Project description:BackgroundPeptidylprolyl cis-trans isomerase B (PPIB) plays an important role in the process of inflammation through binding RNA, but the molecular pathogenesis is not yet clearly understood. The objective of this study was to investigate and verify the PPIB-regulated gene expressions and alternative splicing in Hela cells.MethodsWe examined the PPIB-regulated transcriptomes in HeLa cells using RNA-seq data. Differentially expressed genes, alternative splicing analysis were carried out. Functional enrichment analysis was used to define the enrichment of each term.ResultsWe found that PPIB knockdown successfully downregulated PPIB in Hela cells, which promoted cell proliferation (P < 0.001), but no significant effect on cell apoptosis. Ten alternative splicing genes regulated by PPIB were detected in Hela cells. The ten top Gene Ontology biological process analysis and functional pathways of the alternative splicing genes were screened and identified. The pathways where differentially expressed genes are most enriched were toll-like receptor 4 signaling pathways and other signaling pathways relating to inflammation and immune response. In addition, PPIB affects the alternative splicing of multiple genes, and the Gene Ontology-biological process analysis showed that genes significantly related to alternative splicing changes were mainly enriched in the cell cycle (P < 0.05).ConclusionPPIB regulates the alternative splicing of cell cycle-related genes to affect cell proliferation and regulate the occurrence and development of chronic inflammatory diseases such as Nasal polyps.

Project description:Alternative splicing is a vast source of biological regulation and diversity that is misregulated in cancer and other diseases. To investigate global control of alternative splicing in human cells, we analyzed splicing of mRNAs encoding Bcl2 family apoptosis factors in a genome-wide siRNA screen. The screen identified many regulators of Bcl-x and Mcl1 splicing, notably an extensive network of cell-cycle factors linked to aurora kinase A. Drugs or siRNAs that induce mitotic arrest promote proapoptotic splicing of Bcl-x, Mcl1, and caspase-9 and alter splicing of other apoptotic transcripts. This response precedes mitotic arrest, indicating coordinated upregulation of prodeath splice variants that promotes apoptosis in arrested cells. These shifts correspond to posttranslational turnover of splicing regulator ASF/SF2, which directly binds and regulates these target mRNAs and globally regulates apoptosis. Broadly, our results reveal an alternative splicing network linking cell-cycle control to apoptosis.

Project description:BackgroundAberrant alternative splicing (AS) events, triggered by the alterations in serine/arginine splicing factor 1 (SRSF1), a member of the SR protein family, have been implicated in various pathological processes. However, the function and mechanism of SRSF1 in cardiovascular diseases remain unclear.ResultsIn this study, we found that the expression of SRSF1 was significantly down-regulated in the hearts of mice with acute myocardial infarction (AMI) and H9C2 cells exposed to H2O2. Moreover, in vivo experiments utilizing adeno-associated virus serotype 9-mediated SRSF1 overexpression improved cardiac function and reduced infarct size in AMI mice. Mechanistically, we employed RNA-seq assay to identify AS aberrations associated with altered SRSF1 level in cardiomyocytes, and found that SRSF1 regulates the splice switching of Bcl2L12. Further study showed that silencing SRSF1 inhibits the inclusion of exon7 in Bcl2L12. Importantly, the truncated Bcl2L12 lacked the necessary structural elements and failed to interact with p53, thus compromising its ability to suppress apoptosis.ConclusionsOur study unraveled the role of SRSF1 as a splicing factor involved in the regulation of Bcl2L12 splice switching, thereby exerting an anti-apoptotic effect through the p53 pathway, which provides new insights into potential approaches targeting cardiomyocyte apoptosis in cardiovascular diseases.

Project description:Changes in the cellular environment result in chromatin structure alteration, which in turn regulates gene expression. To learn about the effect of the cellular environment on the transcriptome, we studied the H3K9 demethylase KDM3A. Using RNA-seq, we found that KDM3A regulates the transcription and alternative splicing of genes associated with cell cycle and DNA damage. We showed that KDM3A undergoes phosphorylation by PKA at serine 265 following DNA damage, and that the phosphorylation is important for proper cell-cycle regulation. We demonstrated that SAT1 alternative splicing, regulated by KDM3A, plays a role in cell-cycle regulation. Furthermore we found that KDM3A's demethylase activity is not needed for SAT1 alternative splicing regulation. In addition, we identified KDM3A's protein partner ARID1A, the SWI/SNF subunit, and SRSF3 as regulators of SAT1 alternative splicing and showed that KDM3A is essential for SRSF3 binding to SAT1 pre-mRNA. These results suggest that KDM3A serves as a sensor of the environment and an adaptor for splicing factor binding. Our work reveals chromatin sensing of the environment in the regulation of alternative splicing.

Project description:In cardiomyocytes, calcium is known to control gene expression at the level of transcription, whereas its role in regulating alternative splicing has not been explored. Here we report that, in mouse primary or embryonic stem cell-derived cardiomyocytes, increased calcium levels induce robust and reversible skipping of several alternative exons from endogenously expressed genes. Interestingly, we demonstrate a calcium-mediated splicing regulatory mechanism that depends on changes of histone modifications. Specifically, the regulation occurs through changes in calcium-responsive kinase activities that lead to alterations in histone modifications and subsequent changes in the transcriptional elongation rate and exon skipping. We demonstrate that increased intracellular calcium levels lead to histone hyperacetylation along the body of the genes containing calcium-responsive alternative exons by disrupting the histone deacetylase-to-histone acetyltransferase balance in the nucleus. Consequently, the RNA polymerase II elongation rate increases significantly on those genes, resulting in skipping of the alternative exons. These studies reveal a mechanism by which calcium-level changes in cardiomyocytes impact on the output of gene expression through altering alternative pre-mRNA splicing patterns.

Project description:RNA binding proteins and signaling components control the production of pro-death and pro-survival splice variants of Bcl-x. DNA damage promoted by oxaliplatin increases the level of pro-apoptotic Bcl-xS in an ATM/CHK2-dependent manner, but how this shift is enforced is not known. Here, we show that in normally growing cells, when the 5' splice site of Bcl-xS is largely repressed, SRSF10 partially relieves repression and interacts with repressor hnRNP K and stimulatory hnRNP F/H proteins. Oxaliplatin abrogates the interaction of SRSF10 with hnRNP F/H and decreases the association of SRSF10 and hnRNP K with the Bcl-x pre-mRNA. Dephosphorylation of SRSF10 is linked with these changes. A broader analysis reveals that DNA damage co-opts SRSF10 to control splicing decisions in transcripts encoding components involved in DNA repair, cell-cycle control, and apoptosis. DNA damage therefore alters the interactions between splicing regulators to elicit a splicing response that determines cell fate.

Project description:Akt/PKB is a key signaling molecule in higher eukaryotes and a crucial protein kinase in human health and disease. Phosphorylation, acetylation, and ubiquitylation have been reported as important regulatory post-translational modifications of this kinase. We describe here that Akt is modified by SUMO conjugation, and show that lysine residues 276 and 301 are the major SUMO attachment sites within this protein. We found that phosphorylation and SUMOylation of Akt appear as independent events. However, decreasing Akt SUMOylation levels severely affects the role of this kinase as a regulator of fibronectin and Bcl-x alternative splicing. Moreover, we observed that the Akt mutant (Akt E17K) found in several human tumors displays increased levels of SUMOylation and also an enhanced capacity to regulate fibronectin splicing patterns. This splicing regulatory activity is completely abolished by decreasing Akt E17K SUMO conjugation levels. Additionally, we found that SUMOylation controls Akt regulatory function at G?/S transition during cell cycle progression. These findings reveal SUMO conjugation as a novel level of regulation for Akt activity, opening new areas of exploration related to the molecular mechanisms involved in the diverse cellular functions of this kinase.

Project description:Progression through the mitotic cell cycle requires periodic regulation of gene function at the levels of transcription, translation, protein-protein interactions, post-translational modification and degradation. However, the role of alternative splicing (AS) in the temporal control of cell cycle is not well understood. By sequencing the human transcriptome through two continuous cell cycles, we identify ~1300 genes with cell cycle-dependent AS changes. These genes are significantly enriched in functions linked to cell cycle control, yet they do not significantly overlap genes subject to periodic changes in steady-state transcript levels. Many of the periodically spliced genes are controlled by the SR protein kinase CLK1, whose level undergoes cell cycle-dependent fluctuations via an auto-inhibitory circuit. Disruption of CLK1 causes pleiotropic cell cycle defects and loss of proliferation, whereas CLK1 over-expression is associated with various cancers. These results thus reveal a large program of CLK1-regulated periodic AS intimately associated with cell cycle control.

Project description:Genome-wide analysis of transcriptome data in Chlamydomonas reinhardtii shows periodic patterns in gene expression levels when cultures are grown under alternating light and dark cycles so that G1 of the cell cycle occurs in the light phase and S/M/G0 occurs during the dark phase. However, alternative splicing, a process that enables a greater protein diversity from a limited set of genes, remains largely unexplored by previous transcriptome based studies in C. reinhardtii In this study, we used existing longitudinal RNA-seq data obtained during the light-dark cycle to investigate the changes in the alternative splicing pattern and found that 3277 genes (19.75% of 17,746 genes) undergo alternative splicing. These splicing events include Alternative 5' (Alt 5'), Alternative 3' (Alt 3') and Exon skipping (ES) events that are referred as alternative site selection (ASS) events and Intron retention (IR) events. By clustering analysis, we identified a subset of events (26 ASS events and 10 IR events) that show periodic changes in the splicing pattern during the cell cycle. About two-thirds of these 36 genes either introduce a pre-termination codon (PTC) or introduce insertions or deletions into functional domains of the proteins, which implicate splicing in altering gene function. These findings suggest that alternative splicing is also regulated during the Chlamydomonas cell cycle, although not as extensively as changes in gene expression. The longitudinal changes in the alternative splicing pattern during the cell cycle captured by this study provides an important resource to investigate alternative splicing in genes of interest during the cell cycle in Chlamydomonas reinhardtii and other eukaryotes.

Project description:Background: Peptidylprolyl cis-trans isomerase B (PPIB) plays an important function in the process of inflammation through binding RNA, but the clear molecular pathogenesis is not completely understood. The objective of this study was to investigate the PPIB-regulated gene expression and alternative splicing.