Project description:Metabolic stress and changes in nutrient levels modulate many aspects of skeletal muscle function during aging and disease. Growth factors and cytokines secreted by skeletal muscle, known as myokines, are important signaling factors but it is largely unknown whether they modulate muscle growth and differentiation in response to nutrients. Here, we find that changes in glucose levels increase the activity of the glucose-responsive transcription factor MLX, which promotes and is necessary for myoblast fusion. MLX promotes myogenesis not via an adjustment of glucose metabolism but rather by inducing the expression of several myokines, including insulin like-growth factor-2 (IGF2), whereas RNAi and dominant-negative MLX reduce IGF2 expression and block myogenesis. This phenotype is rescued by conditioned media from control muscle cells and by recombinant IGF2, which activates the myogenic kinase Akt. Importantly, MLX null mice display decreased IGF2 induction and diminished muscle regeneration in response to injury, indicating that the myogenic function of MLX is conserved in vivo. Thus, glucose is a signaling molecule that regulates myogenesis and muscle regeneration via MLX/IGF2/Akt signaling.â??The data pproided are histome H4 acetlation data for MLX DN and MLX wt samples; 3 MLX DN H4 Ac Chip seq samples , 3 Inputs, 3 MLX WT H4 Ac samples and 3 WT inputs

Project description:Circadian phase-dependent myoblast differentiation and muscle regeneration

Project description:Metabolic stress and changes in nutrient levels modulate many aspects of skeletal muscle function during aging and disease. Growth factors and cytokines secreted by skeletal muscle, known as myokines, are important signaling factors but it is largely unknown whether they modulate muscle growth and differentiation in response to nutrients. Here, we find that changes in glucose levels increase the activity of the glucose-responsive transcription factor MLX, which promotes and is necessary for myoblast fusion. MLX promotes myogenesis not via an adjustment of glucose metabolism but rather by inducing the expression of several myokines, including insulin like-growth factor-2 (IGF2), whereas RNAi and dominant-negative MLX reduce IGF2 expression and block myogenesis. This phenotype is rescued by conditioned media from control muscle cells and by recombinant IGF2, which activates the myogenic kinase Akt. Importantly, MLX null mice display decreased IGF2 induction and diminished muscle regeneration in response to injury, indicating that the myogenic function of MLX is conserved in vivo. Thus, glucose is a signaling molecule that regulates myogenesis and muscle regeneration via MLX/IGF2/Akt signaling. The data pproided are histome H4 acetlation data for MLX DN and MLX wt samples;

Project description:Fibroblasts can be reprogrammed to induced neurons (iNs) via transducion of Ascl1, Brn2, and Myt1l. To understand the roles of the circadian regulators Per1 and Per2 on the reprogramming, embryonic fibroblasts from wild type (WT), Per1-/-, and Per2-/- mice were transduced with the three genes and cells were harvested for scRNA-seq on days 4, 7, and 10 after transduction.

Project description:Long noncoding RNAs (lncRNAs) are involved in the regulation of skeletal muscle development. In the present study, differentially expressed lncRNAs were identified from RNA-seq data derived from myoblasts and myotubes. We conducted studies to elucidate the function and molecular mechanism of action of Linc-smad7 during skeletal muscle development. Our findings show that Linc-smad7 is upregulated during the early phase of myoblasts differentiation. In in vitro studies, we showed that overexpression of Linc-smad7 promoted the arrest of myoblasts in G1 phase, inhibited DNA replication, and induced myoblast differentiation. Our in vivo studies suggest that Linc-smad7 stimulates skeletal muscle regeneration in cardiotoxin-induced muscle injury. Mechanistically, Linc-smad7 overexpression increased smad7 and IGF2 protein levels. On the contrary, overexpression of miR-125b reduced smad7 and IGF2 protein levels. Results of RNA immunoprecipitation analysis and biotin-labeled miR-125b capture suggest that Linc-smad7 could act as a competing endogenous RNA (ceRNA) for miRNA-125b. Taken together, our findings suggest that the novel noncoding regulator Linc-smad7 regulates skeletal muscle development.

Project description:The regeneration of skeletal muscle relies on satellite cells which can proliferate, differentiate and form new myofibers upon injury. Emerging evidence suggests that misregulations of satellite cell fate and function influence the severity of Duchenne Muscular Dystrophy (DMD). The myogenic identity and maintenance of the pool of satellite cells is determined by the transcription factor PAX7. Satellite cell proliferation and self-renewal is regulated by the circadian clock. Here, we show that the CLOCK-interacting protein, Circadian (CIPC), a negative-feedback regulator of the circadian clock, is up-regulated during myoblast differentiation. Specific deletion of CIPC in satellite cells alleviated myopathy, improved muscle function and reduced fibrosis in mdx mice. CIPC deficiency led to activation of the ERK1/2 and JNK1/2 signaling pathways, which in turn activated the transcription factor SP1 to trigger the transcription of PAX7. Therefore, CIPC is a negative regulator of satellite cell function and loss of CIPC in satellite cells promotes muscle regeneration.

Project description:Healthy skeletal muscle can regenerate after ischaemic, mechanical, or toxin-induced injury, but ageing impairs that regeneration potential. This has been largely attributed to dysfunctional satellite cells and reduced myogenic capacity. Understanding which signalling pathways are associated with reduced myogenesis and impaired muscle regeneration can provide valuable information about the mechanisms driving muscle ageing and prompt the development of new therapies. To investigate this, we developed a high-throughput in vitro model to assess muscle regeneration in chemically injured C2C12 and human myotube-derived young and aged myoblast cultures. We observed a reduced regeneration capacity of aged cells, as indicated by an attenuated recovery towards preinjury myotube size and myogenic fusion index at the end of the regeneration period, in comparison with younger muscle cells that were fully recovered. RNA-sequencing data showed significant enrichment of KEGG signalling pathways, PI3K-Akt, and downregulation of GO processes associated with muscle development, differentiation, and contraction in aged but not in young muscle cells. Data presented here suggests that repair in response to in vitro injury is impaired in aged vs. young muscle cells. Our study establishes a framework that enables further understanding of the factors underlying impaired muscle regeneration in older age.

Project description:a circadian proteome atlas of eight organs, namely suprachiasmatic nucleus (SCN), hypothalamus (HPOA), liver (LIV), gall bladder (GBD), brown adipose tissue (BAT), kidney (KDN), heart (HEA) and muscle (MUS), from wild-type (WT) and Per1-/-/Per2-/- (DKO) mice housed under constant darkness and ad libitum feeding, collected every two hours for deep proteomic analysis over two days

Project description:In this study, we deciphered the functions of Dhx36 and related molecular mechanisms in muscle stem cells and muscle regeneration. We found Dhx36 was highly induced in activated muscle stem cells during regeneration induced by injury. Conditional inactivation of Dhx36 in mouse muscle stem cells caused significant impaired regeneration, which was due to the dramatically decreased cell proliferation. Dhx36 was a well-known RNA helicase for binding/unbinding DNA/RNA G-quadruplexes and it was dominantly expressed in cytoplasm of proliferating myoblast. Therefore CLIP-seq was conducted to identify the mRNAs interacting with Dhx36 in myoblast cells.

Project description:Retinal photoreceptors undergo daily renewal of their distal outer segments, a process indispensable for maintaining retinal health. Photoreceptor Outer Segment (POS) phagocytosis occurs as a daily peak, roughly about one hour after light onset. However, the underlying cellular and molecular mechanisms which initiate this process are still unknown. Here we show that, under constant darkness, mice deficient for core circadian clock genes (Per1 and Per2), lack a daily peak in POS phagocytosis. By qPCR analysis we found that core clock genes were rhythmic over 24h in both WT and Per1, Per2 double mutant whole retinas. More precise transcriptomics analysis of laser capture microdissected WT photoreceptors revealed no differentially expressed genes between time-points preceding and during the peak of POS phagocytosis. By contrast, we found that microdissected WT retinal pigment epithelium (RPE) had a number of genes that were differentially expressed at the peak phagocytic time-point compared to adjacent ones. We also found a number of differentially expressed genes in Per1, Per2 double mutant RPE compared to WT ones at the peak phagocytic time-point. Finally, based on STRING analysis we found a group of interacting genes which potentially drive POS phagocytosis in the RPE. This potential pathway consists of genes such as: Pacsin1, Syp, Camk2b and Camk2d among others. Our findings indicate that Per1 and Per2 are necessary clock components for driving POS phagocytosis and suggest that this process is transcriptionally driven by the RPE.