Subsets of mammalian adult stem cells reside in the quiescent state for prolonged periods of time. This state, which is reversible, has long been viewed as dormant and with minimal basal activity. Recent advances in adult stem cell isolation have provided insights into the epigenetic, transcriptional and post-transcriptional control of quiescence and suggest that quiescence is an actively maintained state in which signalling pathways are involved in maintaining a poised state that allows rapid activation. Deciphering the molecular mechanisms regulating adult stem cell quiescence will increase our understanding of tissue regeneration mechanisms and how they are dysregulated in pathological conditions and in ageing.
Summary The ability to maintain quiescence is critical for the long-term maintenance of a functional stem cell pool. To date, the epigenetic and transcriptional characteristics of quiescent stem cells and how they change with age remain largely unknown. In this study, we explore the chromatin features of adult skeletal muscle stem cells, or satellite cells (SCs), which reside predominantly in a quiescent state in fully developed limb muscles of both young and aged mice. Using a ChIP-seq approach to obtain global epigenetic profiles of quiescent SCs (QSCs), we show that QSCs possess a permissive chromatin state in which few genes are epigenetically repressed by Polycomb group (PcG)-mediated histone 3 lysine 27 trimethylation (H3K27me3), and a large number of genes encoding regulators that specify nonmyogenic lineages are demarcated by bivalent domains at their transcription start sites (TSSs). By comparing epigenetic profiles of QSCs from young and old mice, we also provide direct evidence that, with age, epigenetic changes accumulate and may lead to a functional decline in quiescent stem cells. These findings highlight the importance of chromatin mapping in understanding unique features of stem cell identity and stem cell aging.
Satellite cells (SCs) are myogenic stem cells found in skeletal muscle that function to repair tissue damaged by injury or disease. SCs are quiescent at rest, although the signaling pathways required to maintain quiescence are unknown. Using a transgenic Notch reporter mouse and quantitative reverse-transcription polymerase chain reaction analysis of Notch target genes, we determined that Notch signaling is active in quiescent SCs. SC-specific deletion of recombining binding protein-Jκ (RBP-Jκ), a nuclear factor required for Notch signaling, resulted in the depletion of the SC pool and muscles that lacked any ability to regenerate in response to injury. SC depletion was not due to apoptosis. Rather, RBP-Jκ-deficient SCs spontaneously activate, fail to self-renew, and undergo terminal differentiation. Intriguingly, most of the cells differentiate without first dividing. They then fuse with adjacent myofibers, leading to the gradual disappearance of SCs from the muscle. These results demonstrate the requirement of Notch signaling for the maintenance of the quiescent state and for muscle stem cell homeostasis by the regulation of self-renewal and differentiation, processes that are all critical for normal postnatal myogenesis.
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