Project description:We performed irCLASH and HiCLIP for ADAR1-3 in HEK293 cells. In addition, we performed mRNA-seq in ADAR1-3 overexpressed HEK293 cells and control HEK293 cells
Project description:We performed irCLASH and HiCLIP for ADAR1-3 in HEK293 cells. In addition, we performed mRNA-seq in ADAR1-3 overexpressed HEK293 cells and control HEK293 cells
Project description:Cellular RNAs containing double-stranded RNA (dsRNA) structures are subject to A-to-I RNA editing by the adenosine deaminases that act on RNA (ADARs). While A-to-I editing can alter mRNA coding potential, most editing is observed in non-coding sequences, the function of which remains poorly characterized. To correlate small RNA population with expression patterns of ADARs and hyperedited RNAs (editing-enriched regions: EERs) defined and characterized in a separate RNAseq analysis, we re-analyzed existing smallRNAseq datasets of a wildtype strain and a strain lacking ADARs (adr-1;adr-2). Analysis of primary siRNAs from mixed-stage worms revealed that ADARs impact siRNA biogenesis from EERs. We then analyzed primary and secondary RNAs mapping to EERs from embryo-stage or L4-stage worms and observed that ADAR effects on siRNA levels are dependent on developmental stage.
Project description:Circular RNAs (circRNAs) are produced by head-to-tail back-splicing which is mainly facilitated by base-pairing of reverse complementary matches (RCMs) in circRNA flanking introns. Adenosine deaminases acting on RNA (ADARs) are known to bind double-stranded RNAs for adenosine to inosine (A-to-I) RNA editing. Here we characterize ADARs as potent regulators of circular transcriptome by identifying over a thousand of circRNAs regulated by ADARs in a bidirectional manner through and beyond their editing function. We found that editing can stabilize or destabilize secondary structures formed between RCMs via correcting A:C mismatches to I(G)-C pairs or creating I(G).U wobble pairs, respectively. We provided experimental evidence that editing also favors the binding of RNA-binding proteins such as PTBP1 to regulate back-splicing. These ADARs-regulated circRNAs which are ubiquitously expressed in multiple types of cancers, demonstrate high functional relevance to cancer. Our findings support a hitherto unappreciated bidirectional regulation of circular transcriptome by ADARs and highlights the complexity of cross-talk in RNA processing and its contributions to tumorigenesis.
Project description:Adenosine deaminases that act on RNA (ADARs) are RNA editing enzymes that convert adenosine to inosine in double-stranded RNA (dsRNA). To evaluate effects of ADARs on small RNAs that derive from dsRNA precursors, we performed deep-sequencing, comparing small RNAs from wildtype and ADAR mutant C. elegans. While editing in small RNAs was rare, at least 40% of microRNAs had altered levels in at least one ADAR mutant strain, and miRNAs with significantly altered levels had mRNA targets with correspondingly affected levels. About 40% of siRNAs derived from endogenous genes (endo-siRNAs) also had altered levels in at least one mutant strain, including 63% of Dicer-dependent endo-siRNAs. The 26G class of endo-siRNAs was significantly affected by ADARs, and many altered 26G loci had intronic reads, and histone modifications associated with transcriptional silencing. Our data indicate ADARs, through both direct and indirect mechanisms, are important for maintaining wildtype levels of many small RNAs in C. elegans.
Project description:Adenosine deaminases that act on RNA (ADARs) catalyze the conversion of adenosine to inosine in dsRNA. C. elegans ADARs, ADR-1 and ADR-2, promote the expression of genes containing dsRNA structures by preventing their processing into siRNAs and silencing by RNAi. The 26G endogenous siRNA (endo-siRNA) pathway generates a subset of siRNAs distinct from those made in adr-1;adr-2 mutants, but using many of the same factors. We found that adr-1;adr-2;rrf-3 mutants, lacking both ADARs and the RNA-dependent RNA polymerase RRF-3 required for the 26G pathway, display a bursting phenotype rescued by the RNAi factors RDE-1 and RDE-4. To determine what gene expression changes underlie the synthetic phenotype of adr-1;adr-2;rrf-3 mutants, we sequenced poly(A)+ RNA from adr-1;adr-2;rrf-3 embryos, their parent strains, and strains rescued with mutations in rde-1 and rde-4. We found that genes associated with edited structures were robustly downregulated in adr-1;adr-2;rrf-3 mutants in a manner partially dependent on rde-1 and rde-4. Additionally, genes induced during Orsay virus infections were induced in rrf-3 mutants and further upregulated in adr-1;adr-2;rrf-3 mutants, again dependent in part on rde-1 and rde-4.