Disruption of the OLE ribonucleoprotein complex causes magnesium toxicity in Bacillus halodurans

OLE RNAs represent an unusual class of bacterial noncoding RNAs common in Gram‐positive anaerobes. The OLE RNA of the alkaliphile Bacillus halodurans is highly expressed and naturally interacts with at least two RNA‐binding proteins called OapA and OapB. The phenotypes of the corresponding knockouts include growth inhibition when exposed to ethanol or other short‐chain alcohols or when incubated at modestly reduced temperatures (e.g. 20°C). Intriguingly, the OapA ‘PM1’ mutant, which carries two amino acid changes to a highly conserved region, yields a dominant‐negative phenotype that causes more severe growth defects under these same stress conditions. Herein, we report that the PM1 strain also exhibits extreme sensitivity to elevated Mg²⁺ concentrations, beginning as low as 2 mM. Suppressor mutants predominantly map to genes for aconitate hydratase and isocitrate dehydrogenase, which are expected to alter cellular citrate concentrations. Citrate reduces the severity of the Mg²⁺ toxicity phenotype, but neither the genomic mutations nor the addition of citrate to the medium overcomes ethanol toxicity or temperature sensitivity. These findings reveal that OLE RNA and its protein partners are involved in biochemical responses under several stress conditions, wherein the unusual sensitivity to Mg²⁺ can be independently suppressed by specific genomic mutations.     

Emerging themes in non-coding RNA quality control

Quality control pathways for non-coding RNAs such as tRNAs and rRNAs are widespread. In both prokaryotes and eukaryotes, poly(A) polymerases target aberrant non-coding RNAs for degradation. In yeast, a nuclear complex that includes the poly(A) polymerase Trf4p works together with the exosome in degrading a broad array of non-coding RNAs, several of which are aberrant. Yeast also have additional pathways for the degradation of defective RNAs and other pathways may exist in higher eukaryotes. One possibility is that cells recognize specific, still undiscovered, features common to misfolded RNAs; however, an alternative is that RNA quality control proteins interact with relatively general RNA structures, whereas correctly folded RNAs are sequestered by specific RNA-binding proteins and thus protected from degradation. Recently available structures of protein and ribonucleoprotein complexes involved in non-coding RNA quality control are providing a more detailed understanding of this process.     

小RNA, 大本领: 22 nt siRNAs在植物适应逆境中的重要作用

RNA是传递生命遗传信息的重要介质。依据RNA是否编码蛋白质, 可分为编码RNA和非编码RNA。作为非编码RNA的核心种类之一, 小RNA在各种生命活动中均发挥重要调控作用, 其产生及功能发挥依赖于不同的DCL、RDR和AGO蛋白。目前, 植物中功能和调控方式较为明确的是以21 nt为主的miRNA和24 nt siRNA, 其它长度和类型的小RNA由于积累水平通常较低, 尚知之甚少。近日, 南方科技大学郭红卫团队发现, 拟南芥(Arabidopsis thaliana)在缺氮等逆境胁迫下可产生大量依赖于DCL2和RDR6的22 nt siRNA。22 nt siRNA与AGO1结合形成效应复合物, 抑制硝酸还原酶基因(NIA1和NIA2)等mRNA的翻译效率, 从而减少植物在营养缺失条件下的能量消耗。这意味着, 当植物遇到不利环境时, 虽然无法通过移动来逃避逆境, 但可通过诱导产生小RNA, 协调和平衡正常的生长发育与胁迫响应。     

Non-coding RNAs and the acquisition of genomic imprinting in mammals

Genomic imprinting, representing parent-specific expression of alleles at a locus, is mainly evident in flowering plants and placental mammals. Most imprinted genes, including numerous non-coding RNAs, are located in clusters regulated by imprinting control regions (ICRs). The acquisition and evolution of genomic imprinting is among the most fundamental genetic questions. Discoveries about the transition of mammalian imprinted gene domains from their non-imprinted ancestors, especially recent studies undertaken on the most ancient mammalian clades — the marsupials and monotremes from which model species genomes have recently been sequenced, are of high value. By reviewing and analyzing these studies, a close connection between non-coding RNAs and the acquisition of genomic imprinting in mammals is demonstrated. The evidence comes from two observations accompanied with the acquisition of the imprinting: (i) many novel non-coding RNA genes emerged in imprinted regions; (ii) the expressions of some conserved non-coding RNAs have changed dramatically. Furthermore, a systematical analysis of imprinted snoRNA (small nucleolar RNA) genes from 15 vertebrates suggests that the origination of imprinted snoRNAs occurred after the divergence between eutherians and marsupials, followed by a rapid expansion leading to the fixation of major gene families in the eutherian ancestor prior to the radiation of modern placental mammals. Involved in the regulation of imprinted silencing and mediating the chromatins epigenetic modification may be the major roles that non-coding RNAs play during the acquisition of genomic imprinting in mammals. Supported by National Natural Science Foundation of China (Grant No. 30830066), the Ministry of Education of China and Natural Science Foundation of Guangdong Province (Grant No. IRT0447, NSF-05200303) and National Key Basic Research and Development Program of China (Grant No. 2005CB724600)     

miRNA在植物响应高温胁迫中的研究进展

microRNA(miRNA)是一类由20-24个核苷酸组成的小的非编码RNA,通常通过序列互补降解或抑制其靶标基因转录后的翻译过程,从而在转录后水平上调控基因的表达。miRNA在植物基因组中普遍存在,作为一类重要的调节因子参与到植物的生长发育与逆境响应中。目前,已有研究表明高温除了诱导植物编码基因表达发生改变之外,一些非编码RNA的表达也发生了显著改变,其中miRNA作为重要的非编码RNA,参与了植物的高温胁迫响应。对植物miRNA的合成途径,作用机制以及主要功能进行了扼要阐述,重点阐述了高温胁迫下植物miRNA的作用机制,旨在为mi RNA在植物抵抗高温胁迫中的研究与应用提供新的思路。     

Diversity of endogenous small non-coding RNAs in Oryza sativa

Small non-coding RNAs play important roles in regulating cell functions by controlling mRNA turnover and translational repression in eukaryotic cells. Here we isolated 162 endogenous small RNA molecules from Oryza sativa, which ranged from 16 to 35 nt in length. Further analysis indicated that they represented a diversity of small RNA molecules, including 17 microRNAs (miRNAs), 30 tiny non-coding RNAs (tncRNAs) and 20 repeat-associated small interfering RNAs (rasiRNAs). Among 17 miRNAs, 13 were novel miRNA candidates and their potential targets were important regulatory genes in the rice genome. We also found that a cluster of small RNAs, including many rasiRNAs, matched to a nuclear DNA fragment that evolutionarily derived from chloroplast. These results demonstrate clearly the existence of distinct types of small RNAs in rice and further suggest that small RNAs may control gene regulation through diverse mechanisms.     

Efficient and specific knockdown of small non-coding RNAs in mammalian cells and in mice

Hundreds of small nuclear non-coding RNAs, including small nucleolar RNAs (snoRNAs), have been identified in different organisms, with important implications in regulating gene expression and in human diseases. However, functionalizing these nuclear RNAs in mammalian cells remains challenging, due to methodological difficulties in depleting these RNAs, especially snoRNAs. Here we report a convenient and efficient approach to deplete snoRNA, small Cajal body RNA (scaRNA) and small nuclear RNA in human and mouse cells by conventional transfection of chemically modified antisense oligonucleotides (ASOs) that promote RNaseH-mediated cleavage of target RNAs. The levels of all seven tested snoRNA/scaRNAs and four snRNAs were reduced by 80-95%, accompanied by impaired endogenous functions of the target RNAs. ASO-targeting is highly specific, without affecting expression of the host genes where snoRNAs are embedded in the introns, nor affecting the levels of snoRNA isoforms with high sequence similarities. At least five snoRNAs could be depleted simultaneously. Importantly, snoRNAs could be dramatically depleted in mice by systematic administration of the ASOs. Together, our findings provide a convenient and efficient approach to characterize nuclear non-coding RNAs in mammalian cells, and to develop antisense drugs against disease-causing non-coding RNAs.     

十字花科植物种子低分子RNA提取方法比较

非编码RNA不翻译成蛋白质,它们通过转录、转录后及翻译水平调控靶基因表达,在植物生长发育及逆境胁迫中发挥功能。目前,大量种子萌发期特异表达的非编码RNA (Non-coding RNA)已被发现,高效提取种子低分子RNA是对其进行研究的关键。本研究将介绍一种改良SDS RNA提取方法,并与Trizol、CTAB法、RNA提取试剂盒进行比较。结果表明:这种方法可以高效提取用于Northern blotting、RT-PCR等分子生物学分析的十字花科植物种子低分子RNA。改良SDS RNA提取方法为种子非编码RNA研究、种子萌发生理及分子育种研究提供了帮助。     

ADAR-mediated RNA editing in non-coding RNA sequences

Adenosine to inosine (A-to-I) RNA editing is the most abundant editing event in animals. It converts adenosine to inosine in double-stranded RNA regions through the action of the adenosine deaminase acting on RNA (ADAR) proteins. Editing of pre-mRNA coding regions can alter the protein codon and increase functional diversity. However, most of the A-to-I editing sites occur in the non-coding regions of pre-mRNA or mRNA and non-coding RNAs. Untranslated regions (UTRs) and introns are located in pre-mRNA non-coding regions, thus A-to-I editing can influence gene expression by nuclear retention, degradation, alternative splicing, and translation regulation. Non-coding RNAs such as microRNA (miRNA), small interfering RNA (siRNA) and long non-coding RNA (lncRNA) are related to pre-mRNA splicing, translation, and gene regulation. A-to-I editing could therefore affect the stability, biogenesis, and target recognition of non-coding RNAs. Finally, it may influence the function of non-coding RNAs, resulting in regulation of gene expression. This review focuses on the function of ADAR-mediated RNA editing on mRNA non-coding regions (UTRs and introns) and non-coding RNAs (miRNA, siRNA, and lncRNA).     

miRNAs调控lincRNAs的生物信息学预测与功能分析

基因间长链非编码RNAs(Long intergenic non-coding RNAs, lincRNAs)是位于蛋白编码基因之间的长度超过200 nt的非编码RNAs, 在动物中参与细胞周期调控、免疫监视、胚胎干细胞分化等多种生物学过程, 但是lincRNAs在大多数植物中的功能尚不清楚。MicroRNAs(miRNAs)是真核生物中一类在转录水平和转录后水平介导基因沉默的21 nt左右的内源性单链小非编码RNAs分子, 通过序列互补的方式调控靶标基因的表达。目前miRNAs的靶标研究主要集中于编码蛋白的基因, 而对于靶标为非编码RNAs的研究较少, 尤其在植物中的研究更为少见。为了系统挖掘植物中lincRNAs的功能, 文章整合miRNAs数据、cDNAs数据和降解组数据, 利用生物信息学方法找到拟南芥(Arabidopsis thaliana)337个成熟miRNAs在2708个lincRNAs上的可能结合位点, 构建了miRNAs-mRNAs-lincRNAs调控网络, 并根据竞争性内源(ceRNA)假说预测lincRNAs的功能, 为进一步阐明植物中miRNAs对lincRNAs的调控机制以及lincRNAs的功能奠定了基础。     

Prediction of structured non-coding RNAs in the genomes of the nematodes Caenorhabditis elegans and Caenorhabditis briggsae

We present a survey for non-coding RNAs and other structured RNA motifs in the genomes of Caenorhabditis elegans and Caenorhabditis briggsae using the RNAz program. This approach explicitly evaluates comparative sequence information to detect stabilizing selection acting on RNA secondary structure. We detect 3,672 structured RNA motifs, of which only 678 are known non-translated RNAs (ncRNAs) or clear homologs of known C. elegans ncRNAs. Most of these signals are located in introns or at a distance from known protein-coding genes. With an estimated false positive rate of about 50% and a sensitivity on the order of 50%, we estimate that the nematode genomes contain between 3,000 and 4,000 RNAs with evolutionary conserved secondary structures. Only a small fraction of these belongs to the known RNA classes, including tRNAs, snoRNAs, snRNAs, or microRNAs. A relatively small class of ncRNA candidates is associated with previously observed RNA-specific upstream elements.