Project description:The storage of lipids as energy in adipose tissue (AT) has been conserved over the course of evolution. However, substantial differences in ATs physiological activities were reported between species. Hence, establishing the mechanisms shaping evolutionarily divergence in ATs transcriptomes could provide a deeper understanding of AT regulation and its roles in obesity-related diseases. While previous studies performed anatomical, physiological and morphological comparisons between ATs across different species, little is currently understood at the molecular phenotypic levels. Here, we characterized transcriptional and lipidomic profiles of available subcutaneous and visceral ATs samples across 15 vertebrate species, spanning more than 300 million years of evolution, including placental mammals, birds and reptiles. We provide detailed descriptions of the datasets produced in this study and report gene expression and lipid profiles across samples. These resources should provide researchers could insights into the molecular and evolutionary mechanisms underlying functional differences between ATs in vertebrate species.

Project description:Detailed genomic contact maps have revealed that chromosomes are composed of developmentally stable topologically associated domains (TADs) and more flexible sub-TADs. These domains reside in active and inactive nuclear compartments, but cause and consequence of compartmentalization are largely unknown. Here, we combined lacO/lacR binding platforms with allele-specific 4C technologies to track their precise position in the three-dimensional genome upon recruitment of NANOG, SUV39H1 or EZH2. We observed locked genomic loci resistant to spatial repositioning and unlocked loci that could be repositioned to different nuclear sub-compartments with distinct chromatin signatures. Focal protein recruitment caused the entire sub- TAD, but not surrounding regions, to engage in new genomic contacts. Compartment switching was uncoupled from gene expression changes and enzymatically modifying histones per se was insufficient for repositioning. Collectively this suggests that transassociated factors determine three-dimensional compartmentalization independent of their cis-effect on local chromatin composition and activity. 4C-seq was performed on a range of viewpoints in 129/Sv;C57BL/6 embryonic stem cells carying a lacO array in chromosome 8 and 11.

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: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.