Recent developments in high-throughput RNA sequencing methods coupled with innovative bioinformatic tools have uncovered thousands of circular (circ)RNAs. CircRNAs have emerged as a vast and novel class of regulatory RNAs with potential to modulate gene expression by acting as sponges for microRNAs (miRNAs) and RNA-binding proteins (RBPs). The biochemical enrichment of circRNAs by exoribonuclease treatment or by depletion of polyadenylated RNAs coupled with deep-sequencing is widely used for the systematic identification of circRNAs. Although these methods enrich circRNAs substantially, they do not eliminate efficiently non-polyadenylated and highly-structured RNAs. Here, we describe a method we termed RPAD, based on initial RNase R treatment followed by Polyadenylation and poly(A)+ RNA Depletion. These joint interventions drastically depleted linear RNAs leading to isolation of highly pure circRNAs from total RNA pools. By facilitating the isolation of highly pure circRNAs, RPAD enables the elucidation of circRNA biogenesis, sequence, and function.
Keywords: Backsplice sequence; CircRNAs; Linear RNA depletion; Polyadenylation; RNase R; RT-qPCR.
Published by Elsevier Inc.