Project description:Evidence is emerging that skeletal muscle metabolic reprogramming could be a modifier of hepatic steatosis. Skeletal muscle-specific Mll4-knockout (MLL4SETf/fHSA-Cre) and wild-type (WT) littermates were placed on HFD (60% kcal from fat). Interestingly, muscle MLL4 deficiency prevents HFD-induced hepatic steatosis. To gain insight into the liver metabolic reprogramming in MLL4SETf/fHSA-Cre mice, we performed RNA-Seq analysis on mRNA isolated from liver of the MLL4SETf/fHSA-Cre mice and littermate controls. Gene ontology (GO) analysis of down-regulated genes revealed significant enrichment in lipid metabolic process, inflammatory response as well as collagen fibril organization. Conversely, pathways of oxidation-reduction and epoxygenase P450 were significantly enriched in the upregulated gene set. Gene expression validation studies demonstrated that the expression of the gene encoding lipid uptake and de novo lipogenesis was reduced in HFD-fed MLL4SETf/fHSA-Cre liver, concomitant with an increased in the expression of the oxidation-reduction genes. These findings suggest that MLL4 deletion in skeletal muscle decreases lipid uptake and denovo lipogenesis in the liver, leading to protection from HFD-induced hepatic steatosis.

Project description:This experiment was conducted to identify novel MLL4 targets in skeletal muscle 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. Here, we identified the genome-wide MLL4 occupancy in mouse skeletal muscle by ChIP-seq coupled with RNA-seq analysis. Gene ontology analysis revealed that MLL4 controls muscle fiber-type switching. We thus have revealed novel MLL4 targets involved in muscle metabolism.

Project description:This experiment was conducted to identify mRNA transcripts alteration in skeletal muscle of MLL4SET muscle-specific knockout mice. 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. Here, we identified the genome-wide MLL4 occupancy in mouse skeletal muscle by ChIP-seq coupled with RNA-seq analysis. Gene ontology analysis revealed that MLL4 controls muscle fiber-type switching. We thus have revealed novel MLL4 targets involved in muscle metabolism.

Project description:High fat feeding is deleterious for skeletal muscle metabolism, while exercise has well documented beneficial effects for these same metabolic features. To identify the genomic mechanisms by which exercise ameliorates some of the deleterious effects of high fat feeding, we investigated the transcriptional and epigenetic response of human skeletal muscle to 9 days of a high-fat diet (HFD) alone (Sed-HFD) or in combination with resistance exercise (Ex-HFD), using genome-wide profiling of gene expression (by RNA-seq) and DNA methylation (by Reduced Representation Bisulfite Sequencing). HFD markedly induced expression of immune and inflammatory genes which was not attenuated by Ex. In contract, Ex markedly remodelled expression of genes associated with muscle growth and structure. We detected marked DNA methylation changes following HFD alone and in combination with Ex. Among the genes that showed significant association between DNA methylation changes and gene expression were glycogen phosphorylase, muscle associated (PYGM), which was epigenetically regulated in both groups, and angiopoiten like 4 (ANGPTL4), which was regulated only following Ex. We conclude that Short-term Ex does not prevent HFD-induced inflammatory response, but provokes a genomic response that may preserve skeletal muscle from atrophy. Epigenetic adaptation provides important mechanistic insight into the gene specific regulation of inflammatory and metabolic processes in human skeletal muscle.

Project description:High fat feeding is deleterious for skeletal muscle metabolism, while exercise has well documented beneficial effects for these same metabolic features. To identify the genomic mechanisms by which exercise ameliorates some of the deleterious effects of high fat feeding, we investigated the transcriptional and epigenetic response of human skeletal muscle to 9 days of a high-fat diet (HFD) alone (Sed-HFD) or in combination with resistance exercise (Ex-HFD), using genome-wide profiling of gene expression (by RNA-seq) and DNA methylation (by Reduced Representation Bisulfite Sequencing). HFD markedly induced expression of immune and inflammatory genes which was not attenuated by Ex. In contract, Ex markedly remodelled expression of genes associated with muscle growth and structure. We detected marked DNA methylation changes following HFD alone and in combination with Ex. Among the genes that showed significant association between DNA methylation changes and gene expression were glycogen phosphorylase, muscle associated (PYGM), which was epigenetically regulated in both groups, and angiopoiten like 4 (ANGPTL4), which was regulated only following Ex. We conclude that Short-term Ex does not prevent HFD-induced inflammatory response, but provokes a genomic response that may preserve skeletal muscle from atrophy. Epigenetic adaptation provides important mechanistic insight into the gene specific regulation of inflammatory and metabolic processes in human skeletal muscle.

Project description:The popularity of high fat foods in modern society has been associated with epidemic of various metabolic diseases characterized by insulin resistance, the pathology of which involves complex interactions between multiple tissues such as liver, skeletal muscle and white adipose tissue (WAT). To uncover the mechanism by which excessive fat impairs insulin sensitivity, we conducted a multi- tissue study by using TMT-based quantitative proteomics. 3-week-old ICR mice were fed with high fat diet (HFD) for 19 weeks to induce insulin resistance. Liver, skeletal muscle and epididymal fat were collected for proteomics screening. Additionally, PRM was used for validating adipose differential proteins. By comparing tissue-specific protein profiles of HFD mice, multi-tissue regulation of glucose and lipid homeostasis and corresponding underlying mechanisms was systematically investigated and characterized.

Project description:Effects of EPA/DHA enriched high fat diets (HFD) compared to HFD-Corn oil after 8 weeks intervention on age/obesity induced skeletal muscle degradation. Results provides novel information on the signalling pathways regulated by EPA and DHA enriched HFD in delaying the onset of muscle degradation in C57Bl/6J mice compared with HFD-Corn oil.

Project description:Physical inactivity and over-nutrition are key risk factors for metabolic diseases, with impaired skeletal muscle gene transcription and metabolic function proposed as key etiological factors. Here, we have used RNA-seq to assessed the skeletal muscle transcriptome from mice fed a control or high fat diet (HFD), both pre- and 3h post-exercise. HFD up-regulated genes involved in lipid catabolism in skeletal muscle (quadriceps), while decreasing 241 exercise-responsive genes related to skeletal muscle plasticity. Collectively, this experimental approach provides a suitable resource to study transcriptional and metabolic networks in skeletal muscle in the context of health and disease.

Project description:The popularity of high fat foods in modern society has been associated with epidemic of various metabolic diseases characterized by insulin resistance, the pathology of which involves complex interactions between multiple tissues such as liver, skeletal muscle and white adipose tissue (WAT). To uncover the mechanism by which excessive fat impairs insulin sensitivity, we conducted a multi- tissue study by using TMT-based quantitative proteomics. 3-week-old ICR mice were fed with high fat diet (HFD) for 19 weeks to induce insulin resistance. Liver, skeletal muscle and epididymal fat were collected for proteomics screening. Additionally, PRM was used for validating adipose differential proteins. By comparing tissue-specific protein profiles of HFD mice, multi-tissue regulation of glucose and lipid homeostasis and corresponding underlying mechanisms was systematically investigated and characterized. NC: normal birth weight + chow diet; NH: normal birth weight + high fat diet; LC: low birth weight + chow diet; LH: low birth weight + high fat diet.

Project description:Enhancers play a central role in cell-type-specific gene expression and are marked by H3K4me1/2. Active enhancers are further marked by H3K27ac. However, the methyltransferases responsible for the deposition of H3K4me1/2 on enhancers remain elusive. Furthermore, the functions of these methyltransferases on enhancers and associated cell-type-specific gene expression are poorly understood. Here, we identify MLL4 (KMT2D) as a major H3K4 mono- and di-methyltransferase in mammalian cells. Using adipogenesis and myogenesis as model systems, we show that MLL4 exhibits cell-type- and differentiation-stage-specific genomic binding and is predominantly localized on enhancers. MLL4 co-localizes with lineage-determining transcription factors (TFs) on active enhancers during differentiation. Deletion of MLL4 dramatically decreases H3K4me1/2 and H3K27ac on enhancers and leads to severe defects in cell-type-specific gene expression and cell differentiation. Finally, we provide evidence that lineage-determining TFs recruit and require MLL4 to establish enhancers critical for cell-type-specific gene expression. Together, these results identify MLL4 as an H3K4 mono-/di-methyltransferase required for enhancer activation during cell differentiation. ChIP-Seq analyses of C/EBPbeta, MLL4 and histone modifications (H3K4me1, H3K27ac) in vec- or C/EBPbeta-overexpressing, adenoviral GFP- or Cre-infected, MLL3-/-MLL4-flox/flox brown preadipocytes without induction of differentiation.