Project description:The eukaryotic genome is organized into chromatin, which constitutes the physiological template for DNA-dependent processes including replication, recombination, repair and transcription. Chromatin mediated transcription regulation involves histone modifications, chromatin remodeling and DNA methylation. However, the precise biological function of non-histone chromatin-associated proteins is still unclear. The high mobility group proteins are the most abundant non-histone chromatin-associated proteins. Here we combined proteomic, ChIP-seq and transcriptome data to decipher the mechanism of transcriptional regulation mediated by the high mobility group AT-hook protein 2 (HMGA2). We showed that HMGA2-induced transcription requires H2AX phosphorylation at S139 (H2AXS139ph; γ-H2AX), mediated by the kinase ataxia telangiectasia mutated (ATM). Furthermore, we demonstrated the relevance of this mechanism within the biological context of TGFB1-signaling. Our results link H2AXS139ph, a marker for DNA damage, to transcription, which is a new function for this histone modification. The interplay between HMGA2, ATM and H2AX is a novel mechanism of transcription initiation. Chip-seq data of HMGA2, H2AXS139ph and ATM obtained from Mouse embryonic Fibroblast cells in wt and Ko of Hmga2

Project description:The eukaryotic genome is organized into chromatin, which constitutes the physiological template for DNA-dependent processes including replication, recombination, repair and transcription. Chromatin mediated transcription regulation involves histone modifications, chromatin remodeling and DNA methylation. However, the precise biological function of non-histone chromatin-associated proteins is still unclear. The high mobility group proteins are the most abundant non-histone chromatin-associated proteins. Here we combined proteomic, ChIP-seq and transcriptome data to decipher the mechanism of transcriptional regulation mediated by the high mobility group AT-hook protein 2 (HMGA2). We showed that HMGA2-induced transcription requires H2AX phosphorylation at S139 (H2AXS139ph; γ-H2AX), mediated by the kinase ataxia telangiectasia mutated (ATM). Furthermore, we demonstrated the relevance of this mechanism within the biological context of TGFB1-signaling. Our results link H2AXS139ph, a marker for DNA damage, to transcription, which is a new function for this histone modification. The interplay between HMGA2, ATM and H2AX is a novel mechanism of transcription initiation.

Project description:Phosphorylation of the histone variant H2AX forms γ-H2AX that marks DNA double-strand break (DSB). Here we generated the sequencing-based maps of H2AX and γ-H2AX positioning in resting and proliferating cells before and after ionizing irradiation. Genome-wide locations of possible endogenous and exogenous DSBs were identified based on γ-H2AX distribution in dividing cancer cells without irradiation and that in resting cells upon irradiation, respectively. γ-H2AX-enriched regions of endogenous origin in replicating cells included telomeres and active transcription start sites, apparently reflecting replication- and transcription-mediated stress during rapid cell division. Surprisingly, H2AX itself, prior to phosphorylation, was specifically located at these endogenous hotspots. This phenomenon was only observed in dividing cancer cells but not in resting cells. Endogenous H2AX was concentrated on the transcription start site of actively transcribed genes but was irrelevant to pausing of RNA polymerase II (pol II), which precisely coincided with γ-H2AX of endogenous origin. γ-H2AX enrichment upon irradiation also coincided with actively transcribed regions, but unlike endogenous γ-H2AX, it extended into the gene body and was not specifically concentrated on the pausing site of pol II. Subtelomeres were not responsive to external DNA damage. Our findings provide insight into DNA repair programs of cancer and may have implications for cancer therapy.

Project description:The eukaryotic genome is organized into chromatins, the physiological template for DNA-dependent processes including replication, recombination, repair, and transcription. Chromatin-mediated transcription regulation involves DNA methylation, chromatin remodeling, and histone modifications. However, chromatin also contains non-histone chromatin-associated proteins, of which the high-mobility group (HMG) proteins are the most abundant. Although it is known that HMG proteins induce structural changes of chromatin, the processes underlying transcription regulation by HMG proteins are poorly understood. Here we decipher the molecular mechanism of transcription regulation mediated by the HMG AT-hook 2 protein (HMGA2). We combined proteomic, ChIP-seq, and transcriptome data to show that HMGA2-induced transcription requires phosphorylation of the histone variant H2AX at S139 (H2AXS139ph; γ-H2AX) mediated by the protein kinase ataxia telangiectasia mutated (ATM). Furthermore, we demonstrate the biological relevance of this mechanism within the context of TGFβ1 signaling. The interplay between HMGA2, ATM, and H2AX is a novel mechanism of transcription initiation. Our results link H2AXS139ph to transcription, assigning a new function for this DNA damage marker. Controlled chromatin opening during transcription may involve intermediates with DNA breaks that may require mechanisms that ensure the integrity of the genome.

Project description:Phosphorylation of the histone variant H2AX forms γ-H2AX, which serves as a marker of DNA repair response. Here we provide ChIP-seq-based maps of histone H2AX, γ-H2AX, H2AZ, INO80, SRCAP, and RNA polymerase II in activated T cells. Matched data for H2AX and γ-H2AX in resting T cells and Jurkat cancer T cells are available in GSE25577.

Project description:Phosphorylation of the histone variant H2AX forms M-NM-3-H2AX that marks DNA double-strand break (DSB). Here we generated the sequencing-based maps of H2AX and M-NM-3-H2AX positioning in resting and proliferating cells before and after ionizing irradiation. Genome-wide locations of possible endogenous and exogenous DSBs were identified based on M-NM-3-H2AX distribution in dividing cancer cells without irradiation and that in resting cells upon irradiation, respectively. M-NM-3-H2AX-enriched regions of endogenous origin in replicating cells included telomeres and active transcription start sites, apparently reflecting replication- and transcription-mediated stress during rapid cell division. Surprisingly, H2AX itself, prior to phosphorylation, was specifically located at these endogenous hotspots. This phenomenon was only observed in dividing cancer cells but not in resting cells. Endogenous H2AX was concentrated on the transcription start site of actively transcribed genes but was irrelevant to pausing of RNA polymerase II (pol II), which precisely coincided with M-NM-3-H2AX of endogenous origin. M-NM-3-H2AX enrichment upon irradiation also coincided with actively transcribed regions, but unlike endogenous M-NM-3-H2AX, it extended into the gene body and was not specifically concentrated on the pausing site of pol II. Subtelomeres were not responsive to external DNA damage. Our findings provide insight into DNA repair programs of cancer and may have implications for cancer therapy. Profiles of H2AX and gamma-H2AX in normal resting and cancer T cells with and without ionizing irradiation.

Project description:Phosphorylation of histone H2AX is an early response to DNA damage in eukaryotes. In Saccharomyces cerevisiae, DNA damage or replication fork stalling results in histone H2A phosphorylation to yield gamma-H2A (yeast gamma-H2AX) in a Mec1 (ATR)- and Tel1 (ATM)- dependent manner. Here, we describe the genome-wide location analysis of gamma-H2A as a strategy to identify loci prone to engage the Mec1 and Tel1 pathways. Remarkably, gamma-H2A enrichment overlaps with loci prone to replication fork stalling and is caused by the action of Mec1 and Tel1, indicating that these loci are prone to breakage. Moreover, about half the sites enriched for gamma-H2A map to repressed protein-coding genes, and histone deacetylases are necessary for formation of gamma-H2A at these loci. Finally, our work indicates that high resolution mapping of gamma-H2AX is a fruitful route to map fragile sites in eukaryotic genomes.

Project description:Phosphorylation of the histone variant H2AX forms γ-H2AX, which serves as a marker of DNA repair response. Here we provide ChIP-seq-based maps of histone H2AX, γ-H2AX, H2AZ, INO80, SRCAP, and RNA polymerase II in activated T cells. Matched data for H2AX and γ-H2AX in resting T cells and Jurkat cancer T cells are available in GSE25577. CD4+ T cells were stimulated in two different ways (IL-2 alone or IL-2 plus anti-CD3 and anti-CD28), and H2AX, γ-H2AX, H2AZ, INO80, and SRCAP profiles were examined by ChIP-seq

Project description:H2AX has been characterized as a novel tumor suppressor protein. Difficiency of H2AX will result in apoptotic inhibition of cancer cells. However, how H2AX epigenetically regulates apoptosis of cancer cells is still unclear. To reveal the genes expression regulated by H2AX and involved in apoptosis, the microarray profiling analysis was employed to identify differentially expressed genes in H2AX knockdown lung cancer cells and control ones after apoptotic induction. H2AX was knockdown by miRNA interfering system in human lung cancer originated cell A549 and the stable cell line named P1, while the control stable cell line named C. Genes with greater than 1.2-fold change and P-value ＜0.05 were identified as differentially expressed genes between C and P1 cells both with apoptosis induction.

Project description:H2AX has been characterized as a novel tumor suppressor protein. Difficiency of H2AX will result in apoptotic inhibition of cancer cells. However, how H2AX epigenetically regulates apoptosis of cancer cells is still unclear To reveal the miRNA expression regulated by H2AX and involved in apoptosis, the microarray profiling analysis was employed to identify differentially expressed miRNAs in H2AX knockdown lung cancer cells and control ones after apoptotic induction. H2AX was knockdown by miRNA interfering system in human lung cancer originated cell A549 and the stable cell line named P1, while the control stable cell line named C. Genes with greater than 1.5-fold change and P-value ＜0.05 were identified as differentially expressed genes between C and P1 cells both with apoptosis induction.