Project description:Histone modifications are critical for regulating chromatin structure and gene expression. Dysregulation of histone modifications likely contributes to disease states and cancer. Depletion of the chromatin-binding protein BRWD3, a known substrate-specificity factor of the Cul4-DDB1 E3 ubiquitin ligase complex, results in increased in H3K4me1 levels. The underlying mechanism linking BRWD3 and H3K4 methylation, however, has yet to be defined. Here, we show that depleting BRWD3 not only causes an increase in H3K4me1 levels, but also causes a decrease in H3K4me3 levels, indicating that BRWD3 influences H3K4 methylation more broadly. Using immunoprecipitation coupled to quantitative mass spectrometry, we identified an interaction between BRWD3 and the H3K4-specific demethylase 5 (KDM5/Lid), an enzyme that removes tri- and di- methyl marks from H3K4. Moreover, analysis of ChIP-seq data revealed that BRWD3 and KDM5 are significantly co-localized throughout the genome and that sites of H3K4me3 are highly enriched at BRWD3 binding sites. We show that BRWD3 promotes K48-linked polyubiquitination and degradation of KDM5 and that KDM5 degradation is dependent on both BRWD3 and Cul4. Critically, depleting KDM5 fully restores altered H3K4me3 levels and partially restores H3K4me1 levels upon BRWD3 depletion. Together, our results demonstrate that BRWD3 regulates KDM5 activity to balance H3K4 methylation levels.

Project description:Ubiquitination and epigenetic modification both play essential roles in regulating cell fates and development, but little is known how two pathways crosstalk. A known chromatin-binding protein BRWD3, Bromodomain repeats and WD40 repeats domain contain protein 3, has been shown involved both in ubiquitination and histone modification regulation. BRWD3 has roles in multiple chromatin-related processes, including transcription, DNA replication, and chromatin modification. However, how ubiquitination is involved and what’s BRWD3’s ubiquitination targets are barely known. Here, we study the single Drosophila homolog dBRWD3 to uncover its mechanism. To find dBRWD3’s ubiquitination targets, we performed both dBRWD3 IP-MS and BRWD3 dependent ubiquitination IP-MS. Expectedly, the whole BRWD3-Cul4-DDB1 E3 ubiquitination complex and multiple histones are significantly enriched in dBRWD3-IP. Interestingly, multiple histone modification writers and the DNA replication initiation factor origin recognition complex (ORC) are among the intersection of two MS. ORC’s function is highly dependent on chromatin signature. dBRWD3 could provide a perspective on how chromatin signature is regulated by ubiquitination to regulate ORC function. In support of this, about 35% of ORC2 binding sites overlap with dBRWD3 binding sites among the genome. The H3K27ac occupancy rate of dBRWD3 related ORC sites is about 50% higher than that of dBRWD3 irrelevant ORC sites. Depletion of dBRWD3 significantly reduces DNA proliferation in the S phase. Further study will focus on determining which histone modification writer is targeted for ubiquitination and how does it contribute to the chromatin signature and ORC function.

Project description:Histones are essential for chromatin packaging and histone supply must be tightly regulated as excess histones are toxic. To drive the rapid cell cycles of the early embryo, however, excess histones are maternally deposited. Therefore, soluble histones must be buffered by histone chaperones but the chaperone necessary to stabilize soluble H3-H4 pools in the Drosophila embryo has yet to be identified. Here, we show that CG8223, the Drosophila ortholog of NASP, is a H3-H4-specific chaperone in the early embryo. NASP specifically binds to H3-H4 in the early embryo. We demonstrate that, while NASP is non-essential in Drosophila, NASP is maternal effect lethal gene. Embryos laid by NASP mutant mothers have a reduce rate of hatching and show defects in early embryogenesis. Critically, soluble H3-H4 pools are degraded in embryos laid by NASP mutant mothers. Our work identifies NASP as the critical H3-H4 histone chaperone in the Drosophila embryo.

Project description:BRWD3 promotes KDM5 degradation to maintain H3K4 methylation levels

Project description:SIN3 the scaffold protein of a histone deacetylase complex interacts with a histone demethylase KDM5 (little imaginal discs - LID) in Drosophila. Reduction of SIN3 or dKDM5/LID both result in similar phenotypes during cell proliferation and wing development. To identify underlying transcriptional changes that may contribute to these phentypic defects we performed whole genome expression analysis in Drosophila cultured cells upon RNAi-mediated knockdown of Sin3A, lid or both. We identified a large number of genes regulated by SIN3, dKDM5/LID or both. While many common genes were regulated by SIN3 and dKDM5/LID an enrichment for genes involved in stress tolerance pathways was observed. Additional RNAseq analysis of expression changes upon knockdown of Sin3A, lid or both under paraquat mediated oxidative stress conditions identified significant changes in genes involved in cell cycle related processes.

Project description:SIN3 the scaffold protein of a histone deacetylase complex interacts with a histone demethylase KDM5 (little imaginal discs - LID) in Drosophila. Reduction of SIN3 or dKDM5/LID both result in similar phenotypes during cell proliferation and wing development. To identify underlying transcriptional changes that may contribute to these phentypic defects we performed whole genome expression analysis in Drosophila cultured cells upon RNAi-mediated knockdown of Sin3A, lid or both. We identified a large number of genes regulated by SIN3, dKDM5/LID or both. While many common genes were regulated by SIN3 and dKDM5/LID an enrichment for genes involved in stress tolerance pathways was observed. Additional RNAseq analysis of expression changes upon knockdown of Sin3A, lid or both under paraquat mediated oxidative stress conditions identified significant changes in genes involved in cell cycle related processes. Drosophila S2 cells were treated with dsRNA targetting Sin3A, lid and both or GFP as control under normal or oxidative stress conitions induced by treatment with paraquat. mRNA profiling of these samples were performed by deep sequencing using Illumina Hiseq2500.Three biological replicates were performed.

Project description:Alterations in the histone methylation profiles are observed in various types of cancer and targeting of this epigenetic process has therapeutic potential. Here we provide proof-of-principle that pharmacological targeting of KDM5 histone-demethylases is a new strategy for the personalized treatment of HER2-positive breast cancer. This analysis demonstrates that cells characterized by HER2-positivity are particularly sensitive to KDM5 inhibition. The results are confirmed in an appropriate in vivo model with a close structural analogue (KDM5-inh1A). In selected HER2-positive breast cancer cells, we demonstrate synergistic interactions between KDM5-inh1 and HER2-targeting agents (trastuzumab and lapatinib). In addition, HER2-positive cell lines showing innate/acquired resistance to trastuzumab show sensitivity to KDM5-inh1. The levels of KDM5A/B/C proteins, which are selectively targeted by the agent, have no significant association with KDM5-inh1 responsiveness across our panel of breast cancer cell lines, suggesting the existence of other determinants of sensitivity. Using RNA-sequencing data of the breast cancer cell lines, we generate a gene-expression model, consisting of fifteen genes, which is a robust predictor of KDM5-inh1 sensitivity. In a test set of breast cancers, this model correctly predicts sensitivity to the compound in a large fraction of HER2+ tumors. In conclusion, KDM5 inhibition has potential in the treatment of HER2+ breast cancer and our gene-expression model can be developed into a diagnostic tool to select patients who may benefit from treatments based on KDM5-inhibitors.

Project description:In this experiment we demonstrate the use of an inhibitor of the KDM5 family of histone demethylases, KDM5-C70, on H3K4me3 marks in the multiple myeloma cell line MM1S. KDM5-C70 increases H3K4me3 in a global fashion across the genome. Examination of H3K4me3 mark across MM1S cells treated with either KDM5-C70 or vehicle control

Project description:To determine which genes affected by loss of KDM5 in adults were direct targets, we carried out KDM5 ChIP-seq analyses. To valide this data, we utilized a previously generated fly strain in which the sole source of KDM5 is from a transgene expressing an HA tagged form of KDM5 expressed under the control of its endogenous promoter. Comparing genome-wide gene expression and KDM5 binding analyses in Drosophila adults, we demonstrate the primary function of KDM5 in adults is to activate gene expression KDM5. To investigate the link between KDM5 and H3K4me3, we carried out anti-H3K4me3 ChIP-seq from wildtype adults . Genome-wide, KDM5 and H3K4me3 peaks showed a similar distribution, with both peaking at the transcription start site (TSS) showed a striking overlap with the presence of H3K4me3. Examination of KDM5 binding and histone H3K4me3 modifications in drosophila adults

Project description:LID is a histone demethylase acting on H3K4me3, a mark related to transcription and found near the transcription start sites (TSS) of the genes. We analyzed where LID is localized and the effects of LID downregulation in the distribution of H3K4me3.