Project description:The mRNA repertoire is specific to a given tissue type. This specificity, whether it is in the levels of gene expression or the splicing pattern of the transcripts, is important to study to increase our general knowledge of transcription and alternative splicing, as well as to identify novel coding sequence that can be important for elucidating the mechanisms of disease. We have performed RNA-Seq on three normal human retinal samples and have found a profound level of novel alternative splicing including novel exons, exon skipping, and 3’ and 5’ alternate splice sites. Additionally, we have identified hundreds of novel genes. With so many novel splicing events identified in the retinal transcriptome, we set out to determine if these novel features were indeed real. We developed a high throughput capture set to target 14,696 of the novel features. We found that 99% of the novel features do validate, including those initially detected at a depth of coverage as low as one. These results confirm that the transcripts expressed in the retina are much more diverse than previously identified. The complete human retinal transcriptome described here will be useful for investigators studying multiple aspects of retinal biology and disease.

Project description:Inappropriate or sustained activation of innate immunity is a pathologic feature of several common cardio-metabolic disorders. Little is known, however, about transcriptomic modulation during inflammatory stress in disease-relevant human tissues. We applied deep RNA sequencing (RNA-seq) during low-dose experimental endotoxemia (LPS) in healthy humans to interrogate, in an unbiased manner, inflammatory tissue-level transcriptome responses of relevance to complex cardio-metabolic diseases. We utilized adipose and blood samples from three individuals who underwent a standardized inpatient endotoxemia protocol. Our comprehensive analysis revealed substantial, highly tissue- and subject-specific LPS-modulated changes in the expression of protein-coding genes and linc-RNAs as well as alternative splicing (AS). We also confirmed adipocytes and macrophages as potential cell sources of selective LPS-modulated linc-RNAs and AS events. Finally, we defined disease relevance of a subset of findings in obese adipose tissue and through interrogation of overlap with genome-wide association study loci for cardio-metabolic traits. Our findings provide novel insights into tissue-level genomic regulation, not detectable through analysis of DNA variations alone, of relevance to common cardio-metabolic diseases. Using RNA-seq data to study LPS-modulated changes in lincRNA expression for adipose and blood of a healthy individual.

Project description:To systematically explore the functions of core splicing factors and regulators in alternative splicing, RNA-seq analyses were carried out upon the knockdown of over 305 splicing-related factors.

Project description:A critical task in high throughput sequencing is aligning millions of short reads to a reference genome. Alignment is especially complicated for RNA sequencing (RNA-Seq) because of RNA splicing. A number of RNA-Seq algorithms are available, and claim to align reads with high accuracy and efficiency while detecting splice junctions. RNA-Seq data is discrete in nature; therefore with reasonable gene models and comparative metrics RNA-Seq data can be simulated to sufficient accuracy to enable meaningful benchmarking of alignment algorithms. The exercise to rigorously compare all viable published RNA-Seq algorithms has not previously been performed. RESULTS: We developed an RNA-Seq simulator that models the main impediments to RNA alignment, including alternative splicing, insertions, deletions, substitutions, sequencing errors, and intron signal. We used this simulator to measure the accuracy and robustness of available algorithms at the base and junction levels. Additionally, we used RT-PCR and Sanger sequencing to validate the ability of the algorithms to detect novel transcript features such as novel exons and alternative splicing in RNA-Seq data from mouse retina. A pipeline based on BLAT was developed to explore the performance of established tools for this problem, and to compare it to the recently developed methods. This pipeline, the RNA-Seq Unified Mapper (RUM) performs comparably to the best current aligners and provides an advantageous combination of accuracy, speed and usability. RNA-Seq of mouse retinal RNA, as described.

Project description:This SuperSeries is composed of the following subset Series: GSE31485: CTCF promotes RNA pol II pausing and links DNA methylation to alternative splicing [ChIP-Seq] GSE31486: CTCF promotes RNA pol II pausing and links DNA methylation to alternative splicing [RNA-Seq] Refer to individual Series

Project description:Analysis of alternative splicing in heart (left ventricles) samples of 3 adult DM1 patients versus 3 adult controls PolyA RNA from left ventricles (heart) of 3 controls and 3 DM1 patients were analysed by massive parrallel sequencing

Project description:Purple-grain wheat are caused by anthocyanin accumulation in the seed coat. But little is known about molecular mechanism of anthocyanin biosynthesis. The anthocyanin biosynthesis and accumulation were affected by light in purple-grain wheat. The spikes of purple-grain wheat Luozhen No.1 were bagged with four-layer Kraft paper bags after pollination. To identify genes involved in the anthocyanin biosynthesis, we sequenced four pericarp cDNA libraries, D15 (15 DAP), D20 (20 DAP) of shading treatment, and L15 (15 DAP), L20 (20 DAP) of untreated control using an Illumina HiSeqTM 2000. After quality control, raw reads are filtered into clean reads which will be aligned to the reference sequences. The alignment data is utilized to calculate distribution of reads on reference genes and mapping ratio, and proceed with downstream analysis including gene and isoform expression, deep analysis based on gene expression (PCA/correlation/screening differentially expressed genes and so on),exon expression, gene structure refinement, alternative splicing, novel transcript prediction and annotation, SNP detection, Indel detection. Further, we also perform deep analysis based on different expression genes, including Gene Ontology (GO) enrichment analysis, Pathway enrichment analysis, cluster analysis, and finding transcriptor factor.

Project description:Adjacent alternative 3’ splice sites, those separated by ≤18nt, provide a unique problem in the study of alternative splicing regulation; there is overlap of the cis-elements that define the adjacent sites. Identification of the intron's 3' end depends upon sequence elements that define the branchpoint, polypyrimidine tract and terminal AG dinucleotide. Starting with RNA-seq data from germline-enriched and somatic cell-enriched C. elegans samples, we identify hundreds of introns with adjacent alternative 3’ splice sites. We identify 203 events that undergo tissue-specific alternative splicing. For these, the regulation is mono-directional, with somatic cells preferring to splice at the distal 3' splice site and germline cells showing a distinct shift towards usage of the adjacent proximal 3' splice site. Splicing patterns in somatic cells follow consensus rules of 3’ splice site definition, using sites with a short stretch of pyrimidines and an AG dinucleotide. Splicing in germline cells occurs at proximal 3' splice sites that frequently lack a polypyrimidine tract or, occasionally, the AG dinucleotide. We provide evidence that use of germline-specific proximal 3' splice sites is conserved across Caenorhabditis species. We propose that divergent mechanisms exist between germline and somatic cells in determining an intron terminus at adjacent alternative 3’ splice sites. Examination of alternative splicing changes between germline- and somatic-cell enriched samples as well as nonsense-mediated decay mutants.

Project description:The global impact of DNA methylation on alternative splicing is largely unknown. Using a genome-wide approach in wild-type and methylation-deficient embryonic stem cells, we found that DNA methylation can act both as an enhancer and as a silencer of splicing, and affects the splicing of more than 20% of alternative exons. These exons are characterized by distinct genetic and epigenetic signatures. Alternative splicing regulation of a subset of these exons can be explained by Heterochromatin protein 1 (HP1), which silences or enhances exon recognition in a position-dependent manner. We constructed an experimental system using site-specific targeting of a methylated/unmethylated gene, and demonstrate a direct causal relationship between DNA methylation and alternative splicing. HP1 regulates this geneM-bM-^@M-^Ys alternative splicing in a methylation-dependent manner by recruiting splicing factors to its methylated form. Our results demonstrate DNA methylation's significant global influence on mRNA splicing, and identify a specific mechanism of splicing regulation mediated by HP1. BS-seq on WT mouse ES cells (2 replicates), MNase-seq on WT and TKO cells (3 replicates), mRNA-seq on WT and TKO cells as well as HP1 knock-down cells (2 replicates for each sample)

Project description:We report RNA-Seq data from MPC11 plasmacytoma cell lines transduced with either control hairpins (shGFP) or hairpins targeting the transcriptional elongation factor ELL2. ELL2 has been identified as regulating the alternative splicing and polyadenylation of immunoglobulin pre-mRNA, and is highly expressed by plasma cells but not other B cells. Notably, ELL2 drives the accumulation of transcripts encoding secreted immunoglobulin at the expense of membrane-associated transcripts. This study sought to examine the impact of ELL2 on mRNA processing at the transcriptome level, and found that ELL2 controls the alternative processing of 12% of annotated transcripts in MPC11 cells. Examination of pre-mRNA splicing patterns in either control or ELL2-depleted cells