Project description:Steady-state gene expression is a coordination of synthesis and decay of RNA through epigenetic regulation, transcription factors, miRNAs, and RNA-binding proteins. Here, we present Bru-Seq and BruChase-Seq to assess genome-wide changes to RNA synthesis and stability in human fibroblasts at homeostasis and after exposure to the proinflammatory TNF. The inflammatory response in human cells involves rapid and dramatic changes in gene expression, and the Bru-Seq and BruChase-Seq techniques revealed a coordinated and complex regulation of gene expression both at the transcriptional and posttranscriptional levels. The combinatory analysis of both RNA synthesis and stability using Bru-Seq and BruChase-Seq allows for a much deeper understanding of mechanisms of gene regulation than afforded by the analysis of steadystate total RNA and should be useful in many biological settings. Analysis of the effect of TNF exposure in nascent gene expression and in transcript stability

Project description:Amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD) share key features, including accumulation of the RNA binding protein TDP-43. TDP-43 regulates RNA homeostasis, but it remains unclear whether RNA stability is affected in these disorders. We use Bru-seq and BruChase-seq to assess genome-wide RNA stability in ALS patient-derived cells, demonstrating profound destabilization of ribosomal and mitochondrial transcripts. This pattern is recapitulated by TDP-43 overexpression, suggesting a primary role for TDP-43 in RNA destabilization, and in post-mortem samples from ALS and FTD patients. Proteomics and functional studies illustrate corresponding reductions in mitochondrial components and compensatory increases in protein synthesis. Collectively, these observations suggest that TDP-43 deposition leads to targeted RNA instability in ALS and FTD, and may ultimately cause cell death by disrupting energy production and protein synthesis pathways.

Project description:Amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD) share key features, including accumulation of the RNA binding protein TDP-43. TDP-43 regulatesRNA homeostasis, but it remains unclear whether RNA stability is affected in these disorders. We used Bru-seq and BruChase-seq to assessgenome-wide RNA stabilityinALS patient-derived cells,demonstratingprofound destabilization of ribosomal and mitochondrial transcripts. This pattern wasrecapitulatedbyTDP-43 overexpression, suggesting a primary role for TDP-43 in RNA destabilization, and in post-mortem samples from ALS and FTD patients. Proteomics and functional studies illustrated corresponding reductionsin mitochondrial components and compensatory increasesin protein synthesis. Collectively, these observations suggest that TDP-43 deposition leads to targeted RNA instability in ALS and FTD, ultimately causing cell death by disrupting energy production and protein synthesis pathways.

Project description:Myotonic dystrophy type 1 (DM1) is a neuro-muscular disorder caused by CTG triplet expansion in the 3'-UTR of the DMPK gene. Mutated transcripts aggregate in muscle nuclei and increase CUGBP1 stability by a not-yet determined mechanism. To assess the involvement of CUGBP1 in DM1, we used Drosophila as a model of the disease and we performed genome wide analyses of gene expression of bru-3 (CUGBP1 orthologue) gain of function line (Mef>bru-3) vs. Mef>lacZ control line.

Project description:Bru-seq nascent RNA sequencing (PubMed ID 23973811) was performed on two primary human fibroblast cell lines, mouse embryonic stem cells, and GM12878 human lymphoblastoid cells. Read data, which include both exon and intron signals, were used to identify transcription unit spans genome-wide, where a transcription unit is roughly correspondent to the longest expressed isoform of a gene. However, because algorithms were not constrained by annotated genes, transcription units need not and often do not correspond precisely to gene boundaries and include extragenic transcription. Transcription units were then compared to separate data sets that comprised induced copy number variants, common fragile sites, and Repli-seq replication timing. The objective was to discover the relationships between transcription unit span and size, local genomic instability, and replication timing. This GEO sample series provides the span and intensity of transcription units called genome-wide in the various samples. Correlations to genome stability and replication timing are provided in the associated manuscript. In addition, one human fibroblast line and the mouse embryonic stem cells had paired samples treated and untreated with low dose aphidicolin. Gene RPKM signal intensities are provided for these samples, although comparing these was not the principal objective of the study. Bru-seq single-read nascent RNA sequencing on human 090 fibroblasts +/- aphidicolin treatment, human UMHF1 fibroblasts (3 replicates), human GM12878 lymphoblastoid cells, and mouse embryonic stem cells+/- aphidicolin treatment.

Project description:BrU incorporation into nascent RNA followed by immunoprecipitation with a BrU specific antibody. The nascent RNA was subsequently eluted with BrU competition.

Project description:BrU incorporation into nascent RNA followed by immunoprecipitation with a BrU specific antibody. The nascent RNA was subsequently eluted with BrU competition.

Project description:Allele-specific analysis of RNA-seq, Bru-seq, and Hi-C data from human diploid B-lymphocytes.

Project description:The cyclin-dependent kinase CDK12 promotes transcription completion of long genes by suppressing the utilization of intronic polyadenylation sites that cause premature transcriptional termination. One class of genes that are particularly affected by loss of CDK12 activity are DNA damage response genes and therefore inhibitors of CDK12 have garnered interest as cancer therapeutic amplifiers. In this study, we used the CDK12/13 inhibitor THZ531 to treat HF1 (normal human fibroblasts), K562 and HeLa cells and the adenine analog 1-NM-PP1 to treat analog-sensitive HeLa cells and to assess the acute effects on transcription and RNA processing using Bru-seq and BruChase-seq. While acute transcriptional changes were small and limited to the 3’-ends of genes, RNA turnover was dramatically affected by CDK12 inhibition. Importantly, the downregulation of DNA damage response genes was predominantly due to increased mRNA turnover. Co-transcriptional splicing was suppressed by CDK12 inhibition. Finally, many introns that showed premature transcriptional termination were found to be resistant to degradation following CDK12 inhibition despite showing efficient splicing. We speculate that premature termination and addition of poly(A)s protect these spliced intronic fragments from degradation. These studies reveal previously unknown roles of CDK12 in regulating RNA turnover and co-transcriptional splicing.

Project description:Pre-mRNA splicing is carried out by the spliceosome and involves splice site recognition, removal of introns, and ligation of exons. Components of the spliceosome have been shown to interact with the elongating RNA polymerase II (RNAPII), which is thought to allow splicing to occur concurrently with transcription. However, little is known about the regulation and efficiency of cotranscriptional splicing in human cells. In this study, we used Bru-seq and BruChase-seq to determine the cotranscriptional splicing efficiencies of 17,000 introns expressed across six human cell lines. We found that less than half of all introns across these six cell lines were cotranscriptionally spliced. Splicing efficiencies for individual introns showed variations across cell lines, suggesting that splicing may be regulated in a cell type–specific manner. Moreover, the splicing efficiency of introns varied within genes. The efficiency of cotranscriptional splicing did not correlate with gene length, intron position, splice site strengths, or the intron/neighboring exons GC content. However, we identified binding signals from multiple RNA binding proteins (RBPs) that correlated with splicing efficiency, including core spliceosomal machinery components—such as SF3B4, U2AF1, and U2AF2 showing higher binding signals in poorly spliced introns. In addition, multiple RBPs, such as BUD13, PUM1, and SND1, showed preferential binding in exons that flank introns with high splicing efficiencies. The nascent RNA splicing patterns presented here across multiple cell types add to our understanding of the complexity in RNA splicing, wherein RNA-binding proteins may play important roles in determining splicing outcomes in a cell type– and intron-specific manner.