Understanding the Noise Spliceosomal snRNA Profiling

Abstract: The concept of the gene has been constantly challenged by new discoveries in the life sciences. Recent challenging observations include the high frequency of alternative splicing events and the common transcription of non-protein-coding-RNAs (ncRNAs) from the genome. The latter has long been considered noise in biological systems. Multiple lines of evidence from genomic studies indicate that alternative splicing and ncRNA play important roles in expanding proteome diversity in eukaryotes. Here, the aim is to find the link between alternative splicing and ncRNAs by studying the expression profile of the spliceosomal snRNAs (U snRNA).Spliceosomal snRNAs are essential for pre-mRNA splicing in eukaryotes. They participate in splice site selection, recruitment of protein factors and catalyzing the splicing reaction. Because of this, both the abundance and diversity of U snRNAs were expected to be large. In our study we deeply analyzed the U snRNA population in primates using a combination of bioinformatical, biochemical and high throughput sequencing approaches. This transcriptome profiling has revealed that human, chimpanzee and rhesus have similar U snRNA populations, i.e. the vast majority of U snRNAs originate from few well-defined gene loci and the heterogeneity observed in U snRNA populations was largely due to the presence of SNPs at these loci. It seems that the gene loci that could potentially encode a significantly heterogeneous population of U snRNAs are mostly silent. Only few minority transcripts were detected in our study, and among them three U1-like snRNAs might play a role in the regulation of alternative splicing by recognizing non-canonical splicing sites.Mutations of U snRNA have been shown to impact the splicing process. Therefore, our study provides a reference to study the biological significance of SNPs in U snRNA genes and their association with diseases.