Project description:Regulation of chromatin accessibility is critical for cell fate decisions. Chromatin architecture responds to extrinsic environments rapidly. The traditional adult stem cell isolation approach requires tissue dissociation, and adult stem cells respond to the stimulation and adapt a different chromatin conformation. Here, we characterized the DNA regulatory landscape and transcriptomic profile of muscle stem cell quiescence exit and self-renewal by time-course profiling of the in situ fixed SCs upon injury-induced activation and during aging. Detailed analysis of the chromatin accessibility profiles leads to the identification of enhancer elements for SC quiescence. Constant activation of the enhancer elements promotes stemness and prevents SCs from differentiation, whereas loss of them causes cell-cycle arrest and essentially leads to defects in SC activation. Interestingly, we also showed that aged SCs display a more open chromatin environment than young SCs. Our compre hensive characterization of the chromatin accessibility and transcriptomic landscapes during SC quiescence exit and self-renewal broadens our understanding of this process and identifies functional distal regulatory elements for SC function.

Project description:Regulation of chromatin accessibility is critical for cell fate decisions. Chromatin architecture responds to extrinsic environments rapidly. The traditional adult stem cell isolation approach requires tissue dissociation, and adult stem cells respond to the stimulation and adapt a different chromatin conformation. Here, we characterized the DNA regulatory landscape and transcriptomic profile of muscle stem cell quiescence exit and self-renewal by time-course profiling of the in situ fixed SCs upon injury-induced activation and during aging. Detailed analysis of the chromatin accessibility profiles leads to the identification of enhancer elements for SC quiescence. Constant activation of the enhancer elements promotes stemness and prevents SCs from differentiation, whereas loss of them causes cell-cycle arrest and essentially leads to defects in SC activation. Interestingly, we also showed that aged SCs display a more open chromatin environment than young SCs. Our compre hensive characterization of the chromatin accessibility and transcriptomic landscapes during SC quiescence exit and self-renewal broadens our understanding of this process and identifies functional distal regulatory elements for SC function.

Project description:Tissue homeostasis and regeneration require activation and subsequent lineage commitment of tissue-resident stem cells (SCs). These state changes are controlled by epigenetic barriers. Using hair follicle stem cells (HFSCs) as paradigm, we studied how aging impacts the chromatin landscape and function of mammalian SCs. Analyses of genome-wide chromatin accessibility revealed that aged HFSCs displayed widespread reduction of chromatin accessibility specifically at key SC self-renewal and differentiation genes that were characterized by bivalent promoters carrying both activating and repressive chromatin marks. Consistently, aged HFSCs showed reduced self-renewing capacity and attenuated ability to activate expression of these bivalent genes upon regeneration. These functional defects were niche-dependent as transplantation of aged HFSCs into young recipients or into ex vivo niches restored SC functions and transcription of poised genes. Mechanistically, aged HFSC niche displayed wide-spread alterations in extracellular matrix composition and mechanics, resulting in compressive forces on SCs and subsequent transcriptional repression, leading to loss of bivalent promoters. Tuning tissue mechanics both in vivo and in vitro recapitulated age-related SC changes, implicating niche mechanics as a central regulator of genome organization and function leading to age-dependent SC exhaustion.

Project description:Muscle Stem Cells or satellite cells (SCs) are required for muscle regeneration. In resting muscles, SCs are kept in quiescence. After injury, SCs undergo rapid activation, proliferation and differentiation to repair damaged muscles. The transcriptome alteration during SC activation is well characterized. While transcriptome is not exactly represent proteome because of post-transcriptional regulations such as miRNA induced gene silencing. However, little is known about SC proteome. We obtained quisecent SCs (QSCs) and freshly isolated SCs (fiSCs, early activated SCs) and activated SCs (ASCs) for high resolution mass spectrometry Bruker timsTOF Pro. Thus, we uncovered the QSC proteome. By comparison of QSC proteome to fiuSCs proteome or ASCs proteome, we identified the pathways that are differentially expressed between them. Forthermore, we characterized a translational regulator CPEB1 reprogrammed translation landscape for SC activation.

Project description:Muscle Stem Cells or satellite cells (SCs) are required for muscle regeneration. In resting muscles, SCs are kept in quiescence. After injury, SCs undergo rapid activation, proliferation and differentiation to repair damaged muscles. The transcriptome alteration during SC activation is well characterized. While transcriptome is not exactly represent proteome because of post-transcriptional regulations such as miRNA induced gene silencing. However, little is known about SC proteome. We obtained in vivo activated SCs (ASCs) from 3 days post injured muscles for high resolution mass spectrometry Bruker timsTOF Pro. Compared with QSC proteome,, we identified the pathways that are differentially expressed between them.

Project description:Sustainable muscle regeneration necessitates proper maintenance of the quiescence-reversible SCs pool. Activation of p16Ink4a-associated senescence pathway during aging breaks muscle homeostasis and causes degenerative muscle disease by irreversibly dampening satellite cell (SC) self-renewal capacity. We performed microarrays analysis to compare the genome-wide gene expression profiles of wild-type and Slug-deficient SCs and identified distinct classes of up-regulated genes upon deletion of Slug gene.

Project description:Skeletal muscle stem cells, or satellite cells (SCs), are essential to regenerate and maintain muscle. Quiescent SCs reside in an asymmetric niche between the basal lamina and myofiber membrane. To repair muscle, SCs activate, proliferate, and differentiate, fusing to repair myofibers or reacquiring quiescence to replenish the SC niche. Little is known about when SCs reacquire quiescence during regeneration or the cellular processes that direct SC fate decisions and progression through myogenesis. Single cell sequencing of myogenic cells in regenerating muscle identifies SCs reacquiring quiescence and reveals that non-cell autonomous signaling networks influence SC fate decisions during regeneration. Single cell RNA-sequencing of regenerating skeletal muscle reveals that RBP expression, including numerous neuromuscular disease-associated RBPs, is temporally regulated in skeletal muscle stem cells and correlates to stages of myogenic differentiation. By combining machine learning with RBP engagement scoring, we discover that the neuromuscular disease associated RBP Hnrnpa2b1 is a differentiation-specifying regulator of myogenesis controlling myogenic cell fate transitions during terminal differentiation.

Project description:Satellite cells (SCs) are adult muscle stem cells residing in a specialised niche that regulates SC homeostasis. How niche-generated signals integrate to regulate gene expression in SC-derived myoblasts, is poorly understood. We undertook an unbiased approach to study the effect of the SC niche on SC-derived myoblast transcriptional regulation and identified the tumour suppressor p53 as a key player in the regulation of myoblast quiescence. After activation and proliferation, a subpopulation of myoblasts cultured in the presence of the niche upregulates p53 and fails to differentiate. When SC self-renewal is modelled ex vivo in a reserve cell assay, myoblasts treated with Nutlin-3, which increases p53 levels in the cell, fail to differentiate and instead become quiescent. Since both these effects of Nutlin-3 are rescued by siRNA-mediated p53 knockdown we conclude that a tight control of p53 levels in myoblasts regulate the balance between differentiation and return to quiescence.

Project description:Although ectopic overexpression of miRNAs can influence mammary normal and cancer stem cells (SCs/CSCs), their physiological relevance remains uncertain. Here, we found that the miR-146 family is linked to SC identity, since: i) their expression is very high in SCs/CSCs from human/mouse primary mammary tissues; correlates with the basal-like breast cancer subtype, which typically has a high CSC content; and specifically distinguishes cells with SC/CSC identity; ii) miR-146 depletion reduces SC/CSC self-renewal in vitro and the number of tumor-initiating cells in vivo. Analysis of the transcriptional effects of miR-146 in breast SC-like cells revealed a complex network of highly connected miR-146 targets related to quiescence, transcription and metabolic pathways (one-carbon pool, purine synthesis and folate metabolism). As predicted by our analysis, SCs/CSCs display innate resistance to anti-folate therapy that can be reversed by miR-146 depletion, unmasking a “hidden vulnerability” that could be exploited for the development of anti-CSC therapies.

Project description:Mouse hair follicles undergo synchronized cycles. Cyclical regeneration and hair growth is fueled by stem cells (SCs). Following hair regeneration, SCs within the bulge and its vicinity (upper ORS which becomes the bulge for the next cycle) briefly self-renew to replenish expended SCs and ensure long-term tissue regeneration. We used microarrays to detect the relative levels of global gene expression influenced by transcription factor Tbx1 in order to gain insight into how Tbx1 is invovled in regulating hair follicle SC self-renewal and long-term regeneration. Fourty eight hours after deplicaiton induced hair regeneration, hair follicle SCs were FACS-purified for RNA extraction and hybridization on Affymetrix microarrays. To obtain homogeneous populations of expression profiles, we applied FASC technique to purify SC according to their cell surface markers.