Project description:Cardiotoxin (CTX)-induced acute muscle injury is a paradigmatic self-limiting sterile injury model for exploring the tissue regeneration process, which consists of a series of tightly-regulated events, including an initial inflammatory response the activation of muscle stem cells (MuSCs, also termed satellite cells) during the early stage after injury, as well as later inflammation resolution along with MuSC proliferation and differentiation. This study set out to determine the potential impact of lipid 11,12-EET on murine MuSCs function.

Project description:During aging, the number and functionality of muscle stem cells (MuSCs) decreases leading to impaired regeneration of aged skeletal muscle. In addition to intrinsic changes in aged MuSCs, extracellular matrix (ECM) proteins deriving from other cell types, e.g., fibrogenic-adipogenic progenitor cells (FAPs), contribute to the aging phenotype of MuSCs and impaired regeneration in the elderly. So far, no comprehensive analysis on how age-dependent changes in the whole skeletal muscle proteome affect MuSC function have been conducted. Here, we investigated age-dependent changes in the proteome of different skeletal muscle types by applying deep quantitative mass spectrometry. We identified 183 extracellular matrix proteins that show different abundances in skeletal muscles of old mice. By integrating single cell sequencing data, we reveal that transcripts of those ECM proteins are mainly expressed in FAPs, suggesting that FAPs are the main contributors to ECM remodelling during aging. We functionally investigated one of those ECM molecules, namely Smoc2, which is aberrantly expressed during aging. We show that Smoc2 levels are elevated during regeneration and that its accumulation in the aged MuSC niche causes impairment of MuSCs function through constant activation of integrin/MAPK signaling. In vivo, supplementation of exogenous Smoc2 hampers the regeneration of young muscles following serial injuries, leading to a phenotype reminiscent of regenerating aged skeletal muscle. Taken together, we provide a comprehensive resource of changes in the composition of the ECM of aged skeletal muscles, we pinpoint the cell types driving these changes, and we identify a new niche protein causing functional impairment of MuSCs thereby hampering the regeneration capacity of skeletal muscles.

Project description:During aging, the number and functionality of muscle stem cells (MuSCs) decreases leading to impaired regeneration of aged skeletal muscle. In addition to intrinsic changes in aged MuSCs, extracellular matrix (ECM) proteins deriving from other cell types, e.g., fibrogenic-adipogenic progenitor cells (FAPs), contribute to the aging phenotype of MuSCs and impaired regeneration in the elderly. So far, no comprehensive analysis on how age-dependent changes in the whole skeletal muscle proteome affect MuSC function have been conducted. Here, we investigated age-dependent changes in the proteome of different skeletal muscle types by applying deep quantitative mass spectrometry. We identified 183 extracellular matrix proteins that show different abundances in skeletal muscles of old mice. By integrating single cell sequencing data, we reveal that transcripts of those ECM proteins are mainly expressed in FAPs, suggesting that FAPs are the main contributors to ECM remodelling during aging. We functionally investigated one of those ECM molecules, namely Smoc2, which is aberrantly expressed during aging. We show that Smoc2 levels are elevated during regeneration and that its accumulation in the aged MuSC niche causes impairment of MuSCs function through constant activation of integrin/MAPK signaling. In vivo, supplementation of exogenous Smoc2 hampers the regeneration of young muscles following serial injuries, leading to a phenotype reminiscent of regenerating aged skeletal muscle. Taken together, we provide a comprehensive resource of changes in the composition of the ECM of aged skeletal muscles, we pinpoint the cell types driving these changes, and we identify a new niche protein causing functional impairment of MuSCs thereby hampering the regeneration capacity of skeletal muscles.

Project description:Epoxyeicosatrienoic acids (EETs) are potent lipid mediators with well-established effects in vascular tissues. Recent studies indicated an emerging role of these eicosanoids in metabolic diseases and the EET signaling pathway was shown to be involved in hepatic insulin sensitivity. However, compared to vascular tissues, there is only limited knowledge about the underlying signaling pathways in the liver. Therefore, we employed an LC-MS/MS-based time-resolved phosphoproteomics approach to characterize 11,12-EET-mediated signaling events in the liver cell line Hepa 1-6. 11,12-EET treatment resulted in the time-dependent regulation of phosphopeptides involved in processes as yet unknown to be affected by EETs, including RNA processing, splicing and translation regulation. Pathway analysis combined with western blot-based validation revealed enhanced AKT/mTOR/p70S6K signaling as demonstrated by increased acute phosphorylation of AKT (Ser473) and p70S6K (Thr389). In addition, 11,12-EET treatment led to differential regulation of phosphopeptides including important mediators of the DNA damage response and we observed a prolonged induction of the etoposide-induced DNA damage marker γH2AX in response to 11,12-EET. In summary, our findings extend current knowledge of 11,12-EET signaling events and emphasize the importance of the AKT/mTOR/p70S6K pathway in hepatic 11,12-EET signaling. Based on the results presented in this study, we furthermore propose a novel role of EET signaling in the regulation of the DNA damage response.

Project description:In our previous study, we found zebrafish embryos treated with 5uM 11,12-EET (epoxyeicosatrienoic acid) had increased stem cell marker, runx1, expression in the AGM. EET also induced ectopic runx1 expression in the tail. To systematically study how EET regulates gene expression, we performed microarray analysis on EET-treated embryos. Zebrafish whole embryos were synchronized at fertilization. Embryos were grown at 28 degree overnight. 25 embryos per group were treated with DMSO or 5uM 11,12-EET starting from 24 hpf (hour post fertilization) until 36 hpf at 28 degree. The triplicates were from three different clutches of embryos, and split into DMSO v.s. EET for each clutch. EET vs. DMSO

Project description:In our previous study, we found zebrafish embryos treated with 5uM 11,12-EET (epoxyeicosatrienoic acid) had increased stem cell marker, runx1, expression in the AGM. EET also induced ectopic runx1 expression in the tail. To systematically study how EET regulates gene expression, we performed microarray analysis on EET-treated embryos. Zebrafish whole embryos were synchronized at fertilization. Embryos were grown at 28 degree overnight. 25 embryos per group were treated with DMSO or 5uM 11,12-EET starting from 24 hpf (hour post fertilization) until 36 hpf at 28 degree. The triplicates were from three different clutches of embryos, and split into DMSO v.s. EET for each clutch.

Project description:In aging, skeletal muscle strength and regenerative capacity declines due, in part, to functional impairment of muscle stem cells MuSCs, yet the underlying mechanisms remain elusive. Here we capitalize on mass-cytometry to identify high CD47 expression as a hallmark of dysfunctional MuSCs CD47hi with impaired regenerative capacity that predominate with aging. The prevalent CD47 hi MuSC subset suppresses the residual functional CD47 lo MuSC subset through a paracrine signaling loop, leading to impaired proliferation. We uncover that elevated CD47 levels on aged MuSCs result from increased U1 snRNA expression, which disrupts alternative polyadenylation. The deficit in aged MuSC function in regeneration can be overcome either by morpholino-mediated blocking of CD47 alternative polyadenylation or antibody blockade of CD47 signaling, leading to improved regeneration in aged mice, with therapeutic implications. Our findings highlight a previously unrecognized age-dependent alteration in CD47 levels and function in MuSCs, which underlies reduced muscle repair in aging. 

Project description:Fatty acid metabolites generated by the sequential actions of cytochrome P450 enzymes and the soluble epoxide hydrolase (sEH) regulate inflammation. Here we report that the TGF--induced polarization of macrophages to a pro-resolving phenotype requires the activation of Alk5 and Smad2 to increase sEH expression and activity. Macrophages lacking sEH failed to fully repolarize, were less efficient at phagocytosis, and retained a pro-inflammatory gene expression profile. 11,12-Epoxyeicosatrienoic acid (EET) was one of the fatty acid metabolites altered in sEH-/- macrophages and was able to reproduce the effect of sEH deletion on gene expression. Importantly, 11,12-EET also attenuated the expression of Alk5 to inhibit the TGF--induced phosphorylation of Smad2 by eliciting the cytosolic translocation of the E3 ligase Smurf2. These results indicate that the expression of sEH is not only controlled by TGF- but that the activity of the enzyme, which keeps 11,12-EET levels low, actually promotes TGF- signaling by preventing the proteolytic degradation of Alk5. Thus, an autocrine loop between the sEH/11,12-EET and TGF-1 determines macrophage function.

Project description:Abstract: Transcription factors (TFs) play key roles in regulating differentiation and function of stem cells, including muscle satellite cells (MuSCs), a resident stem cell population responsible for postnatal regeneration of the skeletal muscle. Sox11 belongs to the Sry-related HMG-box (SOX) family of TFs that play diverse roles in stem cell behavior and tissue specification. Analysis of single-cell RNA-sequencing (scRNA-seq) datasets identify a specific enrichment of Sox11 mRNA in differentiating but not quiescent MuSCs. Consistent with the scRNA-seq data, Sox11 levels increase during differentiation of murine primary myoblasts in vitro. scRNA-seq data comparing muscle regeneration in young and old mice further demonstrate that Sox11 expression is reduced in aged MuSCs. Age-related decline of Sox11 expression is associated with reduced chromatin contacts within the topologically associated domains. Unexpectedly, Myod1Cre-driven deletion of Sox11 in embryonic myoblasts has no effects on muscle development and growth, resulting in apparently healthy muscles that regenerate normally. Pax7CreER or Rosa26CreER driven (MuSC-specific or global) deletion of Sox11 in adult mice similarly has no effects on MuSC differentiation or muscle regeneration. These results identify Sox11 as a novel myogenic differentiation marker with reduced expression in quiescent and aged MuSCs, but the specific function of Sox11 in myogenesis remain to be elucidated.

Project description:Adult skeletal muscle regeneration is mainly driven by muscle stem cells (MuSCs), which are highly heterogeneous. Although recent studies have started to characterize the heterogeneity of MuSCs, whether a subset of cells with distinct exists within MuSCs remains unanswered. Here, we found that a population of MuSCs, marked by Gli1 expression, is required for muscle regeneration. The Gli1+ MuSC population displayed advantages in proliferation and differentiation both in vitro and in vivo. Depletion of this population led to delayed muscle regeneration, while transplanted Gli1+ MuSCs supported muscle regeneration more effectively than Gli1- MuSCs. Further analysis revealed that even in the uninjured muscle, Gli1+ MuSCs had elevated mTOR signaling activity, increased cell size and mitochondrial numbers compared to Gli1- MuSCs, indicating Gli1+ MuSCs are displaying the features of primed MuSCs. Moreover, Gli1+ MuSCs greatly contributed to the formation of GAlert cells after muscle injury. Collectively, our findings demonstrate that Gli1+ MuSCs represent a distinct MuSC population which is more active in the homeostatic muscle and enters the cell cycle shortly after injury. This cell population functions as the tissue-resident sentinel that rapidly responds to injury and initiates muscle regeneration.