Project description:Previous studies suggested that MeCP2 binds to linker DNA and competes with linker histone H1 to regulate chromatin structure, but this hypothesis has never been tested in vivo. Here, we expressed Flag-tagged H1.0 in forebrain excitatory neurons in mice and performed ChIP-Seq to reveal H1.0 distribution and its relationship with MeCP2. Unexpectedly, we detected no major change in H1.0 upon MeCP2 depletion, revealing that MeCP2 functions independent of linker H1.0.

Project description:Previous studies suggested that MeCP2 binds to linker DNA and competes with linker histone H1 to regulate chromatin structure, but this hypothesis has never been tested in vivo. Here, we expressed Flag-tagged H1.0 in forebrain excitatory neurons in mice and performed ChIP-Seq to reveal H1.0 distribution and its relationship with MeCP2. Unexpectedly, we detected no major change in H1.0 upon MeCP2 depletion, revealing that MeCP2 functions independent of linker H1.0.

Project description:Eukaryotic nuclei encase the genome and differentially package it for the various needs of distinct cell types. Tuning of genome structure and function is accomplished by chromatin binding proteins, which are responsive to cellular stress, determining the transcriptome and phenotype of the cell. We sought to investigate the connection between extracellular stress and chromatin structure to regulate cellular stiffness. We demonstrate that the linker histone H1.0, which compacts nucleosomes into higher order chromatin fibers, controls genome structure and cellular response to stress. Histone H1.0 has privileged expression in tension-responsive fibroblasts across tissue types in mouse and humans, and is necessary and sufficient to mount a myofibroblast phenotype in these cells. Loss of histone H1.0 prevents transforming growth factor beta (TGF-b)-induced fibroblast contraction, proliferation and migration in an isoform-specific manner via inhibition of a transcriptome targeting extracellular matrix molecules. Histone H1.0 is associated with local regulation of gene expression by chromatin fiber compaction and histone acetylation, rendering the nucleus and cell stiffer in response to cytokine stimulation. Knockdown of H1.0 decreased levels of HDAC1 and the chromatin reader BRD4, thereby preventing transcription of a fibrotic gene program. Transient depletion of histone H1.0 in vivo decompacts chromatin and prevents fibrosis in cardiac muscle, lung, and kidney, thereby linking chromatin structure with fibroblast phenotype in response to extracellular stress. Our work identifies an unexpected role of linker histones to sense and respond to cellular stress, directly coupling cellular tension, nuclear organization and gene transcription.

Project description:Eukaryotic nuclei encase the genome and differentially package it for the various needs of distinct cell types. Tuning of genome structure and function is accomplished by chromatin binding proteins, which are responsive to cellular stress, determining the transcriptome and phenotype of the cell. We sought to investigate the connection between extracellular stress and chromatin structure to regulate cellular stiffness. We demonstrate that the linker histone H1.0, which compacts nucleosomes into higher order chromatin fibers, controls genome structure and cellular response to stress. Histone H1.0 has privileged expression in tension-responsive fibroblasts across tissue types in mouse and humans, and is necessary and sufficient to mount a myofibroblast phenotype in these cells. Loss of histone H1.0 prevents transforming growth factor beta (TGF-b)-induced fibroblast contraction, proliferation and migration in an isoform-specific manner via inhibition of a transcriptome targeting extracellular matrix molecules. Histone H1.0 is associated with local regulation of gene expression by chromatin fiber compaction and histone acetylation, rendering the nucleus and cell stiffer in response to cytokine stimulation. Knockdown of H1.0 decreased levels of HDAC1 and the chromatin reader BRD4, thereby preventing transcription of a fibrotic gene program. Transient depletion of histone H1.0 in vivo decompacts chromatin and prevents fibrosis in cardiac muscle, lung, and kidney, thereby linking chromatin structure with fibroblast phenotype in response to extracellular stress. Our work identifies an unexpected role of linker histones to sense and respond to cellular stress, directly coupling cellular tension, nuclear organization and gene transcription.

Project description:Identification of H1.0 genome wide distribution in in-vitro transformed fibroblast before its silencing in tumor CSCs and the localization of the histone modifications H3K27me3 and H3K4me3.

Project description:Identification of HDACi-responsive, H1.0-dependent genes inhibiting self-renewal of HCC1569 breast cancer cells.

Project description:Identification of enrichment for H3K27ac and H3K27me3 in in vitro generated CSCs, following the knockdown of the histone linker H1.0

Project description:Identification of nucleosome-free, active regulatory regions in in vitro generated CSCs, following the knockdown of the histone linker H1.0

Project description:Identification of genes regulated by the histone variant H1.0 by RNA-seq analysis of cell lines expressing inducible specific shRNAs.

Project description:The conditions of the tumor microenvironment, such as nutrient starvation, play critical roles in cancer progression. However, the role of glutamine deprivation in cancer progression is not studied as extensively as that of hypoxia. Here, we show that glutamine starvation triggered down-regulation of PCYT2 by stimulating accumulation of PEtn. Interestingly, glutamine upregulated series of glutamine-responsive genes, not only PCYT2. Furthermore, glutamine-responsive genes were associated with overall survival of cancer patients. Thus, our findings show that glutamine responsive genes such as PCYT2 are key for progression of cancer cells, partly protecting cancer cells to glutamine starvation.