fructose in NAFLD utilize molecular fructose, rather than HFCS, thus lacking simulation of human NAFLD in a more realistic way. Herein, by engaging combined omic approaches, we sought to characterize the additive impact of HFCS on NAFLD during obesity and recognize candidate pathways and molecules which could mediate the exaggeration of steatosis under these conditions. To achieve this goal, C57BL/6 male mice were fed a normal-fat (ND), a high-fat (HFD) or a HFD supplemented with HFCS (HFD-HFCS) and upon examination of their metabolic and NAFLD phenotype, proteomic and lipidomic analyses were conducted and utilized separately or in an integrated mode to identify HFCS-related molecular alterations of the hepatic metabolic landscape. Although HFD and HFD-HFCS mice displayed comparable obesity, HFD-HFCS mice showed greater aggravation of hepatic steatosis. Importantly, the HFD-HFCS hepatic proteome was characterized by an upregulation of the enzymes implicated in de novo lipogenesis (DNL), while palmitic-acid containing diglycerides were significantly increased in the HFD-HFCS hepatic lipidome, as compared to the HFD group. Integrated omic analysis further suggested that TCA cycle overstimulation, is likely contributing towards the intensification of steatosis in the HFD-HFCS dietary theme. Overall, our results imply that HFCS may significantly contribute to NAFLD aggravation during obesity, with its fructose-rich properties being the main suspect.

Project description:We observed that Ildr2 knockdown via adenovirally-delivered shRNA (Adv-Ildr2 shRNA) causes hepatic steatosis in mice. Acute, liver-specific Ildr2 knockout mice generated by infecting C57BL/6J mice segregating for a floxed allele of Ildr2 with adenoviral Cre recombinase (Adv-Cre) do not develop hepatic steatosis. However, administration of Adv-Ildr2 shRNA to Ildr2 knockout mice (Ildr2floxed; albumin-cre) did cause hepatic steatosis, indicating that the Adv-Ildr2 shRNA had apparent “off-target” effects on gene(s) other than Ildr2. To determine additional targets of Ildr2 shRNA that may regulate hepatic lipid metabolism, we performed RNA sequencing on liver samples from (1) Adv-Ildr2 shRNA knockdown mice, (2) Adv-lacZ shRNA control mice, and (3) Adv-Cre Ildr2 knockout mice. For the purposes of our study, we sought to identify genes downregulated by Adv-Ildr2 shRNA, but unchanged in Adv-lacZ shRNA control or Adv-Cre Ildr2 knockout mice. The hepatic steatosis observed in Adv-Ildr2 shRNA knockdown mice was likely due to shRNA targeting of other “off-target” genes. We propose that the genes candidates identified in this sequencing experiment may lead to identification of novel regulators of hepatic lipid metabolism.

Project description:Non-alcoholic fatty liver disease (NAFLD) is characterized by excess lipid accumulation in hepatocytes and reprepresents a huge public health problem owing to its propensity to progress to non-alcoholic steatohepatitis (NASH), fibrosis, and liver failure. The lipids stored in hepatic steatosis are primarily triglycerides (TGs) synthesized by two acyl CoA:diacylglycerol acyltransferase (DGAT) enzymes. Either DGAT1 or DGAT2 catalyzes this reaction, and these enzymes have been suggested to differentially utilize exogenous or endogenously synthesized fatty acids, with DGAT2 being linked to storage of fatty acids from de novo lipogenesis, a process that is increased in NAFLD. However, whether DGAT2 is more responsible for lipid accumulation in NAFLD and the progression to fibrosis is currently unknown. Also, it is unresolved whether DGAT2 can be safely inhibited as a therapy for NAFLD. Here we induced NAFLD-like disease in mice by feeding a diet rich in fructose, saturated fat, and cholesterol and found that hepatocyte-specfici Dgat2 deficiency reduced expression of de novo lipogenesis genes and lowered liver TGs by ~70%. Importantly, the reduction of steatosis was not accompanied by increased inflammation or fibrosis, and insulin and glucose metabolism were unchanged. Conclusion: This study suggests that hepatic DGAT2 deficiency successfully reduced diet-induced hepatic steatosis and supports the development of DGAT2 inhibitors as a therapeutic strategy for treating NAFLD and preventing downstream consequences.