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.

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:Genome organization is driven by forces affecting transcriptional state, but the relationship between transcription and genome architecture remains unclear. Here, we identified the Drosophila transcription factor Motif 1 Binding Protein (M1BP) in physical association with the gypsy chromatin insulator core complex, including the universal insulator protein CP190. M1BP is required for enhancer-blocking and barrier activities of the gypsy insulator as well as its proper nuclear localization. Genome-wide, M1BP specifically colocalizes with CP190 at Motif 1-containing promoters, which are enriched at topologically associating domain (TAD) borders. M1BP facilitates CP190 chromatin binding at many shared sites and vice versa. Both factors promote Motif 1-dependent gene expression and transcription near TAD borders genome-wide. Finally, loss of M1BP reduces chromatin accessibility and increases both inter- and intra-TAD local genome compaction. Our results reveal physical and functional interaction between CP190 and M1BP to activate transcription at TAD borders and mediate chromatin insulator-dependent genome organization.

Project description:Chromosomes of metazoan organisms are partitioned in the interphase nucleus into discrete topologically associating domains (TADs). Borders between TADs are preferentially formed in regions containing high density of active genes and clusters of architectural protein binding sites. Transcription of most genes is turned off during the heat shock response in Drosophila. Here we show that temperature stress induces relocalization of architectural proteins from TAD borders to inside TADs, and this is accompanied by a dramatic rearrangement in the 3D organization of the nucleus. TAD border strength declines, allowing for an increase in long-distance inter-TAD interactions. Similar but quantitatively weaker effects are observed upon inhibition of transcription or depletion of individual architectural proteins. New heat shock-induced inter-TAD interactions result in increased contacts among enhancers and promoters of silenced genes, which recruit Pc and form Pc bodies at the nucleolus. These results suggest that the TAD organization of metazoan genomes is plastic and can be quickly reconfigured to allow new interactions between distant sequences. Analysis of 3D chromatin organization using Hi-C in Drosophila Kc167 cells. Cells were grown at 25 C and heat shocked for 20 min at 36.5 C. Cells were also treated with flavopiridol or triptolide to inhibit transcription elongation or initiation, respectively. Cells were depeleted of Cap-H2 or Rad21 using RNAi. Finally, cells depleted of RAd21 were subjected to heat shock at 36.5 C for 20 min.

Project description:Chromosomes of metazoan organisms are partitioned in the interphase nucleus into discrete topologically associating domains (TADs). Borders between TADs are preferentially formed in regions containing high density of active genes and clusters of architectural protein binding sites. Transcription of most genes is turned off during the heat shock response in Drosophila. Here we show that temperature stress induces relocalization of architectural proteins from TAD borders to inside TADs, and this is accompanied by a dramatic rearrangement in the 3D organization of the nucleus. TAD border strength declines, allowing for an increase in long-distance inter-TAD interactions. Similar but quantitatively weaker effects are observed upon inhibition of transcription or depletion of individual architectural proteins. New heat shock-induced inter-TAD interactions result in increased contacts among enhancers and promoters of silenced genes, which recruit Pc and form Pc bodies at the nucleolus. These results suggest that the TAD organization of metazoan genomes is plastic and can be quickly reconfigured to allow new interactions between distant sequences. Analysis of the distribution of architectural proteins, chromatin proteins and histone modifications in Drosophila Kc167 cells. Cells were grown at 25 C (NT) or heat shocked for 20 min at 36.5 C (HS). Both control and reference samples are included. For some of the samples, replicates are also included.