Project description:Loss of regeneration is a key feature of aging organs, often linked to stem cell exhaustion. Skeletal muscle stem cells (MuSCs) undergo age-related numerical and functional decline, contributing to reduced regenerative potential. Using low-input multi-omics, we systematically profiled the epigenome, transcriptome, and 3D genome of MuSCs from individual mice across 3 age groups (young, old, and geriatric) and both sexes. At baseline, young male MuSCs showed reduced expression of cell cycle-related mRNAs. In aged mice, particularly males, MuSCs exhibited early alterations (emerging during the transition from young to old age), including enhanced proinflammatory signaling, and loss of cell identity. Late alterations (emerging during the transition from old to geriatric age) included heightened inflammation, widespread enhancer activation, and extensive 3D genome rewiring. Proinflammatory pathways were enriched for interferon signaling and correlated with endogenous retroviral expression and NFκB activity. Late-stage epigenome and 3D genome rewiring reflected downstream degenerative changes in muscle organization, response to cytokines, and loss of myogenic identity. Thus, progressive molecular shifts may explain the aggravated proliferative deficit and functional impairment observed in MuSCs during aging.

Project description:Loss of regeneration is a key feature of aging organs, often linked to stem cell exhaustion. Skeletal muscle stem cells (MuSCs) undergo age-related numerical and functional decline, contributing to reduced regenerative potential. Using low-input multi-omics, we systematically profiled the epigenome, transcriptome, and 3D genome of MuSCs from individual mice across 3 age groups (young, old, and geriatric) and both sexes. At baseline, young male MuSCs showed reduced expression of cell cycle-related mRNAs. In aged mice, particularly males, MuSCs exhibited early alterations (emerging during the transition from young to old age), including enhanced proinflammatory signaling, and loss of cell identity. Late alterations (emerging during the transition from old to geriatric age) included heightened inflammation, widespread enhancer activation, and extensive 3D genome rewiring. Proinflammatory pathways were enriched for interferon signaling and correlated with endogenous retroviral expression and NFκB activity. Late-stage epigenome and 3D genome rewiring reflected downstream degenerative changes in muscle organization, response to cytokines, and loss of myogenic identity. Thus, progressive molecular shifts may explain the aggravated proliferative deficit and functional impairment observed in MuSCs during aging.

Project description:Loss of regeneration is a key feature of aging organs, often linked to stem cell exhaustion. Skeletal muscle stem cells (MuSCs) undergo age-related numerical and functional decline, contributing to reduced regenerative potential. Using low-input multi-omics, we systematically profiled the epigenome, transcriptome, and 3D genome of MuSCs from individual mice across 3 age groups (young, old, and geriatric) and both sexes. At baseline, young male MuSCs showed reduced expression of cell cycle-related mRNAs. In aged mice, particularly males, MuSCs exhibited early alterations (emerging during the transition from young to old age), including enhanced proinflammatory signaling, and loss of cell identity. Late alterations (emerging during the transition from old to geriatric age) included heightened inflammation, widespread enhancer activation, and extensive 3D genome rewiring. Proinflammatory pathways were enriched for interferon signaling and correlated with endogenous retroviral expression and NFκB activity. Late-stage epigenome and 3D genome rewiring reflected downstream degenerative changes in muscle organization, response to cytokines, and loss of myogenic identity. Thus, progressive molecular shifts may explain the aggravated proliferative deficit and functional impairment observed in MuSCs during aging.

Project description:Muscle stem cells (MuSCs) are required for muscle regeneration. In resting muscles, MuSCs are kept in quiescence. After injury, MuSCs undergo rapid activation, proliferation and differentiation to repair damaged muscles. Age-associated impairments in stem cell functions correlate with a decline in somatic tissue regeneration capacity during aging. However, the mechanisms underlying the molecular regulation of adult stem cell aging remain elusive. Here, we obtained quisecent MuSCs from young, old, geriatric mice for high resolution mass spectrometry Bruker timsTOF Pro. By comparison of young proteome to old MuSCs proteome or geriatric MuSC proteome, we identified the pathways that are differentially during aging.

Project description:3D genome architecture rewiring is known to influence spatiotemporal expression of lineage-specific genes and cell fate transition during multiple lineage progression and cell differentiation. However, it is yet unknown how nuclear architecture remodels and effects transcription changes during muscle stem cell (SC) development and ageing process. Here, we comprehensively map the 3D chromatin reorganization and integrate genome topology with transcriptional and epigenetic change during muscle SC lineage development and ageing process. Rewiring of compartmentalization is most pronounced when SC become activated, while striking loss in insulation of TAD borders and chromatin looping during early activation process. Meanwhile, super-enhancer containing TAD cluster reorganize in nuclear space and orchestrate stage-specific gene expression. In depth analysis identifies and verifies cis-regulatory elements at Pax7 locus controlling the local chromatin interactions and Pax7 expression. Geriatric cells display a more prominent gain in long-range contacts and loss insulation of TAD borders. Moreover, genome compartmentalization and chromatin loop has already altered for aged SC while geriatric SC display a more prominent loss in strength of TAD borders. Together, our results implicate 3D chromatin extensively reorganizes at multiple architectural levels and underpin the transcriptome remodeling and SC behaviors during SC lineage development and SC aging.

Project description:3D genome architecture rewiring is known to influence spatiotemporal expression of lineage-specific genes and cell fate transition during multiple lineage progression and cell differentiation. However, it is yet unknown how nuclear architecture remodels and effects transcription changes during muscle stem cell (SC) development and ageing process. Here, we comprehensively map the 3D chromatin reorganization and integrate genome topology with transcriptional and epigenetic change during muscle SC lineage development and ageing process. Rewiring of compartmentalization is most pronounced when SC become activated, while striking loss in insulation of TAD borders and chromatin looping during early activation process. Meanwhile, super-enhancer containing TAD cluster reorganize in nuclear space and orchestrate stage-specific gene expression. In depth analysis identifies and verifies cis-regulatory elements at Pax7 locus controlling the local chromatin interactions and Pax7 expression. Geriatric cells display a more prominent gain in long-range contacts and loss insulation of TAD borders. Moreover, genome compartmentalization and chromatin loop has already altered for aged SC while geriatric SC display a more prominent loss in strength of TAD borders. Together, our results implicate 3D chromatin extensively reorganizes at multiple architectural levels and underpin the transcriptome remodeling and SC behaviors during SC lineage development and SC aging.

Project description:3D genome architecture rewiring is known to influence spatiotemporal expression of lineage-specific genes and cell fate transition during multiple lineage progression and cell differentiation. However, it is yet unknown how nuclear architecture remodels and effects transcription changes during muscle stem cell (SC) development and ageing process. Here, we comprehensively map the 3D chromatin reorganization and integrate genome topology with transcriptional and epigenetic change during muscle SC lineage development and ageing process. Rewiring of compartmentalization is most pronounced when SC become activated, while striking loss in insulation of TAD borders and chromatin looping during early activation process. Meanwhile, super-enhancer containing TAD cluster reorganize in nuclear space and orchestrate stage-specific gene expression. In depth analysis identifies and verifies cis-regulatory elements at Pax7 locus controlling the local chromatin interactions and Pax7 expression. Geriatric cells display a more prominent gain in long-range contacts and loss insulation of TAD borders. Moreover, genome compartmentalization and chromatin loop has already altered for aged SC while geriatric SC display a more prominent loss in strength of TAD borders. Together, our results implicate 3D chromatin extensively reorganizes at multiple architectural levels and underpin the transcriptome remodeling and SC behaviors during SC lineage development and SC aging.

Project description:3D genome architecture rewiring is known to influence spatiotemporal expression of lineage-specific genes and cell fate transition during multiple lineage progression and cell differentiation. However, it is yet unknown how nuclear architecture remodels and effects transcription changes during muscle stem cell (SC) development and ageing process. Here, we comprehensively map the 3D chromatin reorganization and integrate genome topology with transcriptional and epigenetic change during muscle SC lineage development and ageing process. Rewiring of compartmentalization is most pronounced when SC become activated, while striking loss in insulation of TAD borders and chromatin looping during early activation process. Meanwhile, super-enhancer containing TAD cluster reorganize in nuclear space and orchestrate stage-specific gene expression. In depth analysis identifies and verifies cis-regulatory elements at Pax7 locus controlling the local chromatin interactions and Pax7 expression. Geriatric cells display a more prominent gain in long-range contacts and loss insulation of TAD borders. Moreover, genome compartmentalization and chromatin loop has already altered for aged SC while geriatric SC display a more prominent loss in strength of TAD borders. Together, our results implicate 3D chromatin extensively reorganizes at multiple architectural levels and underpin the transcriptome remodeling and SC behaviors during SC lineage development and SC aging.

Project description:3D genome architecture rewiring is known to influence spatiotemporal expression of lineage-specific genes and cell fate transition during multiple lineage progression and cell differentiation. However, it is yet unknown how nuclear architecture remodels and effects transcription changes during muscle stem cell (SC) development and ageing process. Here, we comprehensively map the 3D chromatin reorganization and integrate genome topology with transcriptional and epigenetic change during muscle SC lineage development and ageing process. Rewiring of compartmentalization is most pronounced when SC become activated, while striking loss in insulation of TAD borders and chromatin looping during early activation process. Meanwhile, super-enhancer containing TAD cluster reorganize in nuclear space and orchestrate stage-specific gene expression. In depth analysis identifies and verifies cis-regulatory elements at Pax7 locus controlling the local chromatin interactions and Pax7 expression. Geriatric cells display a more prominent gain in long-range contacts and loss insulation of TAD borders. Moreover, genome compartmentalization and chromatin loop has already altered for aged SC while geriatric SC display a more prominent loss in strength of TAD borders. Together, our results implicate 3D chromatin extensively reorganizes at multiple architectural levels and underpin the transcriptome remodeling and SC behaviors during SC lineage development and SC aging.

Project description:3D genome architecture rewiring is known to influence spatiotemporal expression of lineage-specific genes and cell fate transition during multiple lineage progression and cell differentiation. However, it is yet unknown how nuclear architecture remodels and effects transcription changes during muscle stem cell (SC) development and ageing process. Here, we comprehensively map the 3D chromatin reorganization and integrate genome topology with transcriptional and epigenetic change during muscle SC lineage development and ageing process. Rewiring of compartmentalization is most pronounced when SC become activated, while striking loss in insulation of TAD borders and chromatin looping during early activation process. Meanwhile, super-enhancer containing TAD cluster reorganize in nuclear space and orchestrate stage-specific gene expression. In depth analysis identifies and verifies cis-regulatory elements at Pax7 locus controlling the local chromatin interactions and Pax7 expression. Geriatric cells display a more prominent gain in long-range contacts and loss insulation of TAD borders. Moreover, genome compartmentalization and chromatin loop has already altered for aged SC while geriatric SC display a more prominent loss in strength of TAD borders. Together, our results implicate 3D chromatin extensively reorganizes at multiple architectural levels and underpin the transcriptome remodeling and SC behaviors during SC lineage development and SC aging.