Project description:Quaking is a global regulator of muscle-specific alternative splicing in vertebrates

Project description:Quaking is a global regulator of muscle-specific alternative splicing in vertebrates [siRNA data]

Project description:This work provides the first evidence that Qk is a global regulator of splicing in vertebrates, defines a new splicing regulatory network in muscle, and suggests that overlapping splicing networks contribute to the complexity of changes in alternative splicing during differentiation. Alternative splicing contributes to muscle development and differentiation, but the complete set of muscle splicing factors and their combinatorial interactions are not known. Previously work identifies ACUAA (STAR motif) as an enriched sequence near muscle-specific alternative exons such as Capzb exon 9. We did mass spectrometry of proteins selected by wild type and mutant Capzb intron 9 RNA affinity chromatography, and identified Quaking (Qk), a protein known to regulate mRNA function through ACUAA motifs in 3' UTRs. We show that in myoblasts, Qk promotes inclusion of Capzb exon 9 in opposition to repression by PTB. Qk knockdown in myoblasts has little effect on transcript levels, but alters inclusion of 824 cassette exons whose adjacent intron sequences are enriched in ACUAA motifs. During differentiation to myotubes, Qk levels increase 2-3 fold, suggesting a mechanism for Qk-responsive exon regulation. We captured the PTB splicing regulatory network and intersected it with the Qk network, identifying overlap between the functions of Qk and PTB. Approximately 60% of exons whose inclusion is altered during myogenesis appear to be under control of one or both of these splicing factors in myoblasts. This series is the C2C12 differentiation data. It is 9 arrays, 3 timepoints, with 3 replicates. The time points are 0 hrs, 24 hrs, and 72hrs.

Project description:This work provides the first evidence that Qk is a global regulator of splicing in vertebrates, defines a new splicing regulatory network in muscle, and suggests that overlapping splicing networks contribute to the complexity of changes in alternative splicing during differentiation. Alternative splicing contributes to muscle development and differentiation, but the complete set of muscle splicing factors and their combinatorial interactions are not known. Previously work identifies ACUAA (STAR motif) as an enriched sequence near muscle-specific alternative exons such as Capzb exon 9. We did mass spectrometry of proteins selected by wild type and mutant Capzb intron 9 RNA affinity chromatography, and identified Quaking (Qk), a protein known to regulate mRNA function through ACUAA motifs in 3' UTRs. We show that in myoblasts, Qk promotes inclusion of Capzb exon 9 in opposition to repression by PTB. Qk knockdown in myoblasts has little effect on transcript levels, but alters inclusion of 824 cassette exons whose adjacent intron sequences are enriched in ACUAA motifs. During differentiation to myotubes, Qk levels increase 2-3 fold, suggesting a mechanism for Qk-responsive exon regulation. We captured the PTB splicing regulatory network and intersected it with the Qk network, identifying overlap between the functions of Qk and PTB. Approximately 60% of exons whose inclusion is altered during myogenesis appear to be under control of one or both of these splicing factors in myoblasts. This series is the C2C12 Qk and PTB siRNA data. It is 12 arrays: 3 PTB siRNA arrays , 3 Qk siRNA arrays, and 6 mock siRNA arrays.

Project description:This work provides the first evidence that Qk is a global regulator of splicing in vertebrates, defines a new splicing regulatory network in muscle, and suggests that overlapping splicing networks contribute to the complexity of changes in alternative splicing during differentiation. Alternative splicing contributes to muscle development and differentiation, but the complete set of muscle splicing factors and their combinatorial interactions are not known. Previously work identifies ACUAA (STAR motif) as an enriched sequence near muscle-specific alternative exons such as Capzb exon 9. We did mass spectrometry of proteins selected by wild type and mutant Capzb intron 9 RNA affinity chromatography, and identified Quaking (Qk), a protein known to regulate mRNA function through ACUAA motifs in 3' UTRs. We show that in myoblasts, Qk promotes inclusion of Capzb exon 9 in opposition to repression by PTB. Qk knockdown in myoblasts has little effect on transcript levels, but alters inclusion of 824 cassette exons whose adjacent intron sequences are enriched in ACUAA motifs. During differentiation to myotubes, Qk levels increase 2-3 fold, suggesting a mechanism for Qk-responsive exon regulation. We captured the PTB splicing regulatory network and intersected it with the Qk network, identifying overlap between the functions of Qk and PTB. Approximately 60% of exons whose inclusion is altered during myogenesis appear to be under control of one or both of these splicing factors in myoblasts.

Project description:This work provides the first evidence that Qk is a global regulator of splicing in vertebrates, defines a new splicing regulatory network in muscle, and suggests that overlapping splicing networks contribute to the complexity of changes in alternative splicing during differentiation. Alternative splicing contributes to muscle development and differentiation, but the complete set of muscle splicing factors and their combinatorial interactions are not known. Previously work identifies ACUAA (STAR motif) as an enriched sequence near muscle-specific alternative exons such as Capzb exon 9. We did mass spectrometry of proteins selected by wild type and mutant Capzb intron 9 RNA affinity chromatography, and identified Quaking (Qk), a protein known to regulate mRNA function through ACUAA motifs in 3' UTRs. We show that in myoblasts, Qk promotes inclusion of Capzb exon 9 in opposition to repression by PTB. Qk knockdown in myoblasts has little effect on transcript levels, but alters inclusion of 824 cassette exons whose adjacent intron sequences are enriched in ACUAA motifs. During differentiation to myotubes, Qk levels increase 2-3 fold, suggesting a mechanism for Qk-responsive exon regulation. We captured the PTB splicing regulatory network and intersected it with the Qk network, identifying overlap between the functions of Qk and PTB. Approximately 60% of exons whose inclusion is altered during myogenesis appear to be under control of one or both of these splicing factors in myoblasts.

Project description:A number of microRNAs have been shown to regulate skeletal muscle development and differentiation. MicroRNA-222 is downregulated during myogenic differentiation and its overexpression leads to alteration of muscle differentiation process and specialized structures. By using RNA induced silencing complex (RISC) pulldown followed by RNA sequencing, combined with in silico microRNA target prediction, we have identified two new targets of microRNA-222 involved in the regulation of myogenic differentiation, Ahnak and Rbm24. Specifically, the RNA binding protein Rbm24 is a major regulator of muscle specific alternative splicing and its downregulation by microRNA-222 results in defective exon inclusion impairing the production of muscle-specific isoforms of Coro6, Fxr1 and NACA transcripts. Reconstitution of normal levels of Rbm24 in cells overexpressing microRNA-222 rescues muscle-specific splicing. In conclusion, we have identified a new function of microRNA-222 leading to alteration of myogenic differentiation at the level of alternative splicing, and we provide evidence that this effect is mediated by Rbm24 protein. We built linear models using 2 different experiments and two conditions (miR222 over expression (n=1) and control siRNA(n=2)) with the linear formula (~condition + experiment).

Project description:Quaking are RNA binding proteins, which are known to regulate the expression of different genes at the post-transcriptional level. Genetic interference with quaking a (qkia) and quaking c (qkic) leads to major myofibril defects during zebrafish development, without affecting early muscle differentiation. In order to understand how qkia and qkic jointly regulate myofibril formation, we performed a comparative analysis of the transcriptome of qkia/qkic (qkia mutant injected with qkic morpholino) versus control embryos. We show that Quaking activity is required for accumulation of the muscle-specific tropomyosin 3 transcript, tpm3.1. Whereas interference with tmp3.1 function disrupts myofibril formation, reintroducing tpm3.1 transcripts into embryos with reduced Quaking activity can restore structured myofibrils. Thus, we identify tropomyosin as an essential component in the process of myofibril formation and as a relay downstream of the regulator proteins Quaking.

Project description:A number of microRNAs have been shown to regulate skeletal muscle development and differentiation. MicroRNA-222 is downregulated during myogenic differentiation and its overexpression leads to alteration of muscle differentiation process and specialized structures. By using RNA induced silencing complex (RISC) pulldown followed by RNA sequencing, combined with in silico microRNA target prediction, we have identified two new targets of microRNA-222 involved in the regulation of myogenic differentiation, Ahnak and Rbm24. Specifically, the RNA binding protein Rbm24 is a major regulator of muscle specific alternative splicing and its downregulation by microRNA-222 results in defective exon inclusion impairing the production of muscle-specific isoforms of Coro6, Fxr1 and NACA transcripts. Reconstitution of normal levels of Rbm24 in cells overexpressing microRNA-222 rescues muscle-specific splicing. In conclusion, we have identified a new function of microRNA-222 leading to alteration of myogenic differentiation at the level of alternative splicing, and we provide evidence that this effect is mediated by Rbm24 protein.

Project description:Myotonic dystrophes (DM), the most common adult muscular dystrophy, are the first recognized examples of RNA-mediated diseases in which expression of mutant RNAs containing expanded CUG or CCUG repeats interfere with the splicing of other mRNAs. Using whole-genome microarrays, we found that alternative splicing of the BIN1 mRNA is altered in DM skeletal muscle tissues, resulting in the expression of an inactive form of BIN1 deprived of phosphoinositide-binding and membrane-tubulating activities. BIN1 is involved in tubular invaginations of the plasma membrane and is essential for biogenesis of the muscle T-tubules, which are specialized skeletal muscle membrane structures essential to correct excitation-contraction (E-C) coupling. Mutations in the BIN1 gene cause centronuclear myopathy (CNM) that shares some histopathological features with DM, and both diseases are characterized by muscle weakness. Consistent with a loss-of-function of BIN1, muscle T-tubules were altered in DM patients, and membrane tubulation was restored upon expression of the correct splicing form of BIN1 in DM muscle cells. By deciphering the mechanism of BIN1 splicing mis-regulation we demonstrate that the splicing regulator, MBNL1, which is sequestered by expanded CUG and CCUG in DM, binds the BIN1 pre-mRNA and regulates directly its alternative splicing. Finally, reproducing BIN1 splicing alteration in mice is sufficient to reproduce the DM features of T-tubule alterations and muscle weakness. We propose that alteration of BIN1 alternative splicing regulation leads to muscle weakness, a predominant pathological feature of DM. Exon-Array analysis of control and CDM1 muscle primary cultures 10 days of differentiation