Project description:Chromatin compartments reorganize dramatically during cell cycle transitions, shifting from a compartmentalized interphase to a condensed mitotic configuration in which large-scale compartment signals are attenuated. While histone modifications are linked to compartment identity, their contribution to compartment organization remains unclear. Using meiotic (mouse spermatogenesis) and mitotic (mouse neuronal progenitor cell, mNPC) models, we mapped histone landscapes alongside compartment dynamics. We found that histone H4 lysine 16 acetylation (H4K16ac) strongly tracked compartment reorganization, remaining enriched in A compartments during compartmentalization but redistributing upon chromatin compaction. In spermatogenesis, H4K16ac loss on the X chromosome coincided with condensation and H3K9me3 spreading. Machine learning highlighted H4K16ac as a stronger predictor of compartment transitions than H3K27ac. Acute degradation of MOF, the principal H4K16ac acetyltransferase, disrupted both the spatial distribution and global abundance of H4K16ac and progressively impaired compartmentalization in mNPCs. These results position H4K16ac as a histone modification selectively coupled to chromatin compartment transitions.

Project description:Chromatin compartments reorganize dramatically during cell cycle transitions, shifting from a compartmentalized interphase to a condensed mitotic configuration in which large-scale compartment signals are attenuated. While histone modifications are linked to compartment identity, their contribution to compartment organization remains unclear. Using meiotic (mouse spermatogenesis) and mitotic (mouse neuronal progenitor cell, mNPC) models, we mapped histone landscapes alongside compartment dynamics. We found that histone H4 lysine 16 acetylation (H4K16ac) strongly tracked compartment reorganization, remaining enriched in A compartments during compartmentalization but redistributing upon chromatin compaction. In spermatogenesis, H4K16ac loss on the X chromosome coincided with condensation and H3K9me3 spreading. Machine learning highlighted H4K16ac as a stronger predictor of compartment transitions than H3K27ac. Acute degradation of MOF, the principal H4K16ac acetyltransferase, disrupted both the spatial distribution and global abundance of H4K16ac and progressively impaired compartmentalization in mNPCs. These results position H4K16ac as a histone modification selectively coupled to chromatin compartment transitions.

Project description:Chromatin compartments reorganize dramatically during cell cycle transitions, shifting from a compartmentalized interphase to a condensed mitotic configuration in which large-scale compartment signals are attenuated. While histone modifications are linked to compartment identity, their contribution to compartment organization remains unclear. Using meiotic (mouse spermatogenesis) and mitotic (mouse neuronal progenitor cell, mNPC) models, we mapped histone landscapes alongside compartment dynamics. We found that histone H4 lysine 16 acetylation (H4K16ac) strongly tracked compartment reorganization, remaining enriched in A compartments during compartmentalization but redistributing upon chromatin compaction. In spermatogenesis, H4K16ac loss on the X chromosome coincided with condensation and H3K9me3 spreading. Machine learning highlighted H4K16ac as a stronger predictor of compartment transitions than H3K27ac. Acute degradation of MOF, the principal H4K16ac acetyltransferase, disrupted both the spatial distribution and global abundance of H4K16ac and progressively impaired compartmentalization in mNPCs. These results position H4K16ac as a histone modification selectively coupled to chromatin compartment transitions.

Project description:Chromatin compartments reorganize dramatically during cell cycle transitions, shifting from a compartmentalized interphase organization to a condensed mitotic configuration in which large-scale compartment signals are attenuated. While histone modifications are linked to compartment identity, their causal contribution to compartment organization remained unclear. Using meiotic (mouse spermatogenesis) and mitotic (mouse neuronal progenitor cells, mNPCs) models, we mapped histone landscapes alongside compartment dynamics. We found that histone H4 lysine 16 acetylation (H4K16ac) strongly tracked compartment reorganization, remaining enriched in A compartments during compartmentalization but redistributing upon chromatin compaction. In spermatogenesis, H4K16ac loss on the X chromosome coincided with condensation and H3K9me3 spreading. Machine learning highlighted H4K16ac as a stronger predictor of compartment transitions than H3K27ac. To probe causality, we acutely degraded MOF, the principal H4K16ac acetyltransferase, which disrupted both the spatial distribution and global abundance of H4K16ac and progressively impaired compartmentalization in mNPCs. Together, these results position H4K16ac as a selectively coupled and influential histone modification of chromatin compartment transitions.

Project description:Genetic variation leads to phenotypic variability in pluripotent stem cells that presents challenges for regenerative medicine. Although recent studies have investigated the impact of genetic variation on pluripotency maintenance and differentiation capacity, less is known about how genetic variants affecting the pluripotent state influence gene regulation later in development. Here, we characterized expression of 12,000 genes in a large panel of donor-matched Diversity Outbred (DO) mouse embryonic stem cell (mESC) and neural progenitor cell (mNPC) lines. Quantitative trait locus (QTL) mapping identified 4,060 expression QTL (eQTL) in mNPCs, including 2,998 local and 1,062 distant eQTL. In a comparison of mNPC and mESC eQTLs, we found that local eQTLs were more likely than distant eQTL to be detected in both cell types. Distant eQTL were largely unique to one cell type, and we mapped three mNPC-specific eQTL hotspots on Chromosomes (Chrs) 1, 10, and 11. Mediation analysis of the Chr 1 hotspot identified Rnf152 as the best candidate mediator expressed in mNPCs, while cross-cell type mediation using mESC gene expression along with partial correlation analysis strongly implicated genetic variant(s) affecting Pign expression in the mESC state as regulating the mNPC Chr 1 hotspot. These findings highlight that local mNPC eQTL are more likely than distant eQTL to be shared with mESCs; distant mNPC eQTL are numerous but largely unique to that cell type, with many co-localizing to mNPC-specific hotspots; and mediation analysis across cell types suggests that expression of Pign in mESCs shapes the transcriptome of the more specialized mNPC state.

Project description:During mitosis, condensin activity is thought to disrupt interphase chromatin structures. Here, we utilize condensin-deficient mitotic chromosomes as a unique architectural platform to further investigate genome folding principles. Upon condensin loss, compartments progressively emerge in mitotic chromosomes. Euchromatin diverges into two different compartments A1 and A2, the former of which shows strong homotypic interactions while the latter exhibit reduced self-aggregation. Constitutive heterochromatin (B1) displays reduced level of compartmentalization and the normally inert facultative heterochromatin (B2) participates to compartmentalize the genome. Dynamically, A1 compartment is established remarkably fast with similarly efficient separation from B1 while reformation of B1 is delayed, implying that A1 self-attraction is the engine to compartmentalizalize the condensin-depleted mitotic chromosomes. Notified by the mitotic compartmentalization of B1 which lacks HP1 binding, we sought to explore the role of HP1 proteins in genome folding and demonstrat that HP1& are dispensible for chromatin structural restoration during cell divison. Our observations unveil delicate patterns and novel principles of genome compartmentalization that are otherwise hidden in interphase cells.

Project description:During mitosis, condensin activity is thought to disrupt interphase chromatin structures. Here, we utilize condensin-deficient mitotic chromosomes as a unique architectural platform to further investigate genome folding principles. Upon condensin loss, compartments progressively emerge in mitotic chromosomes. Euchromatin diverges into two different compartments A1 and A2, the former of which shows strong homotypic interactions while the latter exhibit reduced self-aggregation. Constitutive heterochromatin (B1) displays reduced level of compartmentalization and the normally inert facultative heterochromatin (B2) participates to compartmentalize the genome. Dynamically, A1 compartment is established remarkably fast with similarly efficient separation from B1 while reformation of B1 is delayed, implying that A1 self-attraction is the engine to compartmentalizalize the condensin-depleted mitotic chromosomes. Notified by the mitotic compartmentalization of B1 which lacks HP1 binding, we sought to explore the role of HP1 proteins in genome folding and demonstrat that HP1& are dispensible for chromatin structural restoration during cell divison. Our observations unveil delicate patterns and novel principles of genome compartmentalization that are otherwise hidden in interphase cells.

Project description:During mitosis, condensin activity is thought to disrupt interphase chromatin structures. Here, we utilize condensin-deficient mitotic chromosomes as a unique architectural platform to further investigate genome folding principles. Upon condensin loss, compartments progressively emerge in mitotic chromosomes. Euchromatin diverges into two different compartments A1 and A2, the former of which shows strong homotypic interactions while the latter exhibit reduced self-aggregation. Constitutive heterochromatin (B1) displays reduced level of compartmentalization and the normally inert facultative heterochromatin (B2) participates to compartmentalize the genome. Dynamically, A1 compartment is established remarkably fast with similarly efficient separation from B1 while reformation of B1 is delayed, implying that A1 self-attraction is the engine to compartmentalizalize the condensin-depleted mitotic chromosomes. Notified by the mitotic compartmentalization of B1 which lacks HP1 binding, we sought to explore the role of HP1 proteins in genome folding and demonstrat that HP1& are dispensible for chromatin structural restoration during cell divison. Our observations unveil delicate patterns and novel principles of genome compartmentalization that are otherwise hidden in interphase cells.

Project description:During mitosis, condensin activity is thought to disrupt interphase chromatin structures. Here, we utilize condensin-deficient mitotic chromosomes as a unique architectural platform to further investigate genome folding principles. Upon condensin loss, compartments progressively emerge in mitotic chromosomes. Euchromatin diverges into two different compartments A1 and A2, the former of which shows strong homotypic interactions while the latter exhibit reduced self-aggregation. Constitutive heterochromatin (B1) displays reduced level of compartmentalization and the normally inert facultative heterochromatin (B2) participates to compartmentalize the genome. Dynamically, A1 compartment is established remarkably fast with similarly efficient separation from B1 while reformation of B1 is delayed, implying that A1 self-attraction is the engine to compartmentalizalize the condensin-depleted mitotic chromosomes. Notified by the mitotic compartmentalization of B1 which lacks HP1 binding, we sought to explore the role of HP1 proteins in genome folding and demonstrat that HP1& are dispensible for chromatin structural restoration during cell divison. Our observations unveil delicate patterns and novel principles of genome compartmentalization that are otherwise hidden in interphase cells.

Project description:During mitosis, condensin activity is thought to disrupt interphase chromatin structures. Here, we utilize condensin-deficient mitotic chromosomes as a unique architectural platform to further investigate genome folding principles. Upon condensin loss, compartments progressively emerge in mitotic chromosomes. Euchromatin diverges into two different compartments A1 and A2, the former of which shows strong homotypic interactions while the latter exhibit reduced self-aggregation. Constitutive heterochromatin (B1) displays reduced level of compartmentalization and the normally inert facultative heterochromatin (B2) participates to compartmentalize the genome. Dynamically, A1 compartment is established remarkably fast with similarly efficient separation from B1 while reformation of B1 is delayed, implying that A1 self-attraction is the engine to compartmentalizalize the condensin-depleted mitotic chromosomes. Notified by the mitotic compartmentalization of B1 which lacks HP1 binding, we sought to explore the role of HP1 proteins in genome folding and demonstrat that HP1& are dispensible for chromatin structural restoration during cell divison. Our observations unveil delicate patterns and novel principles of genome compartmentalization that are otherwise hidden in interphase cells.