Project description:Control of gene expression is fundamental to biology, and post transcriptional regulation is an important component of this process. In mammals, the 3′UTR in particular serves as a major source of regulatory information within the transcript. Here, we developed an accurate, high throughput, reporter based system to evaluate the impact of >1,400 full length human 3′UTRs on RNA stability, translational regulation, and total protein output. We used this data to model the relative contributions of RNA stability and translational efficiency towards total 3′UTR mediated regulation, revealing an unexpectedly large role for 3′UTR specified translational control. We observed relationships between GC content and 3′UTR length and different modes of regulation, and identified candidate RNA binding proteins involved in 3′UTR dependent gene expression. We compared regulation from >1,400 3′UTRs under control of two dissimilar promoters, which revealed promoter driven differences in post transcriptional regulation for certain 3′UTRs. Together, this dataset represents a comprehensive characterization of 3′UTR mediated quantitative regulation.

Project description:Control of gene expression is fundamental to biology, and post transcriptional regulation is an important component of this process. In mammals, the 3′UTR in particular serves as a major source of regulatory information within the transcript. Here, we developed an accurate, high throughput, reporter based system to evaluate the impact of >1,400 full length human 3′UTRs on RNA stability, translational regulation, and total protein output. We used this data to model the relative contributions of RNA stability and translational efficiency towards total 3′UTR mediated regulation, revealing an unexpectedly large role for 3′UTR specified translational control. We observed relationships between GC content and 3′UTR length and different modes of regulation, and identified candidate RNA binding proteins involved in 3′UTR dependent gene expression. We compared regulation from >1,400 3′UTRs under control of two dissimilar promoters, which revealed promoter driven differences in post transcriptional regulation for certain 3′UTRs. Together, this dataset represents a comprehensive characterization of 3′UTR mediated quantitative regulation.

Project description:Control of gene expression is fundamental to biology, and post transcriptional regulation is an important component of this process. In mammals, the 3′UTR in particular serves as a major source of regulatory information within the transcript. Here, we developed an accurate, high throughput, reporter based system to evaluate the impact of >1,400 full length human 3′UTRs on RNA stability, translational regulation, and total protein output. We used this data to model the relative contributions of RNA stability and translational efficiency towards total 3′UTR mediated regulation, revealing an unexpectedly large role for 3′UTR specified translational control. We observed relationships between GC content and 3′UTR length and different modes of regulation, and identified candidate RNA binding proteins involved in 3′UTR dependent gene expression. We compared regulation from >1,400 3′UTRs under control of two dissimilar promoters, which revealed promoter driven differences in post transcriptional regulation for certain 3′UTRs. Together, this dataset represents a comprehensive characterization of 3′UTR mediated quantitative regulation.

Project description:Control of gene expression is fundamental to biology, and post transcriptional regulation is an important component of this process. In mammals, the 3′UTR in particular serves as a major source of regulatory information within the transcript. Here, we developed an accurate, high throughput, reporter based system to evaluate the impact of >1,400 full length human 3′UTRs on RNA stability, translational regulation, and total protein output. We used this data to model the relative contributions of RNA stability and translational efficiency towards total 3′UTR mediated regulation, revealing an unexpectedly large role for 3′UTR specified translational control. We observed relationships between GC content and 3′UTR length and different modes of regulation, and identified candidate RNA binding proteins involved in 3′UTR dependent gene expression. We compared regulation from >1,400 3′UTRs under control of two dissimilar promoters, which revealed promoter driven differences in post transcriptional regulation for certain 3′UTRs. Together, this dataset represents a comprehensive characterization of 3′UTR mediated quantitative regulation.

Project description:Much of posttranscriptional mRNA regulation occurs through cis-acting sequences in mRNA 3´ untranslated regions (UTRs), which interact with specific proteins and ribonucleoprotein complexes that modulate translation, mRNA stability and subcellular localization. Studies in Caenorhabditis elegans have revealed indispensable roles for 3´UTR-mediated gene regulation, yet most C. elegans genes have lacked annotated 3´UTRs. Here we describe a high-throughput method to reliably identify 3´ ends of polyadenylated RNAs. This method, called poly(A)-position profiling by sequencing (3P-Seq), was used to determine the UTRs of C. elegans. Compared to standard methods also recently applied to C. elegans UTRs, 3P-Seq identified 8775 additional UTRs while excluding thousands of shorter UTR isoforms that do not appear to be authentic. Analysis of this expanded and corrected dataset indicated that the high A/U content of C. elegans 3´UTRs facilitated genome compaction, since the elements specifying cleavage and polyadenylation, which are A/U-rich, can more readily emerge in A/U rich regions. Indeed, 30% of the protein-coding genes have mRNAs with alternative, partially overlapping end regions that generate another 10,000 cleavage and polyadenylation sites that had gone largely unnoticed and represent potential evolutionary intermediates of progressive UTR shortening. Moreover, a third of the convergently transcribed genes utilize palindromic arrangements of bidirectional elements to specify UTRs with convergent overlap, which also contributes to genome compaction by eliminating regions between genes. Although nematode 3´UTRs have median length only one-sixth that of mammalian 3´UTRs, they have twice the density of conserved microRNA sites, in part because additional types of seed-complementary sites are preferentially conserved. These findings reveal the influence of cleavage and polyadenylation on the evolution of genome architecture and provide resources for studying posttranscriptional gene regulation. Nine samples (10 sequencing runs) from various mixed and specific stages of wild-type Caenorhabditis elegans and glp-4 mutant adults.

Project description:Much of posttranscriptional mRNA regulation occurs through cis-acting sequences in mRNA 3´ untranslated regions (UTRs), which interact with specific proteins and ribonucleoprotein complexes that modulate translation, mRNA stability and subcellular localization. Studies in Caenorhabditis elegans have revealed indispensable roles for 3´UTR-mediated gene regulation, yet most C. elegans genes have lacked annotated 3´UTRs. Here we describe a high-throughput method to reliably identify 3´ ends of polyadenylated RNAs. This method, called poly(A)-position profiling by sequencing (3P-Seq), was used to determine the UTRs of C. elegans. Compared to standard methods also recently applied to C. elegans UTRs, 3P-Seq identified 8775 additional UTRs while excluding thousands of shorter UTR isoforms that do not appear to be authentic. Analysis of this expanded and corrected dataset indicated that the high A/U content of C. elegans 3´UTRs facilitated genome compaction, since the elements specifying cleavage and polyadenylation, which are A/U-rich, can more readily emerge in A/U rich regions. Indeed, 30% of the protein-coding genes have mRNAs with alternative, partially overlapping end regions that generate another 10,000 cleavage and polyadenylation sites that had gone largely unnoticed and represent potential evolutionary intermediates of progressive UTR shortening. Moreover, a third of the convergently transcribed genes utilize palindromic arrangements of bidirectional elements to specify UTRs with convergent overlap, which also contributes to genome compaction by eliminating regions between genes. Although nematode 3´UTRs have median length only one-sixth that of mammalian 3´UTRs, they have twice the density of conserved microRNA sites, in part because additional types of seed-complementary sites are preferentially conserved. These findings reveal the influence of cleavage and polyadenylation on the evolution of genome architecture and provide resources for studying posttranscriptional gene regulation.

Project description:The 3' untranslated region (3'UTR) constitutes a major site of post-transcriptional regulation of gene expression. Sequence elements in the 3'UTR interact with trans-acting regulators such as microRNAs that affect translation and stability. The overall aim is to use a 3'RACE cloning-sequencing stragety to identify the 3'UTRs of C. elegans transcripts and explore their heterogeneity in different developmental stages and tissues. For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf Use RACE clones to identify 3'UTR isoforms via deep sequencing.

Project description:The 3' untranslated region (3'UTR) constitutes a major site of post-transcriptional regulation of gene expression. Sequence elements in the 3'UTR interact with trans-acting regulators such as microRNAs that affect translation and stability. The overall aim is to use a 3'RACE cloning-sequencing stragety to identify the 3'UTRs of C. elegans transcripts and explore their heterogeneity in different developmental stages and tissues. For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf

Project description:The 3' untranslated region (3'UTR) constitutes a major site of post-transcriptional regulation of gene expression. Sequence elements in the 3'UTR interact with trans-acting regulators such as microRNAs that affect translation and stability. The overall aim is to use a 3'RACE cloning-sequencing stragety to identify the 3'UTRs of C. elegans transcripts and explore their heterogeneity in different developmental stages and tissues. Keywords: Transcriptome analysis For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf Raw data files are available on our FTP site: ftp://ftp.ncbi.nlm.nih.gov/pub/geosup/Series/GSE17781

Project description:Dynamic 3' UTRs variation mediated by APA is one of the major determinants of post-transcriptional regulation. Though some progress has been made in understanding its function in mammalian cells, the role of APA in the model organism S. cerevisiae, which lack of miRNAs, is a matter of debate. Unlike mammalian cells, most of S. cerevisiae genes tend to express mRNAs with longer 3′ UTRs in proliferating cells. Further analysis demonstrated that 3' UTRs length and mRNA expression were negatively correlated in different growth conditions. By combining APA sequencing and polysome profiling, we observed that mRNA isoforms with shorter 3' UTRs with a higher translational efficiency in proliferating cells but not quiescent. Further analysis demonstrated that different function genes translational efficiency control by APA are differential modulated and closely related with growth conditions. Furthermore, we observed the correlation between asRNAs and translational efficiency of different length 3′ UTR transcripts, suggests asRNAs may involve in the regulation of translational efficiency mediated by APA. Thus, this study indicates conservation of molecular function of APA in different Eukaryotes, highlighting the importance of APA in regulating gene function.