Analysis of Intron Sequences Reveals Hallmarks of Circular RNA Biogenesis in Animals

Ivanov, Andranik; Memczak, Sebastian; Wyler, Emanuel; Torti, Francesca; Porath, Hagit T.; Orejuela, Marta Rodriguez; Piechotta, Michael; Levanon, Erez Y.; Landthaler, Markus; Dieterich, Christoph; Rajewsky, Nikolaus

doi:10.1016/j.celrep.2014.12.019

Cited by 884 publications

(930 citation statements)

References 27 publications

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“…Recently, circRNAs were rediscovered and shown to be the products of thousands of loci in eukaryotes, from fly and worm to mouse and human (Jeck et al 2013;Memczak et al 2013;Salzman et al 2013;Guo et al 2014;Westholm et al 2014;Zhang et al 2014;Ivanov et al 2015). Recent research into circRNA biogenesis has shown that backsplicing is catalyzed, though inefficiently (Zhang et al 2016), by the canonical spliceosomal machinery (Ashwal-Fluss et al 2014;Starke et al 2015;Wang and Wang 2015) and modulated by both cis-elements and trans-factors (Ashwal-Fluss et al 2014;Zhang et al 2014;Conn et al 2015;Ivanov et al 2015;Starke et al 2015; for review, see Chen and Yang 2015;Chen 2016). Different from the canonical splicing that joins an upstream 5 ′ splice (donor) site with a downstream 3 ′ splice (acceptor) site in a sequential order to produce a linear RNA, back-splicing occurs in a reversed orientation that links a downstream 5 ′ splice (donor) site to an upstream 3 ′ splice (acceptor) site to yield a circRNA.…”

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Diverse alternative back-splicing and alternative splicing landscape of circular RNAs

Zhang¹,

et al. 2016

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Circular RNAs (circRNAs) derived from back-spliced exons have been widely identified as being co-expressed with their linear counterparts. A single gene locus can produce multiple circRNAs through alternative back-splice site selection and/or alternative splice site selection; however, a detailed map of alternative back-splicing/splicing in circRNAs is lacking. Here, with the upgraded CIRCexplorer2 pipeline, we systematically annotated different types of alternative back-splicing and alternative splicing events in circRNAs from various cell lines. Compared with their linear cognate RNAs, circRNAs exhibited distinct patterns of alternative back-splicing and alternative splicing. Alternative back-splice site selection was correlated with the competition of putative RNA pairs across introns that bracket alternative back-splice sites. In addition, all four basic types of alternative splicing that have been identified in the (linear) mRNA process were found within circRNAs, and many exons were predominantly spliced in circRNAs. Unexpectedly, thousands of previously unannotated exons were detected in circRNAs from the examined cell lines. Although these novel exons had similar splice site strength, they were much less conserved than known exons in sequences. Finally, both alternative back-splicing and circRNA-predominant alternative splicing were highly diverse among the examined cell lines. All of the identified alternative back-splicing and alternative splicing in circRNAs are available in the CIRCpedia database (http://www.picb.ac.cn/rnomics/ circpedia). Collectively, the annotation of alternative back-splicing and alternative splicing in circRNAs provides a valuable resource for depicting the complexity of circRNA biogenesis and for studying the potential functions of circRNAs in different cells.

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Diverse alternative back-splicing and alternative splicing landscape of circular RNAs

Zhang¹,

et al. 2016

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“…65 Nevertheless, (CA) n simple repeats that are complementary over a <30-nt region appear to be sufficient to drive Drosophila Semaphorin-2b circular RNA biogenesis. 37 These data, as well as genomewide analyses 14,40,62,68 and detailed studies on the human EPHB4, 65 GCN1L1, 40,65 HIPK3, 65 LPAR1, 69 and POLR2A 40 circular RNAs, confirm the original Sry circular RNA biogenesis model 48 ( Fig. 2A) and suggest that it is applicable to thousands of eukaryotic genes.…”

Section: Introductionmentioning

confidence: 50%

“…Indeed, one can accurately predict many circular RNAs, especially from highly transcribed genes, by searching for pairs of complementary sequences in the flanking introns. 68 However, the presence of inverted intronic repeats is not sufficient for exon circularization. This is, in part, because of the co-transcriptional nature of splicing, but also because introns commonly contain many repetitive elements that compete for base pairing (Fig.…”

Section: Introductionmentioning

confidence: 99%

“…37 Although very few exons are flanked by repeats as long as those at the mouse Sry locus, most (>70 %) 39 exons that generate circular RNAs in human cells have complementary repeats, usually Alu elements, in their flanking introns. 14,40,68 Circular RNAs in other species, including mice, C. elegans, 68 and Drosophila, 37 are often also flanked by complementary intronic repeats (but not in all cases 25,29 ; see below). As the sequences of these repeats are generally quite different from human Alu elements, backsplicing does not appear to be dependent on the presence of particular sequence motifs (beyond the splice sites).…”

Section: Introductionmentioning

confidence: 99%

“…33,68 This is likely because ADAR activity disrupts base pairing between the intronic repeats, thereby directly preventing circular RNA production.…”

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Circular RNAs: Unexpected outputs of many protein-coding genes

Wilusz

2016

RNA Biology

108

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Pre-mRNAs from thousands of eukaryotic genes can be non-canonically spliced to generate circular RNAs, some of which accumulate to higher levels than their associated linear mRNA. Recent work has revealed widespread mechanisms that dictate whether the spliceosome generates a linear or circular RNA. For most genes, circular RNA biogenesis via backsplicing is far less efficient than canonical splicing, but circular RNAs can accumulate due to their long half-lives. Backsplicing is often initiated when complementary sequences from different introns base pair and bring the intervening splice sites close together. This process is further regulated by the combinatorial action of RNA binding proteins, which allow circular RNAs to be expressed in unique patterns. Some genes do not require complementary sequences to generate RNA circles and instead take advantage of exon skipping events. It is still unclear what most mature circular RNAs do, but future investigations into their functions will be facilitated by recently described methods to modulate circular RNA levels.

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Integrative analysis of Arabidopsis thaliana transcriptomics reveals intuitive splicing mechanism for circular RNA

et al. 2016

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A new regulatory class of small endogenous RNAs called circular RNAs (circRNAs) has been described as miRNA sponges in animals. Using 16 Arabidopsis thaliana RNA-Seq data sets, we identified 803 circRNAs in RNase R-/non-RNase R-treated samples. The results revealed the following features: Canonical and noncanonical splicing can generate circRNAs; chloroplasts are a hotspot for circRNA generation; furthermore, limited complementary sequences exist not only in introns, but also in the sequences flanking splice sites. The latter finding suggests that multiple combinations between complementary sequences may facilitate the formation of the circular structure. Our results contribute to a better understanding of this novel class of plant circRNAs.

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Analysis of Intron Sequences Reveals Hallmarks of Circular RNA Biogenesis in Animals

Cited by 884 publications

References 27 publications

Diverse alternative back-splicing and alternative splicing landscape of circular RNAs

Diverse alternative back-splicing and alternative splicing landscape of circular RNAs

Circular RNAs: Unexpected outputs of many protein-coding genes

Integrative analysis of Arabidopsis thaliana transcriptomics reveals intuitive splicing mechanism for circular RNA

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