Project description:In mammals, chromosome-wide regulatory mechanisms ensure a balance of X-linked gene dosage between males (XY) and females (XX). In female cells, expression of genes from one of the two X-chromosomes is curtailed, with selective accumulation of Xist-RNA, Xist-associated proteins, specific histone modifications (eg. H3K27me3) and Barr body formation observed throughout interphase. Using chromosome flow-sorting, we show that during mitosis, Xist-associated proteins dissociate from inactive X (Xi) chromosomes, while high levels of H3K27me3 and increased compaction of the Xi relative to active X (Xa), are retained. Proteomic comparison of mitotic Xi and Xa revealed, unexpectedly, that components of Hbo1 and Msl/Mof histone acetyltransferase complexes co-enrich with Xa, while inhibitors of histone acetylation co-enrich with Xi. Furthermore, inhibition of Hbo1 or deletion of Msl/Mof components functionally abolishes mitotic differences in H3K27me3 marking and chromosome compaction. These data uncover critical roles for acetylation pathways in preserving X chromosome properties during mitosis.

Project description:The product of dosage compensation in human females is the compacted inactive X chromosome (Xi). Here we show that loss of SET domain bifurcated 1 (SETDB1) results in decompaction of the Xi territory coupled with reactivation on the Xi of a powerful enhancer within the 1.4 Mb interleukin-1 receptor accessory protein like 1 (IL1RAPL1) gene at Xp21.2. The enhancer is centrally located in a 0.5 Mb region corresponding to the 3’ third of the IL1RAPL1 locus that transitions from a heterochromatic territory to a euchromatic configuration on the Xi in the absence of SETDB1. This same region showing chromatin instability is part of a common chromosome fragile site that is frequently deleted or rearranged in patients afflicted with intellectual disability and other neurological ailments. Immediately adjacent to the enhancer is an ERVL-MaLR element that drives bi-directional transcription of novel long sense and antisense transcripts. Deletion of the enhancer from the Xa (but not Xi), resulted in detection of bi-directional expression from the Xi coupled with decompaction of the chromosome territory, supporting a critical role for SETDB1 in maintaining this interval in a silent state to facilitate Xi compaction.

Project description:X-chromosome inactivation (XCI) achieves dosage compensation between males and females through the silencing of the majority of genes on one X chromosome, with approximately 15% of genes reported to show inactive X (Xi) expression. We examined the interplay between ChromHMM states, CpG density, expression and DNAm from over 1800 female samples with the Illumina 450K array. The interaction between CpG density and histone marks differed between the active X (Xa) and the Xi, with X-linked promoters reflecting transcriptional status, while the Xi showed lower DNAm than the Xa at all non-promoter regions. Promoter DNAm was used to determine a novel XCI status for more than 100 transcription start sites and a comparison across 27 tissues revealed the majority of genes were consistently subject to XCI. Inter-female and twin data supported a model of predominately cis-acting influences on escape, or variable escape, from XCI. Increased promoter DNAm at escape genes correlated with decreased relative Xi expression up to ~15% female DNAm but above this threshold DNAm was not correlated with the stability of silencing. Xi DNAm was ~12% lower than Xa DNAm within the gene bodies of subject genes and between genes while there was equivalent DNAm at escape genes. In addition to offering insight into sex-specific difference in disease, female X chromosomes provide the opportunity to compare euchromatin and heterochromatin of allelic regions within the same nuclear environment and demonstrate the correlation of DNAm with transcription and the influences of CpG density and chromatin marks.

Project description:Dosage compensation in mammals occurs at two levels. In addition to balancing X-chromosome dosage between males and females via X-inactivation, mammals also balance dosage of Xs and autosomes. It has been proposed that X-autosome equalization occurs by upregulation of Xa (active X). To investigate the mechanism, we perform allele-specific ChIP-seq for chromatin epitopes and analyze RNA-seq data (SRA010053). The hypertranscribed Xa demonstrates enrichment of active chromatin marks relative to autosomes. We derive predictive models for relationships among Pol II, active mark densities and gene expression, and we suggest that Xa upregulation involves increased transcription initiation and elongation. Enrichment of active marks on Xa does not scale proportionally with transcription output, a disparity explained by nonlinear quantitative dependencies among active histone marks, Pol II occupancy and transcription. Notably, the trend of nonlinear upregulation also occurs on autosomes. Thus, Xa upregulation involves combined increases of active histone marks and Pol II occupancy, without invoking X-specific dependencies between chromatin states and transcription.

Project description:X chromosome inactivation (XCI) is a dosage compensation mechanism that silences the majority of genes on one X chromosome in each female cell. In order to characterize epigenetic changes that accompany this process, we measured DNA methylation levels in both 45,X Turner syndrome patients, who carry a single active X chromosome (Xa) and normal 46,XX females, who carry one Xa and one inactive X (Xi). Methylated DNA was immunoprecipitated and hybridized to tiling oligonucleotide arrays, generating epigenetic profiles of active and inactive X chromosomes. We observed that XCI is accompanied by changes in DNA methylation specifically at CpG islands. While the majority of CpG islands show increased methylation levels on the Xi, XCI results in reduced methylation at ~20% of CpG islands. Both intra- and inter-genic CpG islands are epigenetically modified, with the biggest increase in methylation occuring at the promoters of genes silenced by XCI. In contrast, genes escaping XCI have low levels of promoter methylation, while genes that undergo polymorphic silencing show intermediate increases in methylation proportionate to their frequency of inactivation. Thus promoter methylation and susceptibility to XCI are correlated. We observed a global correlation between CpG island methylation and the evolutionary age of different X chromosome strata, and that genes escaping XCI show increased methylation within gene bodies. We utilized our epigenetic map to predict both novel genes escaping XCI, and to identify sequence features that may contribute to the XCI process. Finally, as our study included Turner syndrome patients with single X chromosomes of both maternal and paternal origin we searched for parent-of-origin specific methylation differences, but found no evidence to support imprinting on the human X chromosome. Our study provides the first epigenetic profile of active and inactive X chromosomes, giving novel insights into the phenomenon of dosage compensation.

Project description:X Chromosome Inactivation (XCI) equalizes X-linked gene expression between sexes. B cells exhibit dynamic XCI, with Xist RNA/heterochromatic marks absent on the inactive X (Xi) in naive B cells but returning following mitogenic stimulation. The impact of dynamic XCI on Xi structure and maintenance was previously unknown. Here, we find dosage compensation of the Xi with state-specific XCI escape genes in naive and in vitro activated B cells. Allele-specific OligoPaints indicate similar Xi and Xa territories in B cells that are less compact than in fibroblasts. Allele-specific Hi-C reveals a lack of TAD-like structures on the Xi of naive B cells, and stimulation-induced alterations in TAD-like boundary strength independent of gene expression. Notably, Xist deletion in B cells changes TAD boundaries and large-scale Xi compaction. Altogether, our results uncover B cell-specific Xi plasticity which could underlie sex-biased biological mechanisms.

Project description:X Chromosome Inactivation (XCI) equalizes X-linked gene expression between sexes. B cells exhibit dynamic XCI, with Xist RNA/heterochromatic marks absent on the inactive X (Xi) in naive B cells but returning following mitogenic stimulation. The impact of dynamic XCI on Xi structure and maintenance was previously unknown. Here, we find dosage compensation of the Xi with state-specific XCI escape genes in naive and in vitro activated B cells. Allele-specific OligoPaints indicate similar Xi and Xa territories in B cells that are less compact than in fibroblasts. Allele-specific Hi-C reveals a lack of TAD-like structures on the Xi of naive B cells, and stimulation-induced alterations in TAD-like boundary strength independent of gene expression. Notably, Xist deletion in B cells changes TAD boundaries and large-scale Xi compaction. Altogether, our results uncover B cell-specific Xi plasticity which could underlie sex-biased biological mechanisms.

Project description:X chromosome inactivation (XCI) is a dosage compensation mechanism that silences the majority of genes on one X chromosome in each female cell. In order to characterize epigenetic changes that accompany this process, we measured DNA methylation levels in both 45,X Turner syndrome patients, who carry a single active X chromosome (Xa) and normal 46,XX females, who carry one Xa and one inactive X (Xi). Methylated DNA was immunoprecipitated and hybridized to tiling oligonucleotide arrays, generating epigenetic profiles of active and inactive X chromosomes. We observed that XCI is accompanied by changes in DNA methylation specifically at CpG islands. While the majority of CpG islands show increased methylation levels on the Xi, XCI results in reduced methylation at ~20% of CpG islands. Both intra- and inter-genic CpG islands are epigenetically modified, with the biggest increase in methylation occuring at the promoters of genes silenced by XCI. In contrast, genes escaping XCI have low levels of promoter methylation, while genes that undergo polymorphic silencing show intermediate increases in methylation proportionate to their frequency of inactivation. Thus promoter methylation and susceptibility to XCI are correlated. We observed a global correlation between CpG island methylation and the evolutionary age of different X chromosome strata, and that genes escaping XCI show increased methylation within gene bodies. We utilized our epigenetic map to predict both novel genes escaping XCI, and to identify sequence features that may contribute to the XCI process. Finally, as our study included Turner syndrome patients with single X chromosomes of both maternal and paternal origin we searched for parent-of-origin specific methylation differences, but found no evidence to support imprinting on the human X chromosome. Our study provides the first epigenetic profile of active and inactive X chromosomes, giving novel insights into the phenomenon of dosage compensation. Methylated DNA was enriched by immunoprecipitation using antibodies against 5-methylcytosine. meDIP and input DNA was labeled with cy5 and cy3 respectively and hybridized to Nimblegen arrays comprising 2.1 million 50-85mers covering human chromosomes 20, 21, 22, X and Y at a mean density of ~1 probe per 100bp. Resulting log2 fluorescence ratios correspond to methylation levels. Seven patients with Turner syndrome (45,X karyotype), and three normal females (46,XX karyotype) were analyzed. Of the Turner syndrome cases, four had a maternally-derived X, and three had a paternally-derived X chromosome.

Project description:Females show an advantage in lifespan and cognition in aging human populations. The X chromosome is a major source of sex difference, as female mammals harbor an inactive (Xi) and active (Xa) following X chromosome inactivation (XCI). Whether Xi – or the silent X – can activate in the aging brain and thus increase X dose is unknown. Here, we performed single nuclei RNA-sequencing in the young and aging hippocampus of female mice and applied allele-specific computational analysis. We show that aging remodels transcription of Xi and Xa across hippocampal cell types. Aging preferentially induced gene expression changes on the X chromosomes compared to the autosomes. Xi underwent activation and repression of select genes, particularly in dentate gyrus neurons, critical to learning and memory.

Project description:Dosage compensation in mammals occurs at two levels. In addition to balancing X-chromosome dosage between males and females via X-inactivation, mammals also balance dosage of Xs and autosomes. It has been proposed that X-autosome equalization occurs by upregulation of Xa (active X). To investigate the mechanism, we perform allele-specific ChIP-seq for chromatin epitopes and analyze RNA-seq data (SRA010053). The hypertranscribed Xa demonstrates enrichment of active chromatin marks relative to autosomes. We derive predictive models for relationships among Pol II, active mark densities and gene expression, and we suggest that Xa upregulation involves increased transcription initiation and elongation. Enrichment of active marks on Xa does not scale proportionally with transcription output, a disparity explained by nonlinear quantitative dependencies among active histone marks, Pol II occupancy and transcription. Notably, the trend of nonlinear upregulation also occurs on autosomes. Thus, Xa upregulation involves combined increases of active histone marks and Pol II occupancy, without invoking X-specific dependencies between chromatin states and transcription. Examination of 4 marks of active transcription (H3K4me3, H3K36me3, POL-II-S2P, POL-II-S5P) in a transformed female mouse embryonic fibroblast cell line (EY.T4).