Project description:The genome of the fertilized egg becomes structurally and functionally reorganized during early embryogenesis. This includes the segregation of active and inactive chromosome regions into A and B compartments, which are a fundamental feature of genome organization in both vertebrates and invertebrates. Mutually exclusive and attractive interactions within each compartment are thought to contribute to compartment formation1,2. However, the molecular nature of compartmental forces, and thus how compartments form, remain unknown. Here we show that HP1a is a major driver of compartmental segregation in Drosophila early development. Depletion of HP1a leads to an overall decrease of compartmentalization and increased intra-chromosomal interactions. Polymer modeling analysis of Hi-C data and ChIP-seq suggest that establishment of the B compartment is driven by HP1a-mediated attractive interactions. Thus, HP1 controls the establishment of higher order 3D structure during early embryogenesis.

Project description:The genome of the fertilized egg becomes structurally and functionally reorganized during early embryogenesis. This includes the segregation of active and inactive chromosome regions into A and B compartments, which are a fundamental feature of genome organization in both vertebrates and invertebrates. Mutually exclusive and attractive interactions within each compartment are thought to contribute to compartment formation1,2. However, the molecular nature of compartmental forces, and thus how compartments form, remain unknown. Here we show that HP1a is a major driver of compartmental segregation in Drosophila early development. Depletion of HP1a leads to an overall decrease of compartmentalization and increased intra-chromosomal interactions. Polymer modeling analysis of Hi-C data and ChIP-seq suggest that establishment of the B compartment is driven by HP1a-mediated attractive interactions. Thus, HP1 controls the establishment of higher order 3D structure during early embryogenesis.

Project description:CTCF is present at the anchors of thousands of loops likely formed via cohesin-mediated loop extrusion in mammalian cells. Interaction domains present in D. melanogaster chromosomes form via the segregation of active and inactive chromatin in the absence of CTCF looping, but the role of transcription versus other architectural proteins in chromatin organization is unclear. Here we find that positioning of RNAPII via transcription elongation is essential in the formation of gene loops, which in turn interact to form compartmental domains. Inhibition of transcription elongation or depletion of cohesin decreases gene looping and formation of active compartmental domains. In contrast, depletion of condensin II, which also localizes to active chromatin, results in increased gene looping, formation of compartmental domains, and stronger intra-chromosomal compartmental interactions. Condensin II has a similar role in maintaining inter-chromosomal interactions responsible for pairing between homologous chromosomes, whereas inhibition of transcription elongation or cohesin depletion has little effect on homolog pairing. The results suggest distinct roles for cohesin and condensin II in the establishment of 3D nuclear organization in Drosophila.

Project description:Histone post-translational modifications and the proteins that bind them are proposed to be drivers of 3D genome organization, but whether and how they do so remain unanswered. Here, we evaluate the contribution of H3K9-methylated constitutive heterochromatin to 3D genome organization in Drosophila tissues. We find that the predominant organizational feature of wildtype tissues is segregation of euchromatic chromosome arms from heterochromatic pericentromeres. Reciprocal perturbation of HP1a•H3K9 binding, using a point mutation in the HP1a chromodomain or replacement of the replication-dependent H3 with H3K9R mutant histones, revealed that HP1a binding to methylated H3K9 in constitutive heterochromatin is required to restrict long-range interactions between pericentromeres and chromosome arms. Surprisingly, self-association of pericentromeric heterochromatin is largely preserved upon disruption of HP1a•H3K9 binding despite loss of pericentromeric H3K9 methylation and HP1a occupancy. Thus, the HP1a•H3K9 interaction contributes to, but does not solely drive, segregation of euchromatin and heterochromatin inside the nucleus.

Project description:Histone post-translational modifications and the proteins that bind them are proposed to be drivers of 3D genome organization, but whether and how they do so remain unanswered. Here, we evaluate the contribution of H3K9-methylated constitutive heterochromatin to 3D genome organization in Drosophila tissues. We find that the predominant organizational feature of wildtype tissues is segregation of euchromatic chromosome arms from heterochromatic pericentromeres. Reciprocal perturbation of HP1a•H3K9 binding, using a point mutation in the HP1a chromodomain or replacement of the replication-dependent H3 with H3K9R mutant histones, revealed that HP1a binding to methylated H3K9 in constitutive heterochromatin is required to restrict long-range interactions between pericentromeres and chromosome arms. Surprisingly, self-association of pericentromeric heterochromatin is largely preserved upon disruption of HP1a•H3K9 binding despite loss of pericentromeric H3K9 methylation and HP1a occupancy. Thus, the HP1a•H3K9 interaction contributes to, but does not solely drive, segregation of euchromatin and heterochromatin inside the nucleus.

Project description:Histone post-translational modifications and the proteins that bind them are proposed to be drivers of 3D genome organization, but whether and how they do so remain unanswered. Here, we evaluate the contribution of H3K9-methylated constitutive heterochromatin to 3D genome organization in Drosophila tissues. We find that the predominant organizational feature of wildtype tissues is segregation of euchromatic chromosome arms from heterochromatic pericentromeres. Reciprocal perturbation of HP1a•H3K9 binding, using a point mutation in the HP1a chromodomain or replacement of the replication-dependent H3 with H3K9R mutant histones, revealed that HP1a binding to methylated H3K9 in constitutive heterochromatin is required to restrict long-range interactions between pericentromeres and chromosome arms. Surprisingly, self-association of pericentromeric heterochromatin is largely preserved upon disruption of HP1a•H3K9 binding despite loss of pericentromeric H3K9 methylation and HP1a occupancy. Thus, the HP1a•H3K9 interaction contributes to, but does not solely drive, segregation of euchromatin and heterochromatin inside the nucleus.

Project description:Enhancers harbor instructions encoded for the interactions between cis-elements and transcription factors to orchestrate lineage specific gene programs. Here we developed a modified method for chromosome conformation capture (3C), named MID Hi-C, to reveal how in mouse embryonic stem cells differential cooperation of enhancers and the chromatin remodeler BAF, as instructed by the underlying transcription factor motifs, modulate enhancer-promoter communication. We show that BAF-dependent enhancers permit genomic interactions beyond enhancer boundaries. BAF-dependent enhancers do not dictate genomic interactions within enhancer-promoter loop domains but rather act to instruct remote enhancer-promoter communication. In contrast, BAF-independent enhancers interact with promoter regions within tightly insulated enhancer-promoter loop domains that are marked by promoter and enhancer boundary elements. In addition, enhancer activeness modulated by BAF enforces compartment segregation. Based on these observations, we propose that enhancer cis elements instruct with great precision BAF-induced enhancer-promoter communication and compartmental segregation.

Project description:Whether and how histone post-translational modifications and the proteins that bind them drive 3D genome organization remains unanswered. Here, we evaluate the contribution of H3K9-methylated constitutive heterochromatin to 3D genome organization in Drosophila tissues. We find that the predominant organizational feature of wildtype tissues is segregation of euchromatic chromosome arms from heterochromatic pericentromeres. Reciprocal perturbation of HP1a•H3K9me binding, using a point mutation in the HP1a chromodomain or replacement of the replication-dependent histone H3 with H3K9R mutant histones, revealed that HP1a binding to methylated H3K9 in constitutive heterochromatin is required to limit contact frequency between pericentromeres and chromosome arms and regulate the distance between arm and pericentromeric regions. Surprisingly, self-association of pericentromeric regions is largely preserved despite loss of H3K9 methylation and HP1a occupancy. Thus, the HP1a•H3K9 interaction contributes to, but does not solely drive, segregation of euchromatin and heterochromatin inside the nucleus.

Project description:We microdissected each compartment from 8-micron paraffin sections using the Leica LMD6000 system to identify all genes active in different compartments of a soybean seed containing a early maturation-stage embryo. Experiment Overall Design: early maturation-stage seed compartments were isolated using the Leica LMD6000 system. Total RNA was amplified and hybridized with Affymetrix Soybean Genome Arrays.

Project description:This is the Dynamical model of nuclear division cycles during early embryogenesis of Drosophila, without StringT regulation. so ksstg=kdstg=0. Figure1B has been simulated by MathSBML. Curator changed model from only one compartment into two compartments according to the paper. Detail explaination of the models are in the supplement information of the paper.The author didn't specify which compartment Xm, Stgm, Xp are located, we assume that they locate in cytoplasm. Some of the parameter values for the equations are dimensionless parameters. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information. In summary, you are entitled to use this encoded model in absolutely any manner you deem suitable, verbatim, or with modification, alone or embedded it in a larger context, redistribute it, commercially or not, in a restricted way or not. To cite BioModels Database, please use: Li C, Donizelli M, Rodriguez N, Dharuri H, Endler L, Chelliah V, Li L, He E, Henry A, Stefan MI, Snoep JL, Hucka M, Le Novère N, Laibe C (2010) BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. BMC Syst Biol., 4:92.