The ability of nucleic acids to form double-stranded structures is essential for all living systems on Earth. While DNA employs it for genome replication, RNA molecules fold into complicated secondary and tertiary structures. Current knowledge on functional RNA structures in human protein-coding genes is focused on locally-occurring base pairs. However, chemical crosslinking and proximity ligation experiments have demonstrated that long-range RNA structures are highly abundant. Here, we present the most complete to-date catalog of conserved long-range RNA structures in the human transcriptome, which consists of 1.1 million pairs of conserved complementary regions (PCCRs). PCCRs tend to occur within introns proximally to splice sites, suppress intervening exons, circumscribe circular RNAs, and exert an obstructive effect on cryptic and inactive splice sites. The double-stranded structure of PCCRs is supported by a significant decrease of icSHAPE nucleotide accessibility, high abundance of A-to-I RNA editing sites, and frequent nearby occurrence of forked eCLIP peaks. Introns with PCCRs show a distinct splicing pattern in response to RNA Pol II slowdown suggesting that splicing is widely affected by co-transcriptional RNA folding. Additionally, transcript starts and ends are strongly enriched in regions between complementary parts of PCCRs, leading to an intriguing hypothesis that RNA folding coupled with splicing could mediate co-transcriptional suppression of premature cleavage and polyadenylation events. PCCR detection procedure is highly sensitive with respect to bona fide validated RNA structures at the expense of having a high false positive rate, which cannot be reduced without loss of sensitivity.The catalog of PCCRs is visualized through a UCSC Genome Browser track hub to facilitate further genome research on long-range RNA structures.Double-stranded structure is a key feature of nucleic acids that enables replicating the genomic information and underlies fundamental cellular processes [1,2]. Many RNAs adopt functional secondary structures, and mRNAs are no exception although their main role is to encode proteins [3,4,5,6]. In eukaryotes, RNA structure affects gene expression through modulating all steps of pre-mRNA processing including splicing [7], cleavage and polyadenylation [8], and RNA editing [9]. The loss of functional RNA structure has been increasingly reported as implicated in hereditary disease and cancer [10,11,12,13].Recent progress in high-throughput sequencing techniques enabled several experimental strategies to determine RNA structure in vivo [14,15,16]. Chemical RNA structure probing can reveal which bases are single-or double-stranded, but it cannot determine which nucleotides form base pairs [17,18,19,20,21].In order to identify the interacting partners, RNA structure probing has to be combined with de novo RNA structure prediction [22], but due to a number of technical limitations such methods cannot account for base pairings that are far apart [23]. Photo-inducible RNA crosslinking a...
