Simple statistical models predict C-to-U edited sites in plant mitochondrial RNA

Background  

RNA editing is the process whereby an RNA sequence is modified from the sequence of the corresponding DNA template. In the mitochondria of land plants, some cytidines are converted to uridines before translation. Despite substantial study, the molecular biological mechanism by which C-to-U RNA editing proceeds remains relatively obscure, although several experimental studies have implicated a role for cis-recognition. A highly non-random distribution of nucleotides is observed in the immediate vicinity of edited sites (within 20 nucleotides 5' and 3'), but no precise consensus motif has been identified.     

人A-to-I RNA编辑事件对外显子剪接增强子潜在影响的生物信息学分析

目的:研究人A-to-I RNA编辑事件对外显子剪接增强子(ESE)的潜在影响。方法:搜集文献报道的人A-to-I RNA编辑位点,并筛选包含有A-to-I RNA编辑位点的ESE,分析人A-to-I RNA编辑前后单碱基变化对ESE的潜在影响。结果:3640个A-to-I RNA编辑位点可能使其所在的ESE功能发生潜在改变;A-to-I RNA编辑事件对不同类型ESE的潜在影响不同。结论:A-to-I RNA编辑事件可能潜在影响ESE的功能,对ESE的潜在影响为量的调节,而非质的改变。     

Arabidopsis thaliana endonuclease V is a ribonuclease specific for inosine-containing single-stranded RNA

Endonuclease V is highly conserved, both structurally and functionally, from bacteria to humans, and it cleaves the deoxyinosine-containing double-stranded DNA in Escherichia coli, whereas in Homo sapiens it catalyses the inosine-containing single-stranded RNA. Thus, deoxyinosine and inosine are unexpectedly produced by the deamination reactions of adenine in DNA and RNA, respectively. Moreover, adenosine-to-inosine (A-to-I) RNA editing is carried out by adenosine deaminase acting on dsRNA (ADARs). We focused on Arabidopsis thaliana endonuclease V (AtEndoV) activity exhibiting variations in DNA or RNA substrate specificities. Since no ADAR was observed for A-to-I editing in A. thaliana, the possibility of inosine generation by A-to-I editing can be ruled out. Purified AtEndoV protein cleaved the second and third phosphodiester bonds, 3′ to inosine in single-strand RNA, at a low reaction temperature of 20–25°C, whereas the AtEndoV (Y100A) protein bearing a mutation in substrate recognition sites did not cleave these bonds. Furthermore, AtEndoV, similar to human EndoV, prefers RNA substrates over DNA substrates, and it could not cleave the inosine-containing double-stranded RNA. Thus, we propose the possibility that AtEndoV functions as an RNA substrate containing inosine induced by RNA damage, and not by A-to-I RNA editing in vivo.     

ADAR1介导的RNA编辑在血液肿瘤中的调控作用

RNA编辑是发生于双链RNA（dsRNA）上的一类重要转录后反应,可通过碱基插入、缺失或替换的方式改变RNA的核苷酸序列从而丰富转录组和蛋白质组水平的多样性。哺乳动物中最常见的RNA编辑是ADAR家族介导的腺嘌呤-次黄嘌呤编辑（A-to-I）,其在碱基配对过程中被识别为鸟嘌呤。人类转录组中已报道了数百万个A-to-I编辑位点,而ADAR1是最主要的催化酶。在血液肿瘤中,ADAR1的失调将直接影响基因编码区、非编码区和miRNA前体的A-to-I编辑状态,从而导致一系列分子事件改变,如蛋白质编码序列改变、内含子滞留、选择性剪接和miRNA生物发生受抑制。近年来研究发现,异常的RNA编辑导致分子调控网络的紊乱,促进细胞增殖、凋亡受阻和细胞耐药,是白血病干细胞（LSCs）生成和干性维持的重要因素。目前,以RNA编辑为靶点的新药（如rebecsinib）已经在动物实验中取得良好疗效。有别于传统抗肿瘤药,表观遗传抗肿瘤药有望克服血液肿瘤的耐药、复发难题,为患者提供全新治疗选择。本综述总结了ADAR1介导的RNA编辑在血液肿瘤中的作用机制及其生物学功能研究的进展,并探讨了其在药物研发和临床应用中的价值。     

Identification of the chloroplast adenosine-to-inosine tRNA editing enzyme

Plastids (chloroplasts) of higher plants exhibit two types of conversional RNA editing: cytidine-to-uridine editing in mRNAs and adenosine-to-inosine editing in at least one plastid genome-encoded tRNA, the tRNA-Arg(ACG). The enzymes catalyzing RNA editing reactions in plastids are unknown. Here we report the identification of the A-to-I tRNA editing enzyme from chloroplasts of the model plant Arabidopsis thaliana. The protein (AtTadA) has an unusual structure in that it harbors a large N-terminal domain of >1000 amino acids, which is not required for catalytic activity. The C-terminal region of the protein displays sequence similarity to tadA, the tRNA adenosine deaminase from Escherichia coli. We show that AtTadA is imported into chloroplasts in vivo and demonstrate that the in vitro translated protein triggers A-to-I editing in the anticodon of the plastid tRNA-Arg(ACG). Suppression of AtTadA gene expression in transgenic Arabidopsis plants by RNAi results in reduced A-to-I editing in the chloroplast tRNA-Arg(ACG). The RNAi lines display a mild growth phenotype, presumably due to reduced chloroplast translational efficiency upon limited availability of edited tRNA-Arg(ACG).