Project description:This model is described in the article: Kinetics of histone gene expression during early development of Xenopus laevis. Koster JG, Destrée OH and Westerhoff HV. J Theor Biol. 1988 Nov 21;135(2):139-67. PMID: 3267765 Abstract: Using literature data for transcriptional and translational rate constants, gene copy numbers, DNA concentrations, and stability constants, we have calculated the expected concentrations of histones and histone mRNA during embryogenesis of Xenopus laevis. The results led us to conclude that: (i) for X. laevis the gene copy number of the histone genes is too low to ensure the synthesis of sufficient histones during very early development, inheritance from the oocyte of either histone protein or histone mRNA (but not necessarily both) is necessary; (ii) from the known storage of histones in the oocyte and the rates of histone synthesis determined by Adamson and Woodland (1977), there would be sufficient histones to structure the newly synthesized DNA up to gastrulation but not thereafter (these empirical rates of histone synthesis may be underestimates); (iii) on the other hand, the amount of H3 mRNA recently observed during early embryogenesis (Koster, 1987, Koster et al., 1988) could direct a higher and sufficient synthesis of H3 protein, also after gastrulation. We present a quantitative model that accounts both for the observed H3 mRNA concentration as a function of time during embryogenesis and for the synthesis of sufficient histones to structure the DNA throughout early embryogenesis. The model suggests that X. laevis exhibits a major (i.e. some 14-fold) reduction in transcription of histone genes approximately 11 hours after fertilization. This reduction could be due to a decrease in the number of transcribed histone genes, a decreased rate constant of transcription with continued transcription of all the histone genes, and/or a reduction in the time during the cell cycle in which histone mRNA synthesis takes place. Alternatively, the histone mRNA stability might decrease approximately 16-fold 11 hours after fertilization. This model originates from BioModels Database: A Database of Annotated Published Models. It is copyright (c) 2005-2011 The BioModels.net Team. 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.

Project description:Cellular senescence is a stable proliferation arrest that suppresses tumorigenesis. Histone chaperone HIRA deposits nucleosome-destabilizing histone variant H3.3 into chromatin in a DNA replication-independent manner. Histone H3.3 and a subset of other typically M-bM-^@M-^\replication-dependentM-bM-^@M-^] core histones were expressed in non-proliferating senescent cells, the latter linked to alternative mRNA splicing and polyadenylation. Senescent cells incorporated newly-synthesized histones into chromatin, partially dependent on HIRA. HIRA and newly-deposited histone H3.3 co-localized at promoters of expressed genes, and their distribution shifted between proliferating and senescent cells, paralleling changes in gene expression. In senescent cells, gene promoters showed exceptional enrichment of a histone acetylation linked to open and dynamic chromatin, H4K16ac. Abundance of H4K16ac depended on HIRA. In the mouse, inactivation of HIRA downregulated H4K16ac and dramatically enhanced oncogene-induced hyperplasia. To conclude, HIRA controls a previously undefined dynamic non-canonical H4K16ac-decorated chromatin landscape in senescence, and also plays an unanticipated role in suppression of oncogene-induced neoplasia. Examination of HIRA protein binding alongside histone modification H4K16ac and H3.3 in proliferating and senescent IMR90 cells

Project description:Cellular senescence is a stable proliferation arrest that suppresses tumorigenesis. Histone chaperone HIRA deposits nucleosome-destabilizing histone variant H3.3 into chromatin in a DNA replication-independent manner. Histone H3.3 and a subset of other typically “replication-dependent” core histones were expressed in non-proliferating senescent cells, the latter linked to alternative mRNA splicing and polyadenylation. Senescent cells incorporated newly-synthesized histones into chromatin, partially dependent on HIRA. HIRA and newly-deposited histone H3.3 co-localized at promoters of expressed genes, and their distribution shifted between proliferating and senescent cells, paralleling changes in gene expression. In senescent cells, gene promoters showed exceptional enrichment of a histone acetylation linked to open and dynamic chromatin, H4K16ac. Abundance of H4K16ac depended on HIRA. In the mouse, inactivation of HIRA downregulated H4K16ac and dramatically enhanced oncogene-induced hyperplasia. To conclude, HIRA controls a previously undefined dynamic non-canonical H4K16ac-decorated chromatin landscape in senescence, and also plays an unanticipated role in suppression of oncogene-induced neoplasia.

Project description:Chromatin organisation is disrupted genome wide during DNA replication. On newly synthesized DNA, nucleosomes are assembled from new naïve histones and old modified histones. It remains unknown whether the landscape of histone post-translational modifications (PTMs) is copied during DNA replication or the epigenomeis perturbed. Here we develop Chromatin Occupancy after Replication, ChOR-seq, a technology that combines chromatin immunopreciptation of histone marks and purification of newly replicated DNA by streptavidin pull-down followed by next generation sequencing. We use this technology to address propagation of epigenetic states across cell division and reveal that accurate recycling of modified parental histones ensures that positional information of histone marks is faithfully reproduced on daughter strands and inherited to daughter cells.

Project description:Chromatin organisation is disrupted genome wide during DNA replication. On newly synthesized DNA, nucleosomes are assembled from new naïve histones and old modified histones. It remains unknown whether the landscape of histone post-translational modifications (PTMs) is copied during DNA replication or the epigenomeis perturbed. Here we develop Chromatin Occupancy after Replication, ChOR-seq, a technology that combines chromatin immunopreciptation of histone marks and purification of newly replicated DNA by streptavidin pull down followed by next generation sequencing. We use this technology to address propagation of epigenetic states across cell division and reveal that accurate recycling of modified parental histones ensures that positional information of histone marks is faithfully reproduced on daughter strands and inherited to daughter cells.

Project description:Chromatin organisation is disrupted genome wide during DNA replication. On newly synthesized DNA, nucleosomes are assembled from new naïve histones and old modified histones. It remains unknown whether the landscape of histone post-translational modifications (PTMs) is copied during DNA replication or the epigenomeis perturbed. Here we develop Chromatin Occupancy after Replication, ChOR-seq, a technology that combines chromatin immunopreciptation of histone marks and purification of newly replicated DNA by streptavidin pull-down followed by next generation sequencing. We use this technology to address propagation of epigenetic states across cell division and reveal that accurate recycling of modified parental histones ensures that positional information of histone marks is faithfully reproduced on daughter strands and inherited to daughter cells.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.