Project description:Potential functional coordination between histone deubiquitinases and histone lysine demethylases represents one of the least studied aspects of epigenetic control of transcriptional outcomes. Here, this question was addressed using Arabidopsis histone modification erasers deubiquitinase OTLD1 and demethylase KDM1C known to interact with each other in plant cells. Characterization of gain- and loss-of-function mutants of OTLD1 and KDM1C showed that both enzymes associate with the promoter chromatin of their target gene AN3 and function as coactivators of its expression. This transcriptional outcome was underlain by demethylation of the H3K9 repression mark, presumably by the KDM1C histone demethylase activity. Association of KDM1C and OTLD1 with the target chromatin was interdependent such that OTLD1 was not detected at the AN3 in the absence of KDM1C and KDM1C displayed a different and non-functional pattern of association in the absence of OTLD1. Thus, OTLD1 and KDM1C may crosstalk with each other to assemble a functional coactivator complex at the AN3 promoter chromatin and set the KDM1C specificity for the methylated H3K9 to determine the correct transcriptional outcome.

Project description:LSD1 (KDM1 under the new nomenclature) was the first identified lysine-specific histone demethylase belonging to the flavin-dependent amine oxidase family. Here, we report that AOF1 (KDM1B under the new nomenclature), a mammalian protein related to LSD1, also possesses histone demethylase activity with specificity for H3K4me1 and H3K4me2. Like LSD1, the highly conserved SWIRM domain is required for its enzymatic activity. However, AOF1 differs from LSD1 in several aspects. First, AOF1 does not appear to form stable protein complexes containing histone deacetylases. Second, AOF1 is found to localize to chromosomes during the mitotic phase of the cell cycle, whereas LSD1 does not. Third, AOF1 represses transcription when tethered to DNA and this repression activity is independent of its demethylase activity. Structural and functional analyses identified its unique N-terminal Zf-CW domain as essential for the demethylase activity-independent repression function. Collectively, our study identifies AOF1 as the second histone demethylase in the family of flavin-dependent amine oxidases and reveals a demethylase-independent repression function of AOF1.

Project description:Osterix (Osx) is an osteoblast-specific transcriptional factor and is required for osteoblast differentiation and bone formation. A JmjC domain-containing protein NO66 was previously found to participate in regulation of Osx transcriptional activity and plays an important role in osteoblast differentiation through interaction with Osx. Here, we report the crystal structure of NO66 forming in a functional tetramer. A hinge domain links the N-terminal JmjC domain and C-terminal winged helix-turn-helix domain of NO66, and both domains are essential for tetrameric assembly. The oligomerization interface of NO66 interacts with a conserved fragment of Osx. We show that the hinge domain-dependent oligomerization of NO66 is essential for inhibition of Osx-dependent gene activation. Our findings suggest that homo-oligomerization of JmjC domain containing proteins might play a physiological role through interactions with other regulatory factors during gene expression.

Project description:Histone monoubiquitination is associated with active chromatin and plays an important role in epigenetic regulation of gene expression in plants. Deubiquitinating enzymes remove the ubiquitin group from histones and thereby contribute to gene repression. The Arabidopsis thaliana genome encodes 50 deubiquitinases, yet only 2 of them-UBP26 and OTLD1, members of the USP/UBP (ubiquitin-specific protease and ubiquitin-binding protein) and OTU (ovarian tumor protease) deubiquitinase families-are known to target histones. Furthermore, UBP26 is the only plant histone deubiquitinase for which the functional role has been characterized in detail. We used gain- and loss-of-function alleles of OTLD1 to examine its role in the plant life cycle and showed that OTLD1 stimulates plant growth, increases cell size, and induces transcriptional repression of five major regulators of plant organ growth and development: GA20OX, WUS, OSR2, ARL, and ABI5 OTLD1 associated with chromatin at each of these target genes and promoted the removal of euchromatic histone acetylation, ubiquitination, and methylation marks. Thus, these data indicate that OTLD1 promotes the concerted epigenetic regulation of a set of genes that collectively limit plant growth.

Project description:One of the main mechanisms of epigenetic control is post translational modification of histones, and one of the relatively less characterized, yet functionally important histone modifications is monoubiquitylation, which is reversed by histone deubiquitinases. In Arabidopsis, only two of such enzymes are known to date. One of them, OTLD1, deubiquitylates histone 2B and functions as a transcriptional repressor. But, could the same deubiquitinase act both as a repressor and an activator? Here, we addressed this question. Using gain-of-function and loss-of-function Arabidopsis alleles, we showed that OTLD1 can promote expression of a target gene. This transcriptional activation activity of OTLD1 involves occupation of the target chromatin by this enzyme, deubiquitination of monoubiquitylated H2B within the occupied regions, and formation of the euchromatic histone acetylation and methylation marks. Thus, OTLD1 can play a dual role in transcriptional repression and activation of its target genes. In these reactions, H2B ubiquitylation acts as both a repressive and an active mark whereas OTLD1 association with and deubiquitylation of the target chromatin may represent the key juncture between two opposing effects of this enzyme on gene expression.

Project description:BackgroundThe transcription factor GATA-2 is predominantly expressed in hematopoietic stem and progenitor cells and counteracts the erythroid-specific transcription factor GATA-1, to modulate the proliferation and differentiation of hematopoietic cells. During hematopoietic cell differentiation, GATA-2 exhibits dynamic expression patterns, which are regulated by multiple transcription factors.MethodsStable LSD1-knockdown cell lines were established by growing murine erythroleukemia (MEL) or mouse embryonic stem cells together with virus particles, in the presence of Polybrene(®) at 4 ?g/mL, for 24-48 hours followed by puromycin selection (1 ?g/mL) for 2 weeks. Real-time polymerase chain reaction (PCR)-based quantitative chromatin immunoprecipitation (ChIP) analysis was used to test whether the TAL1 transcription factor is bound to 1S promoter in the GATA-2 locus or whether LSD1 colocalizes with TAL1 at the 1S promoter. The sequential ChIP assay was utilized to confirm the role of LSD1 in the regulation of H3K4me2 at the GATA-2 locus during erythroid differentiation. Western blot analysis was employed to detect the protein expression. The alamarBlue(®) assay was used to examine the proliferation of the cells, and the absorbance was monitored at optical density (OD) 570 nm and OD 600 nm.ResultsIn this study, we showed that LSD1 regulates the expression of GATA-2 during erythroid differentiation. Knockdown of LSD1 results in increased GATA-2 expression and inhibits the differentiation of MEL and embryonic stem cells. Furthermore, we demonstrated that LSD1 binds to the 1S promoter of the GATA-2 locus and suppresses GATA-2 expression, via histone demethylation.ConclusionOur data revealed that LSD1 mediates erythroid differentiation, via epigenetic modification of the GATA-2 locus.

Project description:Chromatin modification and higher-order chromosome structure play key roles in gene regulation, but their functional interplay in controlling gene expression is elusive. We have discovered the machinery and mechanism underlying the dynamic enrichment of histone modification H4K20me1 on hermaphrodite X chromosomes during C. elegans dosage compensation and demonstrated H4K20me1's pivotal role in regulating higher-order chromosome structure and X-chromosome-wide gene expression. The structure and the activity of the dosage compensation complex (DCC) subunit DPY-21 define a Jumonji demethylase subfamily that converts H4K20me2 to H4K20me1 in worms and mammals. Selective inactivation of demethylase activity eliminates H4K20me1 enrichment in somatic cells, elevates X-linked gene expression, reduces X chromosome compaction, and disrupts X chromosome conformation by diminishing the formation of topologically associating domains (TADs). Unexpectedly, DPY-21 also associates with autosomes of germ cells in a DCC-independent manner to enrich H4K20me1 and trigger chromosome compaction. Our findings demonstrate the direct link between chromatin modification and higher-order chromosome structure in long-range regulation of gene expression.

Project description:Both intercellular signaling and epigenetic mechanisms regulate embryonic development, but it is unclear how they are integrated to establish and maintain lineage-specific gene expression programs. Here, we show that a key function of the developmentally essential Nodal-Smads2/3 (Smad2 and Smad3) signaling pathway is to recruit the histone demethylase Jmjd3 to target genes, thereby counteracting repression by Polycomb. Smads2/3 bound to Jmjd3 and recruited it to chromatin in a manner that was dependent on active Nodal signaling. Knockdown of Jmjd3 alone substantially reduced Nodal target gene expression, whereas in the absence of Polycomb, target loci were expressed independently of Nodal signaling. These data establish a role for Polycomb in imposing a dependency on Nodal signaling for the expression of target genes and reveal how developmental signaling integrates with epigenetic processes to control gene expression.

Project description:Epithelial-mesenchymal transition (EMT) has pivotal roles during embryonic development and carcinoma progression. Members of the Snai1 family of zinc finger transcription factors are central mediators of EMT and induce EMT in part by directly repressing epithelial markers such as E-cadherin, a gatekeeper of the epithelial phenotype and a suppressor of tumor invasion. However, the molecular mechanism underlying Snai1-mediated transcriptional repression remains incompletely understood. Here we show that Snai1 physically interacts with and recruits the histone demethylase LSD1 (KDM1A) to epithelial gene promoters. LSD1 removes dimethylation of lysine 4 on histone H3 (H3K4m2), a covalent histone modification associated with active chromatin. Importantly, LSD1 is essential for Snai1-mediated transcriptional repression and for maintenance of the silenced state of Snai1 target genes in invasive cancer cells. In the absence of LSD1, Snai1 fails to repress E-cadherin. In cancer cells in which E-cadherin is silenced, depletion of LSD1 results in partial de-repression of epithelial genes and elevated H3K4m2 levels at the E-cadherin promoter. These results underline the critical role of LSD1 in Snai1-dependent transcriptional repression of epithelial markers and suggest that the LSD1 complex could be a potential therapeutic target for prevention of EMT-associated tumor invasion.

Project description:The histone demethylase LSD1, a component of the CoREST (corepressor for element 1-silencing transcription factor) corepressor complex, plays an important role in the downregulation of gene expression during development. However, the activities of LSD1 in mediating short-time-scale gene expression changes have not been well understood. To reveal the mechanisms underlying these two distinct functions of LSD1, we performed genome-wide mapping and cellular localization studies of LSD1 and its dimethylated histone 3 lysine 4 (substrate H3K4me2) in mouse embryonic stem cells (ES cells). Our results showed an extensive overlap between the LSD1 and H3K4me2 genomic regions and a correlation between the genomic levels of LSD1/H3K4me2 and gene expression, including many highly expressed ES cell genes. LSD1 is recruited to the chromatin of cells in the G(1)/S/G(2) phases and is displaced from the chromatin of M-phase cells, suggesting that LSD1 or H3K4me2 alternatively occupies LSD1 genomic regions during cell cycle progression. LSD1 knockdown by RNA interference or its displacement from the chromatin by antineoplastic agents caused an increase in the levels of a subset of LSD1 target genes. Taken together, these results suggest that cell cycle-dependent association and dissociation of LSD1 with chromatin mediates short-time-scale gene expression changes during embryonic stem cell cycle progression.