Project description:The H2A.Z histone variant plays major roles in the control of gene expression. In human, H2A.Z is encoded by two genes expressing two isoforms, H2A.Z.1 and H2A.Z.2 differing by three amino acids. Here, we undertook an integrated analysis of the independent and interdependent functions of these two isoforms in gene expression using endogenously-tagged isoform. RNA-Seq analysis following depletion of either isoform or both together in untransformed cells showed that they can regulate both distinct and overlapping sets of genes positively or negatively in a context-dependent manner. Our data revealed that the two isoforms have similar or antagonistic function depending on the gene. H2A.Z.1 and H2A.Z.2 can replace each other at Transcription Start Sites, providing a molecular explanation for this interplay. Mass spectrometry analysis showed that H2A.Z.1 and H2A.Z.2 have specific interactors, PHF14 and associated proteins for H2A.Z.1 and the histone deacetylase SIRT1 for H2A.Z.2. Moreover, we show that PHF14 and SIRT1 mediate the functional antagonism between H2A.Z.1 and H2A.Z.2. In conclusion, we propose a model in which the balance between H2A.Z.1 and H2A.Z.2 at promoters is critically important to regulate specific gene expression and depends on the recruitment of specific proteins. Our work thus provides an additional layer of complexity to the control of gene expression by histone variants.

Project description:The H2A.Z histone variant plays major roles in the control of gene expression. In human, H2A.Z is encoded by two genes expressing two isoforms, H2A.Z.1 and H2A.Z.2 differing by three amino acids. Here, we undertook an integrated analysis of the independent and interdependent functions of these two isoforms in gene expression using endogenously-tagged isoform. RNA-Seq analysis following depletion of either isoform or both together in untransformed cells showed that they can regulate both distinct and overlapping sets of genes positively or negatively in a context-dependent manner. Our data revealed that the two isoforms have similar or antagonistic function depending on the gene. H2A.Z.1 and H2A.Z.2 can replace each other at Transcription Start Sites, providing a molecular explanation for this interplay. Mass spectrometry analysis showed that H2A.Z.1 and H2A.Z.2 have specific interactors, PHF14 and associated proteins for H2A.Z.1 and the histone deacetylase SIRT1 for H2A.Z.2. Moreover, we show that PHF14 and SIRT1 mediate the functional antagonism between H2A.Z.1 and H2A.Z.2. In conclusion, we propose a model in which the balance between H2A.Z.1 and H2A.Z.2 at promoters is critically important to regulate specific gene expression and depends on the recruitment of specific proteins. Our work thus provides an additional layer of complexity to the control of gene expression by histone variants.

Project description:The H2A.Z histone variant plays major roles in the control of gene expression. In human, H2A.Z is encoded by two genes expressing two isoforms, H2A.Z.1 and H2A.Z.2 differing by three amino acids. Here, we undertook an integrated analysis of the independent and interdependent functions of these two isoforms in gene expression using endogenously-tagged isoform. RNA-Seq analysis following depletion of either isoform or both together in untransformed cells showed that they can regulate both distinct and overlapping sets of genes positively or negatively in a context-dependent manner. Our data revealed that the two isoforms have similar or antagonistic function depending on the gene. H2A.Z.1 and H2A.Z.2 can replace each other at Transcription Start Sites, providing a molecular explanation for this interplay. Mass spectrometry analysis showed that H2A.Z.1 and H2A.Z.2 have specific interactors, PHF14 and associated proteins for H2A.Z.1 and the histone deacetylase SIRT1 for H2A.Z.2. Moreover, we show that PHF14 and SIRT1 mediate the functional antagonism between H2A.Z.1 and H2A.Z.2. In conclusion, we propose a model in which the balance between H2A.Z.1 and H2A.Z.2 at promoters is critically important to regulate specific gene expression and depends on the recruitment of specific proteins. Our work thus provides an additional layer of complexity to the control of gene expression by histone variants.

Project description:Pancreatic ductal adenocarcinoma is one of the most intractable and devastating of all malignant tumors. Epigenetic modifications involving both DNA methylation and histone modification have a relationship between tumor initiation and progression. However, the contribution of histone variants in the PDAC is unknown. Here, we demonstrated that the histone variant H2A.Z is highly expressed in PDAC cell lines and PDAC patients and its overexpression correlated with poor prognosis. We found that the three-histone H2A.Z isoforms (H2A.Z.1, H2A.Z.2.1 and, H2A.Z.2.2), are highly expressed in PDAC cell lines and PDAC patients. Knockdown of three H2A.Z isoforms induces a senescent phenotype, cell cycle arrest in phase G2/M, increased cyclin-dependent kinase inhibitor CDKN2A/p16, SA-β-galactosidase activity and interleukin 8 production in PDAC. Transcriptome analysis of knockdown of the H2A.Z isoforms showed altered gene expression in the fatty acid biosynthesis. As well as in the genes that control the cell cycle and DNA damage repair. Furthermore, H2A.Z isoform deficiency, reduces the tumor size in a mouse xenograft model in vivo, and sensitizes PDAC cells to gemcitabine. These results make H2A.Z a potential candidate as a diagnostic biomarker and therapeutic target for PDAC

Project description:Histone acetylation and deposition of H2A.Z variant are integral aspects of active transcrip-tion. In Drosophila, the single DOMINO chromatin regulator complex is thought to combine both activities via an unknown mechanism. Here we show that alternative isoforms of the DOMINO nucleosome remodeling ATPase, DOM-A and DOM-B, directly specify two distinct multi-subunit complexes. Both complexes are necessary for transcriptional regulation but through different mechanisms. The DOM-B complex incorporates H2A.V (the fly ortholog of H2A.Z) genome-wide in an ATP-dependent manner, like the yeast SWR1 complex. The DOM-A complex, instead, functions as an ATP-independent histone acetyltransferase com-plex similar to the yeast NuA4, targeting lysine 12 of histone H4. Our work provides an in-structive example of how different evolutionary strategies lead to similar functional separation. In yeast and humans, nucleosome remodeling and histone acetyltransferase complexes orig-inate from gene duplication and paralog specification. Drosophila generates the same diversi-ty by alternative splicing of a single gene.

Project description:Creating long-lasting memories relies on learning-induced changes in gene expression, which are regulated by epigenetic modifications of DNA and associated histone proteins. Post-translational modifications (PTMs) of histone proteins are key regulators of transcription, with different PTMs producing unique effects on gene activity and behavior. Although recent studies began to investigate histone variants as key regulators of memory formation, PTMs are rarely considered in relation to their function. Here, we analyze the role of acetylation of histone variant H2A.Z.1 in memory and gene expression. To this end, we developed AAV constructs to overexpress mutated H2A.Z.1 isoforms that either mimic acetylation (acetyl-mimetic) by replacing lysines 4, 7 and 11 with glutamine (KQ), or that have impaired acetylation (acetyl-defective) by replacing the same lysine with alanine (KA). We found that overexpression of the acetyl-mimetic (H2A.Z.1KQ) or the acetyl-defective (H2A.Z.1KA) isoforms of H2A.Z.1 in the hippocampus produces different effects on memory depending on strength of the task and sex, with H2A.Z.1KQ generally having a beneficial effect on memory, while H2A.Z.1KA results in impaired memory. We further analyzed gene expression data and found that H2A.Z.1KQ and H2A.Z.1KA uniquely impact the expression of different classes of genes in females and males. However, different genes are regulated by different isoforms in the 2 sexes. Finally, we describe, for the first time, that H2A.Z is involved in the alternative splicing of neuronal genes. Notably, H2A.Z depletion and its replacement with different isoforms influence transcription and splicing of different genes, suggesting that H2A.Z.1 can regulate genes through splicing and expression levels. This is the first study demonstrating that direct manipulation of the levels of AcH2A.Z regulates memory, gene expression and splicing. Overall, this study adds another layer of complexity to the contribution of histone variants to higher brain functions, consolidating H2A.Z as a key regulator of memory.

Project description:Creating long-lasting memories relies on learning-induced changes in gene expression, which are regulated by epigenetic modifications of DNA and associated histone proteins. Post-translational modifications (PTMs) of histone proteins are key regulators of transcription, with different PTMs producing unique effects on gene activity and behavior. Although recent studies began to investigate histone variants as key regulators of memory formation, PTMs are rarely considered in relation to their function. Here, we analyze the role of acetylation of histone variant H2A.Z.1 in memory and gene expression. To this end, we developed AAV constructs to overexpress mutated H2A.Z.1 isoforms that either mimic acetylation (acetyl-mimetic) by replacing lysines 4, 7 and 11 with glutamine (KQ), or that have impaired acetylation (acetyl-defective) by replacing the same lysine with alanine (KA). We found that overexpression of the acetyl-mimetic (H2A.Z.1KQ) or the acetyl-defective (H2A.Z.1KA) isoforms of H2A.Z.1 in the hippocampus produces different effects on memory depending on strength of the task and sex, with H2A.Z.1KQ generally having a beneficial effect on memory, while H2A.Z.1KA results in impaired memory. We further analyzed gene expression data and found that H2A.Z.1KQ and H2A.Z.1KA uniquely impact the expression of different classes of genes in females and males. However, different genes are regulated by different isoforms in the 2 sexes. Finally, we describe, for the first time, that H2A.Z is involved in the alternative splicing of neuronal genes. Notably, H2A.Z depletion and its replacement with different isoforms influence transcription and splicing of different genes, suggesting that H2A.Z.1 can regulate genes through splicing and expression levels. This is the first study demonstrating that direct manipulation of the levels of AcH2A.Z regulates memory, gene expression and splicing. Overall, this study adds another layer of complexity to the contribution of histone variants to higher brain functions, consolidating H2A.Z as a key regulator of memory.

Project description:The histone variant H2A.Z is one of the most evolutionally conserved histone variants. In vertebrates, two isoforms, H2A.Z.1 and H2A.Z.2, are identified and are involved in multiple epigenetic regulations. However, the role of H2A.Z in epigenetic regulations largely remains unknown especially in vertebrate. Previously, we derived tetracycline-inducible H2A.Z isofmrs double knockout (DKO) cells by using DT40 cells. With this cell, we showed that H2A.Z DKO leads to defects in mitotic progression and gene expression. To elucidate the function of H2A.Z further, we established genetic complementation system and confirmed that introducing exogenous H2A.Z complemented phenotypes of H2A.Z DKO cells. Given that acetylation of the N-terminal tail of H2A.Z reportedly contributes to significant roles in H2A.Z functions, we introduced two types of H2A.Z mutants, non-acetylable H2A.Z (5KR-H2A.Z) and chimeric H2A.Z in which its N-terminal tail is replaced with that of canonical H2A (H2A-H2A.Z), into H2A.Z DKO cells. These H2A.Z mutants complemented defects in mitotic progression. However, significant transcriptional dysregulation was observed in H2A.Z DKO cells stably expressing 5KR-H2A.Z and H2A-H2A.Z. These results suggest that the core domain and the N-terminal tail of the vertebrate H2A.Z contribute individually to mitotic progression and transcription regulation, respectively.

Project description:Stem-cells and transformed cancer cells specifically express a polycomb repressive complex subtype, PRC4 which characteristically contains Sirt1 (Sirtuin-1), a NAD+ dependent class III histone deacetylase (HDAC) and Eed2 isoform as specific members. Analyzing the transcriptiome and methylome analysis of Sirt1 deficient murine ESCs (Sirt1-/- ESC), we demonstrate that these cells repressed specifically on some genomic imprinted and germ-line related genes. We used microarrays to characterize the programm of gene expression affected by Sirt1 in murine ESCs and identified distinct classes of down-regulated genes upon Sirt1 deficiency

Project description:High mobility group proteins are chromatin regulators with essential functions in development, cell differentiation and cell proliferation. The protein HMG20A contains three well defined domains: an amino terminal intrinsically distorted domain, a high mobility group box with higher affinity for double stranded four-way-junction DNA than for lineal DNA and a long coiled-coil domain. Here we have found by a proteomic study that HMG20A copurify with the histone reader protein PHF14. Deletion analysis of the interaction domains and structural modeling by using AlphaFold2 software indicated that HMG20A forms a complex with PHF14 through the establishment of a two-stranded alpha-helical coiled-coil. Furthermore, PHF14 was essential for the stability and the chromatin localization of HMG20A. Transcriptomic analysis of triple negative human breast cancer cells demonstrated that PHF14 and HMG20A share a large subset of targets. PHF14 or HMG20A deficiency increased epithelial markers such as E-cadherin or p63 and components of the Hippo pathway and impaired mesenchymal phenotypes including cell migration, and invasion. Expression of mesenchymal adhesion molecules involved in metastasis such as L1CAM and LRRC15 were downregulated in PHF14 or HMG20A depleted cells in agreement with a decreased homotypic cell-cell adhesion ability. Inducible CRISPR inactivation of PHF14 or HMG20A genes impaired normal TGFβ-trigged epithelial to mesenchymal transition in mouse normal breast epithelial cells. Finally, we performed a meta-analysis of PHF14 and HMG20A genes in cancer databases. PHF14 gene is often amplified in different cancers which is associated to poor prognosis. In fact, high levels of PHF14 mRNA are associated to poor prognosis in many types of cancers. High expression of HMG20A and PHF14 are commonly associated to poor prognosis in sarcoma, colon and pancreas adenocarcinomas. In these tumors we found a clear correlation between the mRNA levels of both factors and also similar patterns of co-expressed genes with HMG20A and PHF14, indicating similar functions.