Splicing of a circular yeast pre-mRNA in vitro

Circular RNA 0001073 Attenuates Malignant Biological Behaviours in Breast Cancer Cell and Is Delivered by Nanoparticles to Inhibit Mice Tumour Growth

Background

Circular RNAs (circRNAs) are a special class of noncoding RNAs that are involved in gene regulation and compete with mRNA for miRNA binding sites. The roles of circRNAs in cancer, especially breast cancer (BC), are poorly understood.

Materials and Methods

The expression levels of circRNA 0001073 (circ-1073) in BC cells (BCCs) and tissues and peritumoural tissues were detected by real-time quantitative reverse transcription-polymerase chain reaction. Kaplan–Meier analysis and receiver operating characteristic curves were used to evaluate relapse-free survival (RFS) and the diagnostic value of circ-1073 for BC, respectively. The biological functions of circ-1073 were determined by cell counting kit-8 assays, colony formation assays, flow cytometry, wound-healing assays, transwell assays, and xenograft model studies. RNA immunoprecipitation assays were conducted to identify the connection between circ-1073 and human antigen R (HuR).

Results

Low circ-1073 expression was discovered in BCCs and BC tissues compared with normal mammary epithelial cells and peritumoural tissues, respectively. Circ-1073 downregulation was significantly associated with an unfavourable prognosis, including a shorter RFS, in BC patients. Circ-1073 is a valuable diagnostic biomarker for BC. Circ-1073 overexpression significantly inhibited BCC proliferation and induced apoptosis by increasing Cleaved Caspase-3/9 levels. Moreover, circ-1073 upregulation significantly suppressed cell mobility and epithelial–mesenchymal transition. Notably, xenograft tumour growth was inhibited by the intratumoural injection of nanoparticles containing the circ-1073 plasmid or by circ-1073 overexpression, and this inhibition was accompanied by HuR upregulation.

Conclusion

Circ-1073 functions as a tumour suppressor in BC, suggesting its potential as a novel therapeutic target in BC.

A cis-acting A-U sequence element induces kinetoplastid U-insertions

A 34-nucleotide A-U sequence located immediately upstream of the editing sites of the Leishmania tarentolae cytochrome b mRNA induces a mitochondrial extract to insert U nucleotides independent of guide RNA. Insertions are localized to positions immediately 5' and 3' of the A-U sequence. When placed within an unedited mammalian transcript, the A-U sequence is sufficient to induce U-insertions. The sequence has a high degree of similarity with the templating nucleotides of a cytochrome b guide RNA and with a sequence adjacent to the editing sites in ND7 mRNA, the other characterized kinetoplastid mRNA supporting guide RNA-independent U-insertions. At least one protein specifically interacts with the A-U sequence. The reaction is consistent with a mechanism proposed for guide RNA-directed editing.

Use of an engineered ribozyme to produce a circular human exon

We report the use of an engineered ribozyme to produce a circular human exon in vitro. Specifically, we have designed a derivative of a yeast self-splicing group II intron that is able to catalyze the formation of a circular exon encoding the first kringle domain (K1) of the human tissue plasminogen activator protein. We show that the circular K1 exon is formed with high fidelity in vitro. Furthermore, the system is designed such that the circular exon that is produced consists entirely of human exon sequence. Thus, our results demonstrate that all yeast exon sequences are dispensable for group II intron catalyzed inverse splicing. This is the first demonstration that an engineered ribozyme can be used to create a circular exon containing only human sequences, linked together at a precise desired ligation point. We expect these results to be generalizable, so that similar ribozymes can be designed to precisely create circular derivatives of any nucleotide sequence.

Exon skipping and circular RNA formation in transcripts of the human cytochrome P-450 2C18 gene in epidermis and of the rat androgen binding protein gene in testis

The cytochrome P-450 2C18 gene was found by reverse transcription-PCR to represent the most abundantly expressed gene of the P-450 2C subfamily in human epidermis. However, in addition to the canonical mRNA of nine exons, transcripts that have skipped exon 4 or 5, exons 4, 5, and 6, or exons 4, 5, 6, and 7 were also identified in this tissue. Remarkably, circular RNA transcripts synthesized by the joining of the donor and acceptor splice sites of the same exon were detected in human epidermis for exons 4 and 5. Moreover, molecules composed of exons 4, 5, and 6 with the donor splice site of exon 6 joined to the acceptor splice site of exon 4 or composed of exons 4, 5, 6, and 7 with the donor splice site of exon 7 joined to the acceptor splice site of exon 4 were also found to be present in this tissue. In rat testis, a similar analysis allowed the detection of a circular RNA molecule composed of exons 6 and 7 of the androgen binding protein (ABP) gene, with the donor splice site of exon 7 joined to the acceptor splice site of exon 6, and of an ABP mRNA which had skipped exons 6 and 7. These results apparently substantiate the hypothesis that alternative pre-mRNA splicing has the potential to generate not only mRNAs that lack one or more exons but also circular RNA molecules that are composed of the exons that are skipped. However, additional 2C18 circular species containing various combinations of exons were also detected in human epidermis, and an exon 6-skipped ABP mRNA molecule was identified in rat testis. This observation is interpreted as indicative that at low frequency, numerous circular RNA formation and exon skipping events may occur, allowing the joining of a variety of different combinations of exons. Moreover, the relative stability of these molecules is apparently the key factor that determines the relative ease of their detection.

Inverse splicing of a discontinuous pre-mRNA intron generates a circular exon in a HeLa cell nuclear extract

We have recently reported the first example of inverse splicing of a eukaryotic pre-mRNA intron using a whole cell extract from the yeast Saccharomyces cerevisiae. The concomitant circularization of the exon in the course of this splicing reaction gave rise to the hypothesis that the circular RNA species, which had been recently discovered in vivo in mammalian cells, were generated by inverse splicing. Here we report the formation of a circular exon in HeLa cell nuclear extracts by an inverse splicing reaction of the second intron of the human beta-globin gene from a pre-mRNA transcript in which the two intron halves flanked an artificially fused, single exon. Our data demonstrate that the mammalian pre-mRNA splicing system has indeed an intrinsic capability of aligning splice sites in reverse order and that this alignment can be followed by a complete splicing reaction, whereby the discontinuous intron sequences are removed. Thus we propose that circular exons in vivo arise as a result of an inverse splicing reaction following the pairing of a 5' splice site with an upstream 3' splice site and that the frequency of this event is influenced by the presence and strength of other, competing splice sites.

Circular RNAs from transcripts of the rat cytochrome P450 2C24 gene: correlation with exon skipping

The cytochrome P450 2C24 gene is characterized by the capability to generate, in rat kidney, a transcript containing exons 2 and 4 spliced at correct sites but having the donor site of exon 4 directly joined to the acceptor site of exon 2 (exon scrambling). By reverse transcriptase-PCR analysis, it is now shown that the only exons present in the scrambled transcript are exons 2, 3, and 4 and that this molecule lacks a poly(A)+ tail. Furthermore, the use of PCR primers in both orientations of either exon 2 or exon 4 revealed that the orders of the exons in the scrambled transcript are 2-3-4-2 and 4-2-3-4, respectively. These results, combined with the observation that P450 2C24 is a single-copy gene, with no duplication of the exon 2 to exon 4 segment, suggest that the scrambled transcript has properties consistent with that of a circular molecule. In line with this is the observation of an increased resistance of the transcript to phosphodiesterase I, a 3'-exonuclease. Moreover, an alternatively processed cytochrome P450 2C24 mRNA, lacking the three scrambled exons and having exon 1 directly joined to exon 5, has been identified in kidney and liver, tissues that express the scrambled transcript. This complete identity of the exons that are absent in the alternatively processed mRNA but present in the scrambled transcript is interpreted as indicative of the possibility that exon scrambling and exon skipping might be interrelated phenomena. It is therefore proposed that alternative pre-mRNA processing has the potential to generate not only mRNAs lacking one or more exons but also circular RNA molecules.

Pre-mRNA topology is important for 3'-end formation in Saccharomyces cerevisiae and mammals

Various signal motifs that are required for efficient pre-mRNA 3'-end formation in the yeast Saccharomyces cerevisiae have been reported. None of these known signal sequences appears to be of the same general importance as is the mammalian AAUAAA motif. To establish the importance of yeast pre-mRNA termini in 3'-end formation, the ends of a pre-mRNA transcript synthesized in vitro were ligated before incubation in a yeast whole-cell extract. Such covalently closed circular RNAs were not cleaved at their poly(A) sites. Interestingly, pseudocircular RNAs with complementary 3'- and 5'-terminal sequences allowing the formation of panhandle structures were also resistant to cleavage. However, 3'-end processing was impeded neither by terminal hairpins at either or at both ends nor by RNA oligonucleotides complementary to either or both ends of a linear pre-mRNA. Intriguingly mammalian pseudocircular pre-mRNAs also were not cleaved at their poly(A) sites when incubated in a HeLa cell nuclear extract. These results provide evidence for the general importance of RNA topology in the formation of an active 3'-end processing complex in S. cerevisiae and higher eukaryotes. The possibility of a torus-shaped factor involved in 3'-end formation is discussed.

In vitro generation of a circular exon from a linear pre-mRNA transcript

Recent findings have firmly established the existence of circular exons in vivo. We were interested in the possible splicing mechanism by which these unusual mRNA molecules could be created in vitro, though no biological relevance has been attached to their existence as yet. In this report we demonstrate that a modified synthetic linear yeast ACT1 transcript whose sequence begins with the 3'-part of its original intron, is continued by 247 nt of exon sequence and terminates with the 5'-part of its intron will generate a circular exon when introduced to standard in vitro splicing reactions in whole cell splice extracts from Saccharomyces cerevisiae. The formation of a circular exon was found to be independent of specific circular or secondary structures of the pre-mRNA transcript. We hypothesize that circular exons which are found in vivo may be generated from pre-mRNAs which derive from rare events of transcription initiation within an intron.

During in vivo maturation of eukaryotic nuclear mRNA, splicing yields excised exon circles

Circular splicing has already been described on nuclear pre-mRNA for certain splice sites far apart in the multi exonic ETS-1 gene and in the single 1.2 kb exon of the Sry locus. To date, it is unclear how splice site juxtaposition occurs in normal and circular splicing. The splice site selection of an internal exon is likely to involve pairing between splice sites across that exon. Based on this, we predict that, albeit at low frequency, internal exons yield circular RNA by splicing as an error-prone mechanism of exon juxtaposition or, perhaps more interestingly, as a regulated mechanism on alternative exons. To address this question, the circular exon formation was analyzed at three ETS-1 internal exons (one alternative spliced exon and two constitutive), in human cell line and blood cell samples. Here, we show by RT-PCR and sequencing that exon circular splicing occurs at the three individual exons that we examined. RNase protection experiments suggest that there is no correlation between exon circle expression and exon skipping.