Abstract
Alternative splicing of pre-messenger RNA transcripts enables the generation of multiple protein isoforms from the same gene locus, providing a major source of protein diversity in mammalian genomes. RNA binding proteins (RBPs) bind to RNA to control splice site choice and define which exons are included in the resulting mature RNA transcript. However, depending on where the RBPs bind relative to splice sites, they can activate or repress splice site usage. To explore this position-specific regulation, in vivo binding sites identified by methods such as cross-linking and immunoprecipitation (CLIP) are integrated with alternative splicing events identified by RNA-seq or microarray. Merging these data sets enables the generation of a “splicing map,” where CLIP signal relative to a merged meta-exon provides a simple summary of the position-specific effect of binding on splicing regulation. Here, we provide RBP-Maps, a software tool to simplify generation of these maps and enable researchers to rapidly query regulatory patterns of an RBP of interest. Further, we discuss various alternative approaches to generate such splicing maps, focusing on how decisions in construction (such as the use of peak versus read density, or whole-reads versus only single-nucleotide candidate crosslink positions) can affect the interpretation of these maps using example eCLIP data from the 150 RBPs profiled by the ENCODE consortium.
Highlights
After RNA is transcribed from DNA, intronic regions are removed and exons are joined together in the process of splicing
The ability to profile both RNA processing and RNA binding proteins (RBPs) association transcriptome-wide in vivo has revolutionized our ability to study the mechanisms of RNA processing
Integration of in vivo RBP targets identified by methods such as cross-linking and immunoprecipitation (CLIP) and RBP-responsive targets by knockdown or over-expression followed by RNA-seq or microarray, coupled with bioinformatics analysis techniques, has enabled the mapping of position-dependent regulatory principles for RBPs
Summary
After RNA is transcribed from DNA, intronic regions are removed and exons are joined together in the process of splicing. Most exons are constitutively spliced, meaning they are always included in the mature RNA transcript that is translated. Recent estimates indicate that nine out of every 10 human genes undergo alternative splicing in which alternative splice sites are utilized in a cell type- or condition-specific manner to create distinct RNA transcripts from the same pre-mRNA molecule (Wang et al 2008). The key role of alternative splicing is further confirmed by the linkage of splicing regulation to numerous human diseases, including neurological disorders and many types of cancer (Scotti and Swanson 2016). Available online through the RNA Open Access option
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