Project description:BS69 (aka ZMYND11) was initially discovered as a direct target of adenoviral E1A oncoprotein1. Subsequent studies implicated BS69 as a tumor suppressor and a transcriptional regulator2. But exactly how BS69 regulates gene expression has remained elusive. BS69 contains tandemly arranged PHD, BROMO and PWWP domains, which are known to function as chromatin recognition modalities. Here we show that BS69 selectively recognizes histone variant H3.3 lysine 36 trimethylation (H3.3K36me3) via these chromatin recognition modules. Using a proteomics approach, we further identified association of BS69 with a host of RNA splicing regulators including EFTUD2 and other U5 snRNP components of the spliceosome. Remarkably, RNA-seq analysis shows that BS69 mainly regulates intron retention (IR), which is one of the least well-understood RNA alternative splicing events in mammalian cells. Specifically, loss of BS69 results in a decrease in IR, while in contrast, knockdown of EFTUD2 leads to an increase in IR, consistent with its role as a core member of the splicesome machinery. Importantly, wildtype BS69, but not a BS69 mutant defective in its interaction with EFTUD2, rescues the IR events. We also show that knockdown of SETD2, the main enzyme that mediates H3K36 trimethylation3, similarly results in a decreased retention of the same introns regulated by BS69. Significantly, a BS69 mutant unable to bind H3.3K36me3 in vitro fails to rescue the reduced IR phenotype associated with the loss of BS69. Taken together, our findings identify an antagonistic relationship between BS69 and the core splicing machinery and demonstrate that BS69-mediated RNA splicing regulation is dependent both on its ability to bind chromatin decorated by H3K36me3 and its ability to physically interact with the core spliceosome machinery. Our study reveals a novel and unexpected role of BS69 in connecting histone H3.3K36 trimethylation to regulated RNA splicing, providing significant new insights into chromatin regulation of RNA splicing. HeLa cells were infected with lentiviruses carrying control and BS69 shRNA and deep sequencing data were generated, in triplicate, using Illumina HiSeq 2000

Project description:BS69 (aka ZMYND11) was initially discovered as a direct target of adenoviral E1A oncoprotein1. Subsequent studies implicated BS69 as a tumor suppressor and a transcriptional regulator2. But exactly how BS69 regulates gene expression has remained elusive. BS69 contains tandemly arranged PHD, BROMO and PWWP domains, which are known to function as chromatin recognition modalities. Here we show that BS69 selectively recognizes histone variant H3.3 lysine 36 trimethylation (H3.3K36me3) via these chromatin recognition modules. Using a proteomics approach, we further identified association of BS69 with a host of RNA splicing regulators including EFTUD2 and other U5 snRNP components of the spliceosome. Remarkably, RNA-seq analysis shows that BS69 mainly regulates intron retention (IR), which is one of the least well-understood RNA alternative splicing events in mammalian cells. Specifically, loss of BS69 results in a decrease in IR, while in contrast, knockdown of EFTUD2 leads to an increase in IR, consistent with its role as a core member of the splicesome machinery. Importantly, wildtype BS69, but not a BS69 mutant defective in its interaction with EFTUD2, rescues the IR events. We also show that knockdown of SETD2, the main enzyme that mediates H3K36 trimethylation3, similarly results in a decreased retention of the same introns regulated by BS69. Significantly, a BS69 mutant unable to bind H3.3K36me3 in vitro fails to rescue the reduced IR phenotype associated with the loss of BS69. Taken together, our findings identify an antagonistic relationship between BS69 and the core splicing machinery and demonstrate that BS69-mediated RNA splicing regulation is dependent both on its ability to bind chromatin decorated by H3K36me3 and its ability to physically interact with the core spliceosome machinery. Our study reveals a novel and unexpected role of BS69 in connecting histone H3.3K36 trimethylation to regulated RNA splicing, providing significant new insights into chromatin regulation of RNA splicing. HeLaS cells stably expressing BS69 were used for HA-tagged BS69 ChIP-seq. HeLa cells were used for BS69 ChIP-seq. HeLa cells were used for H3K36me3 ChIP-seq.

Project description:BS69 (aka ZMYND11) was initially discovered as a direct target of adenoviral E1A oncoprotein1. Subsequent studies implicated BS69 as a tumor suppressor and a transcriptional regulator2. But exactly how BS69 regulates gene expression has remained elusive. BS69 contains tandemly arranged PHD, BROMO and PWWP domains, which are known to function as chromatin recognition modalities. Here we show that BS69 selectively recognizes histone variant H3.3 lysine 36 trimethylation (H3.3K36me3) via these chromatin recognition modules. Using a proteomics approach, we further identified association of BS69 with a host of RNA splicing regulators including EFTUD2 and other U5 snRNP components of the spliceosome. Remarkably, RNA-seq analysis shows that BS69 mainly regulates intron retention (IR), which is one of the least well-understood RNA alternative splicing events in mammalian cells. Specifically, loss of BS69 results in a decrease in IR, while in contrast, knockdown of EFTUD2 leads to an increase in IR, consistent with its role as a core member of the splicesome machinery. Importantly, wildtype BS69, but not a BS69 mutant defective in its interaction with EFTUD2, rescues the IR events. We also show that knockdown of SETD2, the main enzyme that mediates H3K36 trimethylation3, similarly results in a decreased retention of the same introns regulated by BS69. Significantly, a BS69 mutant unable to bind H3.3K36me3 in vitro fails to rescue the reduced IR phenotype associated with the loss of BS69. Taken together, our findings identify an antagonistic relationship between BS69 and the core splicing machinery and demonstrate that BS69-mediated RNA splicing regulation is dependent both on its ability to bind chromatin decorated by H3K36me3 and its ability to physically interact with the core spliceosome machinery. Our study reveals a novel and unexpected role of BS69 in connecting histone H3.3K36 trimethylation to regulated RNA splicing, providing significant new insights into chromatin regulation of RNA splicing.

Project description:We generated a human EFTUD2 knockdown cell line using a CRISPR cas9 nickase strategy to investigate the effects of decreased expression of core spliceosome components on cell characteristics and global transcriptome expression/splicing patterns

Project description:The goal of this study was to compare the transcriptional profile (RNA-seq) of Dengue virus 2 and mock infected cells at 24 and 36 hours post infection. Dengue virus NS5 protein plays multiple functions in the cytoplasm of infected cells, enabling viral RNA replication and counteracting host antiviral responses. Here, we demonstrate a novel function of NS5 in the nucleus where it interferes with cellular splicing. Using global proteomic analysis of infected cells together with functional studies, we found that NS5 binds spliceosome complexes and modulates endogenous splicing. In particular, we show that NS5 alone, or in the context of viral infection, interacts with core components of the U5 snRNP particle, CD2BP2 and DDX23, alters the inclusion/exclusion ratio of alternative splicing events, and changes mRNA isoform abundance of known antiviral factors. Interestingly, a genome wide transcriptome analysis, using recently developed bioinformatics tools, revealed an increase of intron retention upon dengue virus infection, and viral replication was improved by silencing specific U5 components. Different mechanistic studies indicate that binding of NS5 to the spliceosome reduces the efficiency of pre-mRNA processing, independently of NS5 enzymatic activities. We propose that NS5 binding to U5 snRNP proteins hijacks the splicing machinery resulting in a less restrictive environment for viral replication. A549 cells where infected with Dengue virus 2 or mock and after 24 and 36 hours post infection mRNA was purified. Then the transcriptional profile of these cells was analyzed using RNA-seq.

Project description:Intron retention (IR) is the most common alternative splicing (AS) event in Arabidopsis. Increasing studies have demonstrated a major role of IR in gene expression regulation. The impacts of IR on plant growth and development, and response to environments remains under explored. Here, we found that IR functions directly in gene expression regulation on a genome-wide scale through detainment of the intron-retained transcripts (IRTs) in the nucleus. Through this mechanism, nuclear-retained IRTs can be kept away from translation. COP1-dependent light modulation of IRTs of light signaling genes, such as PIF4, RVE1, and ABA3, contribute to seedling morphological development in responding to changing light conditions. Further, light-induced IR changes are under the control of the spliceosome, and in part through COP1-dependent ubiquitination and degradation of DCS1, a plant-specific spliceosomal component. Our data suggests that light regulates the activity of the spliceosome and the consequent IRTs nucleus detainment to modulate photomorphogenesis through COP1.

Project description:c-MYC (MYC) overexpression or hyperactivation is one of the most common drivers of human cancer. Despite intensive study, the MYC oncogene remains recalcitrant to therapeutic inhibition. Like other classic oncogenes, hyperactivation of MYC leads to collateral stresses onto cancer cells, suggesting that tumors harbor unique vulnerabilities arising from oncogenic activation of MYC. Herein, we discover the spliceosome as a new target of oncogenic stress in MYC-driven cancers. We identify BUD31 as a MYC-synthetic lethal gene, and demonstrate that BUD31 is a splicing factor required for the assembly and catalytic activity of the spliceosome. Core spliceosomal factors (SF3B1, U2AF1, and others) associate with BUD31 and are also required to tolerate oncogenic MYC. Notably, MYC hyperactivation induces an increase in total pre-mRNA synthesis, suggesting an increased burden on the core spliceosome to process pre-mRNA. In contrast to normal cells, partial inhibition of the spliceosome in MYC-hyperactivated cells leads to global intron retention, widespread defects in pre-mRNA maturation, and deregulation of many essential cell processes. Importantly, genetic or pharmacologic inhibition of the spliceosome in vivo impairs survival, tumorigenicity, and metastatic proclivity of MYC-dependent breast cancers. Collectively, these data suggest that oncogenic MYC confers a collateral stress on splicing and that components of the spliceosome may be therapeutic entry points for aggressive MYC-driven cancers. Examination of intron rentention in MYC-ER HMECs, in 4 conditions

Project description:RNA splicing, the process of intron removal from pre-mRNA, is essential for the regulation of gene expression. It is controlled by the spliceosome, a megadalton RNA-protein complex that assembles de novo on each pre-mRNA intron via an ordered assembly of intermediate complexes. Spliceosome activation is a major control step requiring dramatic protein and RNA rearrangements leading to a catalytically active complex. Splicing factor 3B subunit 1 (SF3B1) protein, a subunit of the U2 snRNP, is phosphorylated during spliceosome activation, but the responsible kinase has not been identified. Here we show that cyclin-dependent kinase 11 (CDK11) associates with SF3B1 and phosphorylates threonine residues at its N-terminus during spliceosome activation. The phosphorylation is important for association of SF3B1 with U5 and U6 snRNAs in spliceosome activated Bact complex and it can be blocked by OTS964, a potent and selective inhibitor of CDK11. CDK11 inhibition prevents spliceosomal transition from the precatalytic complex B to the activated complex Bact and leads to widespread intron retention and accumulation of non-functional spliceosomes on pre-mRNAs and chromatin. We characterize OTS964 as a quality chemical biology probe for CDK11 and demonstrate a central role of CDK11 in spliceosome assembly and splicing regulation.

Project description:Pre-mRNA splicing relies on the still poorly understood dynamic interplay between more than 150 protein components of the Spliceosome, and the steps at which splicing can be regulated remain largely unknown. Here we systematically analyze the effect of knocking down the components of the splicing machinery on alternative splicing events relevant for cell proliferation and apoptosis and use this information to reconstruct a network of functional interactions. The network accurately captures well-established physical and functional associations and identifies new, revealing remarkable regulatory potential of core spliceosomal components, related to the order and duration of their recruitment during Spliceosome assembly. In contrast with standard models of regulation at early events of splice site recognition, factors involved in catalytic activation of the Spliceosome display regulatory properties. The network also sheds light on the antagonism between hnRNP C and U2AF and on targets of anti-tumor drugs, and can be widely used to identify mechanisms of splicing regulation. RNA from 3 biological replicates of 72 hours knockdowns of human IK or SMU1 and a control set were used. Changes between the control and knockdowns were measured based on using a splice-junction array (Affymetrix HJAY).

Project description:Pre-mRNA splicing is a highly regulated process catalyzing intron excision by spliceosome. Spliceosome activation is a major control step requiring dramatic protein and RNA rearrangements leading to a catalytically active complex. Prior research has linked hyperphosphorylation of SF3B1, a subunit of U2 snRNP, with spliceosome activation and catalytically active spliceosome, rendering a relevant kinase a key player for pre-mRNA splicing. Here we use OTS964, the first potent inhibitor of cyclin-dependent kinase 11 (CDK11), to show rapid and selective dephosphorylation of SF3B1 on threonines required for spliceosome activation. CDK11 associates with SF3B1 and its inhibition causes massive intron retention, block in precatalytic spliceosome complex B to activated spliceosome complex Bact transition and accumulation of non-functional spliceosomes on pre-mRNA and chromatin. These studies reveal crucial regulatory role of CDK11 in human pre-mRNA splicing and define the compound OTS964 as a quality chemical biology probe for CDK11.