Project description:In the current project with aim to unequivocally characterize a novel splicing-regulatory network that proves to be a central mediator of endothelial barrier function and vascular integrity. At the core of this network is the endothelial enriched lncRNA NTRAS (annotated as RP11-354k1.1) is shown to control alternative splicing decisions in HUVECs through interplaying with splicing factor hnRNPL. Specifically, in the project we show that NTRAS sequesters the splicing factor hnRNPL through a CA dinucleotide motif, to enhance TJP1 exon 20 usage, thereby TJP1α+ isoform. In turn disrupting TJP1α+ isoform expression impaired endothelial barrier function. Collectively, this splicing-regulatory network might prove fundamental in unlocking new interventions strategic to prevent or reverse vascular leakage.

Project description:Evidence of widespread transcription at active enhancers became apparent. However, our understanding about the functions of enhancer RNAs (eRNAs) and their mechanistic roles remains incomplete. Here, we study eRNA regulation and function using skeletal myoblast differentiation as a paradigm. We provide a panoramic view of enhancer transcription and uncover reprogramming in enhancer transcription occurring during myogenic differentiation. We demonstrate the critical role of MyoD in activating eRNAs production. Results from in depth dissection of two eRNAs transcribed from super enhancers (seRNA-1 and -2) suggest that seRNAs can promote myogenic differentiation in vitro and in vivo; the induction of the seRNAs is in coordination with the activation of the neighboring genes and seRNA loss largely impairs their expression. Mechanistically, we elucidate these seRNAs specifically bind to heterogeneous nuclear ribonucleoprotein L (hnRNPL) and modulate hnRNPL binding to the target promoter. A CAAA tract on the seRNA was identified to be essential in mediating the interaction between seRNA-1 and hnRNPL. Disruption of seRNA-hnRNPL interaction attenuates Pol II and H3K36me3 deposition at the target genes, in coincidence with the reduction of their expression. Furthermore, analyses of hnRNPL binding transcriptome-wide reveals its association with eRNAs is a general phenomenon in multiple cells. Collectively, we propose that eRNA-hnRNPL interaction contributes to target mRNA activation.

Project description:HNRNPL plays a critical role in regulating epidermal stem and progenitor cell function through regulating integrin gene expression at transcriptional level.

Project description:Evidence of widespread transcription at active enhancers became apparent. However, our understanding about the functions of enhancer RNAs (eRNAs) and their mechanistic roles remains incomplete. Here, we study eRNA regulation and function using skeletal myoblast differentiation as a paradigm. We provide a panoramic view of enhancer transcription and uncover reprogramming in enhancer transcription occurring during myogenic differentiation. We demonstrate the critical role of MyoD in activating eRNAs production. Results from in depth dissection of two eRNAs transcribed from super enhancers (seRNA-1 and -2) suggest that seRNAs can promote myogenic differentiation in vitro and in vivo; the induction of the seRNAs is in coordination with the activation of the neighboring genes and seRNA loss largely impairs their expression. Mechanistically, we elucidate these seRNAs specifically bind to heterogeneous nuclear ribonucleoprotein L (hnRNPL) and modulate hnRNPL binding to the target promoter. A CAAA tract on the seRNA was identified to be essential in mediating the interaction between seRNA-1 and hnRNPL. Disruption of seRNA-hnRNPL interaction attenuates Pol II and H3K36me3 deposition at the target genes, in coincidence with the reduction of their expression. Furthermore, analyses of hnRNPL binding transcriptome-wide reveals its association with eRNAs is a general phenomenon in multiple cells. Collectively, we propose that eRNA-hnRNPL interaction contributes to target mRNA activation.

Project description:Evidence of widespread transcription at active enhancers became apparent. However, our understanding about the functions of enhancer RNAs (eRNAs) and their mechanistic roles remains incomplete. Here, we study eRNA regulation and function using skeletal myoblast differentiation as a paradigm. We provide a panoramic view of enhancer transcription and uncover reprogramming in enhancer transcription occurring during myogenic differentiation. We demonstrate the critical role of MyoD in activating eRNAs production. Results from in depth dissection of two eRNAs transcribed from super enhancers (seRNA-1 and -2) suggest that seRNAs can promote myogenic differentiation in vitro and in vivo; the induction of the seRNAs is in coordination with the activation of the neighboring genes and seRNA loss largely impairs their expression. Mechanistically, we elucidate these seRNAs specifically bind to heterogeneous nuclear ribonucleoprotein L (hnRNPL) and modulate hnRNPL binding to the target promoter. A CAAA tract on the seRNA was identified to be essential in mediating the interaction between seRNA-1 and hnRNPL. Disruption of seRNA-hnRNPL interaction attenuates Pol II and H3K36me3 deposition at the target genes, in coincidence with the reduction of their expression. Furthermore, analyses of hnRNPL binding transcriptome-wide reveals its association with eRNAs is a general phenomenon in multiple cells. Collectively, we propose that eRNA-hnRNPL interaction contributes to target mRNA activation.

Project description:Evidence of widespread transcription at active enhancers became apparent. However, our understanding about the functions of enhancer RNAs (eRNAs) and their mechanistic roles remains incomplete. Here, we study eRNA regulation and function using skeletal myoblast differentiation as a paradigm. We provide a panoramic view of enhancer transcription and uncover reprogramming in enhancer transcription occurring during myogenic differentiation. We demonstrate the critical role of MyoD in activating eRNAs production. Results from in depth dissection of two eRNAs transcribed from super enhancers (seRNA-1 and -2) suggest that seRNAs can promote myogenic differentiation in vitro and in vivo; the induction of the seRNAs is in coordination with the activation of the neighboring genes and seRNA loss largely impairs their expression. Mechanistically, we elucidate these seRNAs specifically bind to heterogeneous nuclear ribonucleoprotein L (hnRNPL) and modulate hnRNPL binding to the target promoter. A CAAA tract on the seRNA was identified to be essential in mediating the interaction between seRNA-1 and hnRNPL. Disruption of seRNA-hnRNPL interaction attenuates Pol II and H3K36me3 deposition at the target genes, in coincidence with the reduction of their expression. Furthermore, analyses of hnRNPL binding transcriptome-wide reveals its association with eRNAs is a general phenomenon in multiple cells. Collectively, we propose that eRNA-hnRNPL interaction contributes to target mRNA activation.

Project description:RNA immunoprecipitation coupled with next generation sequencing (RIP-seq) was used to map the HNRNPL-RNA interactome in LNCaP cells.

Project description:SIRT1 is a nuclear enzyme that removes acetyl-groups from target proteins by using NAD+ as a co-substrate. SIRT1 regulates many vital biological processes such as metabolism, stress response, development, and aging. We have previously shown that SIRT1 is critically involved in mouse embryonic stem cell (mESC) maintenance and differentiation in part through modulation of the acetylation status of key transcription factors and their mediated amino acid metabolism and cell signaling. Recent reports have shown that a number of alternative splicing factors are deacetylation substrates of SIRT1. In this study, we aim to understand the total RNA transcriptome, including splicing landscapes, of WT and SIRT1 KO mESCs.

Project description:NTRAS hnRNPL RNA sequencing in HUVECs

Project description:Different from canonical ubiquitin-like proteins, Hub1 does not form covalent conjugates with substrates but binds proteins non-covalently. In Saccharomyces cerevisiae, Hub1 associates with spliceosomes and mediates alternative splicing of SRC1, without affecting pre-mRNA splicing generally. Human Hub1 is highly similar to its yeast homolog, but its cellular function remains largely unexplored. Here, we show that human Hub1 binds to the spliceosomal protein Snu66 as in yeast, however, unlike its S. cerevisiae homolog, human Hub1 is essential for viability. Prolonged in vivo depletion of human Hub1 leads to various cellular defects, including splicing speckle abnormalities, partial nuclear retention of mRNAs, mitotic catastrophe and consequently cell death by apoptosis. Early consequences of Hub1 depletion are severe splicing defects, however, only for specific splice sites leading to exon skipping and intron retention. Thus, the ubiquitin-like protein Hub1 is not a canonical spliceosomal factor needed generally for splicing, but rather a modulator of spliceosome performance and facilitator of alternative splicing. Human U2OS cells were transfected with siRNAs to specifically knockdown the ubiquitn-like protein Hub1. Cells treated with non-targeting oligos (GL2) served as negative control. Total RNAs of three biological replicates of each knockdown experiment were isolated and changes of splicing patterns were subsequently analyzed by Affymetrix GeneChip Human Exon 1.0 ST arrays