Project description:Alternative splicing plays critical roles in differentiation, development, and cancer (Pettigrew et al., 2008; Chen and Manley, 2009). The recent identification of specific spliceosome inhibitors has generated interest in the therapeutic potential of targeting this cellular process (van Alphen et al., 2009). Using an integrated genomic approach, we have identified PRPF6, an RNA binding component of the pre-mRNA spliceosome, as an essential driver of oncogenesis in colon cancer. Importantly, PRPF6 is both amplified and overexpressed in colon cancer, and only colon cancer cells with high PRPF6 levels are sensitive to its loss. Our data clearly point to an important role for PRPF6 in colon cancer growth and suggest that a better understanding of its role in alternative splicing in colon cancer is warranted. To determine the specific alternative splice forms that PRPF6 regulates in colon cancer, we plan three experiments: 1. The first involves knocking down expression of PRPF6 in two different cancer cell lines with 3 different siRNAs, and then completing RNA-seq to determine the gene expression changes that occur relative to a non-targeting control siRNA. Because of the role for PRPF6 in pre-mRNA splicing, we especially want to quantify the changes in splice-specific forms of all genes genome-wide to identify genes whose splicing is altered upon PRPF6 knockdown. 2. The second involves immunoprecipitating PRPF6 from two different cancer cell lines and isolating any RNA that is bound to PRPF6, since PRPF6 is an RNA-binding protein. We then want to carry out RNA-seq to identify which RNA molecules co-immunoprecipitated with PRPF6. This will help us determine possible functions for PRPF6 in regulating colon cancer growth. 3. The third involves overexpressing PRPF6 in cell lines and then carrying out RNA-seq to identify any changes in splice-specific gene expression. This will allow us to determine whether increased PRPF6 expression is sufficient to drive alternative splicing changes.

Project description:Description Alternative splicing plays critical roles in differentiation, development, and cancer. Using an integrated genomic approach, we have identified PRPF6, an RNA binding component of the pre-mRNA spliceosome, as an essential driver of oncogenesis in colon cancer. Importantly, PRPF6 is both amplified and overexpressed in colon cancer, and only colon cancer cells with high PRPF6 levels are sensitive to its loss. Our data clearly point to an important role for PRPF6 in colon cancer growth and suggest that a better understanding of its role in alternative splicing in colon cancer is warranted. To determine the specific alternative splice forms that PRPF6 regulates in colon cancer, we conducted the following experiment: Using two colon cancer cell lines (KM-12 and SW620) that have high PRPF6 levels, we inhibited PRPF6 expression using 2 independent siRNAs. We also tested the effect of U2 snRNP inhibition using both a siRNA targeting SF3B1 as well as spliceostatin A (a small molecule inhibitor of SF3B1). We then conducted RNA-seq to determine the gene expression and exonic changes that occur relative to either the non-targeting control siRNA (for siSF3B1 and siPRPF6) or the vehicle control (for spliceostatin A).

Project description:The investigation of spliceosomal processes is currently a topic of intense research in molecular biology. In the molecular mechanism of alternative splicing, a multi-protein–RNA complex – the spliceosome – plays a crucial role. To understand the biological processes of alternative splicing, it is essential to comprehend the biogenesis of the spliceosome. In this paper, we propose the first abstract model of the regulatory assembly pathway of the human spliceosomal subunit U1. Using Petri nets, we describe its highly ordered assembly that takes place in a stepwise manner.

Project description:PRPF6, an RNA binding component of the pre-mRNA spliceosome, is an essential driver of oncogenesis in colon cancer. PRPF6 is both amplified and overexpressed in colon cancer and cells with high PRPF6 levels are sensitive to its loss. Here we investigate alternative splicing changes in colon cancer cell lines following PRPF6 silencing by three different siRNA sequences. Two colon cancer cell lines (SW620 and KM-12), silencing of PRPF6 and control, 3 biological replicate samples for each group.

Project description:PRPF6, an RNA binding component of the pre-mRNA spliceosome, is an essential driver of oncogenesis in colon cancer. PRPF6 is both amplified and overexpressed in colon cancer and cells with high PRPF6 levels are sensitive to its loss. Here we investigate alternative splicing changes in colon cancer cell lines following PRPF6 silencing by three different siRNA sequences.

Project description:Alternative splicing drives transcriptome and proteome diversification. While splicing regulatory proteins govern this process, their global mechanisms remain enigmatic. We generated high resolution transcriptome-wide protein-RNA interaction maps to determine how the splicing repressor hnRNPA1 influences the global association of spliceosome assembly factor U2AF2 and SRSF1 with pre-mRNA. We observed changes in the distribution of U2AF2 crosslinking sites relative to the 3’ splice sites of cassette exons but not constitutive exons upon hnRNPA1 overexpression. By contrast, SRSF1 crosslinking patterns relative to splice sites are independent of hnRNPA1 expression levels. We also observed an hnRNPA1-dependent increase in U2AF2 but not SRSF1 crosslinking to exon proximal antisense Alu elements. Thus Alu elements can serve as splicing factor-responsive sinks for U2AF2. These results not only demonstrate a novel mechanism for alternative splicing regulation but also implicate retrotransposon-derived sequences in the evolution of species-specific alternative splicing.

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:Changes in alternative splicing are associated with several pathological conditions, including cancer. Microarrays strategies, which allow for the characterization of thousands of alternative splice forms in a single test, can be applied to identify differential alternative splicing events. In this study, a novel splice array platform was developed, including the design of a high-density oligonucleotide array, a labeling procedure, and an algorithm to identify splice events. The array consists of exon probes and thermodynamically balanced junction probes. Suboptimal probes are tagged and considered in the final analysis. An unbiased labeling protocol was developed using random primers. The algorithm used to distinguish changes in expression from changes in splicing was calibrated using internal non-spliced control sequences. The performance of this splice array was first validated with artificial constructs for CDC6, VEGF, and PCBP4 isoforms. The platform was then applied to the analysis of differential splice forms for 8000 genes in lung cancer samples compared to matched normal lung tissue. The expression of lung cancer-associated splice isoforms was validated by RT-PCR. Overexpression of splice isoforms was identified for genes encoding CEACAM1, FHL-1, MLPH, and SUSD2. None of these splicing isoforms had been previously associated with lung cancer. In conclusion, this highly accurate methodology enables the detection of alternative splicing events in complex biological samples, providing a powerful tool to identify novel diagnostic and prognostic biomarkers for cancer and other pathologies. 20 normal/tumor paired specimens. Tumor samples are from non-small cell lung cancer (NSCLC) whereas normals are from adjacent normal lung tissue.

Project description:The spliceosome undergoes extensive rearrangements as it assembles in multiple steps onto the precursor messenger RNA. In the earliest assembly step, U1snRNA identifies the 5' splice site through base-pairing interactions. However, U1snRNA leaves the spliceosome relatively early in the assembly process. The 5' splice site identity is subsequently maintained through interactions with U6snRNA, protein factor PRP8, and other components of the spliceosome during the complex assembly and rearrangements that build the catalytic site. Using a forward genetic screen in C. elegans, we have identified splicing suppressors of a locomotion defect caused by a 5'ss mutation. Here we report three new extragenic suppressor alleles from this screen, two in PRP8 and one in SNRNP200/Brr2. mRNASeq studies of these suppressor strains indicates that there are specific native targets with alternative 5' and alternative 3' splicing events affected by these suppressors, especially for the suppressor PRP8 D 1549N (position D1556 in humans). The strong suppressor at the unstructured N-terminus of SNRP200, N18K, indicates a potential regulatory role for this region. By examining distinct changes in the splicing of native genes, and by mapping these conserved suppressor residues onto cryoEM structural models of assembling human spliceosomes, we conclude that there are multiple interactions in the spliceosome that are required to ensure that the initial 5'ss identified by U1snRNA early in spliceosome assembly is the one that gets loaded into the catalytic core.The spliceosome undergoes extensive rearrangements as it assembles in multiple steps onto the precursor messenger RNA. In the earliest assembly step, U1snRNA identifies the 5' splice site through base-pairing interactions. However, U1snRNA leaves the spliceosome relatively early in the assembly process. The 5' splice site identity is subsequently maintained through interactions with U6snRNA, protein factor PRP8, and other components of the spliceosome during the complex assembly and rearrangements that build the catalytic site. Using a forward genetic screen in C. elegans, we have identified splicing suppressors of a locomotion defect caused by a 5'ss mutation. Here we report three new extragenic suppressor alleles from this screen, two in PRP8 and one in SNRNP200/Brr2. mRNASeq studies of these suppressor strains indicates that there are specific native targets with alternative 5' and alternative 3' splicing events affected by these suppressors, especially for the suppressor PRP8 D 1549N (position D1556 in humans). The strong suppressor at the unstructured N-terminus of SNRP200, N18K, indicates a potential regulatory role for this region. By examining distinct changes in the splicing of native genes, and by mapping these conserved suppressor residues onto cryoEM structural models of assembling human spliceosomes, we conclude that there are multiple interactions in the spliceosome that are required to ensure that the initial 5'ss identified by U1snRNA early in spliceosome assembly is the one that gets loaded into the catalytic core.

Project description:The RNA-binding protein RBM20 has been implicated in dilated cardiomyopathy (DCM), a major cause of chronic heart failure. To determine how RBM20 regulates alternative splicing, we combined transcriptome-wide CLIP-seq, RNA-seq, and quantitative proteomics in cell culture, rat, and human hearts. Our analyses revealed a distinct RBM20 RNA-recognition element in predominantly intronic binding sites and linked repression of exon splicing with RBM20-binding near 3prime- and 5prime-splice sites. Our proteomic data show RBM20 interaction with U1- and U2-snRNPs and suggests splicing repression through spliceosome stalling at complex A. Among direct RBM20 targets are several genes involved in DCM as well as new genes not previously associated with the disease process. In human failing hearts, we demonstrate that reduced expression levels of RBM20 affect alternative splicing of several direct targets, indicating that differences in RBM20 gene expression may affect cardiac function. These findings reveal a new mechanism to understand the pathogenesis of human heart failure. The provided data files for RNA-seq contain information for reads that map to human RBM20 only.