Project description:Alternative polyadenylation generates numerous 3' mRNA isoforms per gene; regulation of this process is critical in development and impaired in cancer. Individual isoforms from the same gene can vary greatly in biological properties such as translational efficiency, localization, and half-life. Even closely related isoforms - including those differing by a single nt - can have different biological properties, but the underlying mechanisms are unknown. Here we show that many highly similar yeast isoforms unexpectedly exhibit extensive structural variation and differential Pab1 binding, and that these physical properties serve as a good predictor of relative isoform stability. We developed DREADS, a dimethyl sulphate (DMS)-based technique, to obtain the first transcriptome-scale structural description of individual 3' mRNA isoforms in vivo. Strikingly, near-identical yeast mRNA isoforms arising from the same gene can possess dramatically different DMS modification profiles over hundreds of nt upstream of the poly(A) tail. DREADS analyses of the same mRNAs refolded in vitro or in different species indicate that structural differences in vivo are often due to trans- acting factors. CLIP-READS, a technique we developed to measure isoform-specific binding, reveals that differences in Poly(A) binding protein (Pab1) binding to 3' ends correlate with the extent of structural variation for closely-spaced isoforms. A pattern encompassing single-strandedness near the 3' terminus, double-stranded character of the poly(A) tail, and low Pab1 binding is significantly associated with mRNA stability. Sequences responsible for isoform-specific structures, differential Pab1 binding, and mRNA stability are evolutionarily conserved, and are indicative of biological function.

Project description:Extensive structural differences of closely related 3’ mRNA isoforms: links to Pab1 binding and mRNA stability

Project description: Not available

Project description:Decoding post-transcriptional regulatory programs underlying gene expression is a crucial step toward a predictive dynamical understanding of cellular state transitions. Despite recent systematic efforts, the sequence determinants of such mechanisms remain largely uncharacterized. An important obstacle in revealing these elements stems from the contribution of local secondary structures in defining interaction partners in a variety of regulatory contexts, including but not limited to transcript stability, alternative splicing and localization. There are many documented instances where the presence of a structural regulatory element dictates alternative splicing patterns (e.g. human cardiac troponin T) or affects other aspects of RNA biology. Thus, a full characterization of post-transcriptional regulatory programs requires capturing information provided by both local secondary structures and the underlying sequence. We have developed a computational framework based on context-free grammars and mutual information that systematically explores the immense space of structural elements and reveals motifs that are significantly informative of genome-wide measurements of RNA behavior. The application of this framework to genome-wide mammalian mRNA stability data revealed eight highly significant elements with substantial structural information, for the strongest of which we showed a major role in global mRNA regulation. Through biochemistry, mass-spectrometry, and in vivo binding studies, we identified HNRPA2B1 as the key regulator that binds this element and stabilizes a large number of its target genes. Ultimately, we created a global post-transcriptional regulatory map based on the identity of the discovered linear and structural cis-regulatory elements, their regulatory interactions and their target pathways. This approach can also be employed to reveal the structural elements that modulate other aspects of RNA behavior. This SuperSeries is composed of the following subset Series: GSE35749: sRSM1 synthetic decoy vs. scrambled transfections in MDA-MB-231 cells GSE35753: HNRPA2B1 RIP-chip GSE35756: Whole-genome decay rate measurements in MDA-MB-231 cells transfected with HNRPA2B1 siRNAs versus controls GSE35757: siRNA-mediated HNRPA2B1 knock-down in MDA-MB-231 cells GSE35799: HNRPA2B1 HITS-CLIP Refer to individual Series

Project description: Not available

Project description: Not available

Project description: Not available

Project description:Decoding post-transcriptional regulatory programs underlying gene expression is a crucial step toward a predictive dynamical understanding of cellular state transitions. Despite recent systematic efforts, the sequence determinants of such mechanisms remain largely uncharacterized. An important obstacle in revealing these elements stems from the contribution of local secondary structures in defining interaction partners in a variety of regulatory contexts, including but not limited to transcript stability, alternative splicing and localization. There are many documented instances where the presence of a structural regulatory element dictates alternative splicing patterns (e.g. human cardiac troponin T) or affects other aspects of RNA biology. Thus, a full characterization of post-transcriptional regulatory programs requires capturing information provided by both local secondary structures and the underlying sequence. We have developed a computational framework based on context-free grammars and mutual information that systematically explores the immense space of structural elements and reveals motifs that are significantly informative of genome-wide measurements of RNA behavior. The application of this framework to genome-wide mammalian mRNA stability data revealed eight highly significant elements with substantial structural information, for the strongest of which we showed a major role in global mRNA regulation. Through biochemistry, mass-spectrometry, and in vivo binding studies, we identified HNRPA2B1 as the key regulator that binds this element and stabilizes a large number of its target genes. Ultimately, we created a global post-transcriptional regulatory map based on the identity of the discovered linear and structural cis-regulatory elements, their regulatory interactions and their target pathways. This approach can also be employed to reveal the structural elements that modulate other aspects of RNA behavior. This SuperSeries is composed of the SubSeries listed below.

Project description: Not available

Project description: Not available