miRNA研究方法进展

miRNA（microRNA）是一类长约22个核苷酸的小分子非编码RNA。miRNA可以通过与靶基因mRNA的特定位点结合,抑制该蛋白的合成或诱导该mRNA的降解,从而参与基因的表达调控。miRNA在各种生物中普遍存在,近年来利用直接克隆和生物信息学方法已从动物、植物、培养细胞和病毒中克隆及预测了数百种miRNA,并通过正反向遗传学技术、碱基互补靶标基因鉴定技术等,确定了少数miRNA基因的生理功能：然而在不同生物中仍有大量的miRNA基因尚未鉴定,它们的靶标及功能也有待进一步探索。由于miRNA序列短小,而且与靶标互作机理所知甚少,因此研究难度较大。本文总结了miRNA基因鉴定、功能鉴定等所采用的研究方法和策略,试图为miRNA研究提供一些思路和启发。     

昆虫microRNA的研究进展

MicroRNA (miRNA)是20世纪90年代发现的一类由内源基因编码的长度约21~24 nt的非编码单链RNA分子, 广泛存在于真核生物中, 对基因的转录后调控起着非常重要的作用。本文简要介绍了miRNA的产生与调控机制, 同时从昆虫miRNA的发现鉴定、 靶基因预测与功能验证, 昆虫miRNA的序列特征与进化, 果蝇和非果蝇类昆虫miRNA生物学功能以及供昆虫miRNA研究的网络平台等方面对昆虫miRNA的最新进展进行了综述, 旨在为进一步研究昆虫miRNA提供借鉴和参考。对昆虫miRNA的研究表明其参与调控细胞分化、 增殖及凋亡、 胚胎发育、 器官发生、 形态构建、 生理代谢、 环境协调、 行为认知、 免疫防御等几乎所有的生物过程。因此, 深入研究其生物功能、 调控网络和开发应用等可能成为今后一段时间昆虫miRNA研究的重要内容。     

miRNA调控昆虫与病毒互作的研究进展

miRNA是一类重要的非编码小分子RNA,可在转录后水平调控基因表达,参与并调控机体的生长发育、细胞分化、细胞凋亡、抗病毒、激素分泌、神经系统等重要生物过程。本文介绍了miRNA的合成途径及其生物学功能,并重点阐述miRNA在昆虫宿主与病毒互作中的调控作用:通过mRNA剪切或抑制靶标蛋白的翻译负调控靶标基因,实现基因沉默,调控约50%的蛋白质编码基因的表达,许多miRNA已被发现在人体和植物中参与调控病毒的复制侵染,因此也有可能控制害虫对病毒抗性的产生,恢复病毒对害虫的防控作用。最近有研究将害虫特异的miRNA转入植物,干扰昆虫蜕皮过程导致幼虫的死亡,作为Bt转基因作物的替代,成为抗虫基因工程的新选择。研究miRNA在昆虫对病毒抗性产生中的作用,将为昆虫抗病毒机制的研究提供新的思路,为害虫生物防治措施的应用及改进提供理论参考。     

miRNA体内作用靶标鉴定的策略

miRNAs是一类重要的基因表达调节因子,近年的研究表明miRNA在控制细胞的生长发育、分化、凋亡等过程中发挥着十分重要的作用。但对miRNA作用机制和分子功能的研究却进展缓慢,归其原因是miRNA和靶标之间非完全配对,缺乏快捷有效的靶标鉴定方法。因此,就miRNA靶标鉴定的策略作一综述。miRNA调节靶标的鉴定有助于揭示一些疾病的致病机理,发现可用于治疗的新分子靶标,为基因治疗奠定基础。     

动物 microRNA 靶基因的筛选与鉴定研究进展

miRNA（microRNA）是一类在生物体内广泛存在的长度约22nt的小分子非编码RNA,其在转录后水平调控靶基因的表达,在生物体生长发育过程中起重要的调控作用。近年来,miRNA的功能研究越来越受到人们的重视,而miRNA功能研究的关键在于其调控靶基因的确定。miRNA主要作用于靶基因mRNA的3’UTR区的结合位点．但由于miRNA和靶基因的作用位点并不完全匹配,没有明显的规律可寻,导致应用传统方法鉴定靶基因十分困难。近年来,人们开发了各种特异的、灵敏度高的高通量miRNA靶基因筛选与鉴定方法,极大地促进了miRNA的功能研究。     

MicroRNA与肺癌发生、诊断及治疗

微小RNA(miRNAs)是一大类小的非编码RNA,它通过与靶mRNA 3′非翻译区部分互补配对来调节特定基因的表达。近来研究表明,miRNA可作为癌基因或抑癌基因在肺癌发生发展过程中起重要作用。比较癌组织和非癌组织中miRNA表达谱的差异可筛选出部分miRNA分子作为肺癌诊断和预后判断的潜在生物标记。调节具有致癌或抑癌功能的miRNA表达可能成为肺癌治疗新方法,而结合传统放化疗及其敏感性miRNA标志也为肺癌治疗研究提供了新的策略。该文对miRNA在肺癌发生与发展、基因诊断和治疗中的作用做一综述。     

多发性骨髓瘤相关microRNA的研究进展

microRNA(miRNA)是一种内源性非编码的单链小分子RNA,长度约19~24个核苷酸,通过靶向结合mRNA的3′非翻译区域(3′UTR)区域,抑制翻译或者降解靶标mRNA而调节基因的表达.miRNA参与一些重要的生理、病理学过程,包括细胞增殖、分化、生长和凋亡等.大量研究发现,miRNA与多发性骨髓瘤(multiplemyeloma,MM)的发生、发展及诊断治疗等有着密切关系.深入探讨MM相关miRNA的调节机制和功能等,可为MM发病机制的研究及诊治提供新的思路.     

microRNA与肿瘤

microRNA（miRNA）是近年来发现的一类长度为19—25个核苷酸的非编码小分子RNA。它主要通过与靶标基因3’UTR的完全或不完全配对,降解靶标基因mRNA或抑制其翻译,从而参与调控个体发育、细胞凋亡、增殖及分化等生命活动。实验证据表明,miRNA可通过调控其靶标基因参与的信号通路,影响肿瘤的发生和发展,发挥着类似于癌基因或抑癌基因的功能。miRNA的发现为肿瘤发病机制的研究提供了新的思路,为肿瘤诊断和治疗提供了新的策略。本综述主要介绍近年来miRNA与肿瘤发生发展相关性研究领域的进展。     

植物microRNA与逆境响应研究进展

MieroRNA(miRNA)是一类在生物体内普遍存在的非编码、长度约16～29 nt的小分子RNA,由内源基因编码,于转录后水平通过介导靶mRNA降解或翻译抑制调控基因表达,是真核细胞基因表达的重要调控因子.随着生物信息学与研究技术的发展,越来越多的植物miRNA得到预测和验证.逆境胁迫下,植物体诱导或下调相关miRNA表达,参与植物逆境生理调节与适应.文章综述了植物miRNA生物合成、与靶基因的作用方式,生物功能以及逆境胁迫响应miRNA,概要介绍了目前常用的miRNA研究方法.     

miRNAs的表达调控机制

microRNAs(miRNAs)是一类在转录后基因调控中发挥功能的非编码小RNAs,在发育、生长和分化等过程中发挥重要作用.至今已经在动物、植物和微生物等不同生物体中鉴定出来数千种miRNAs. miRNAs可以通过降解mRNA或抑制蛋白翻译的方式调节特异基因表达.生物体内约30%的基因都受miRNAs的调节.miRNAs的表达与功能受到转录因子、表观遗传学、多核苷酸多态性及其RNA编辑等多种因素的调节.此外,特异miRNA基因敲除的成功为研究miRNAs功能提供了有力的实验模型.     

miRTar Hunter: A prediction system for identifying human microRNA target sites

MicroRNAs (miRNAs) are important regulators of gene expression and play crucial roles in many biological processes including apoptosis, differentiation, development, and tumorigenesis. Recent estimates suggest that more than 50% of human protein coding genes may be regulated by miRNAs and that each miRNA may bind to 300–400 target genes. Approximately 1,000 human miRNAs have been identified so far with each having up to hundreds of unique target mRNAs. However, the targets for a majority of these miRNAs have not been identified due to the lack of large-scale experimental detection techniques. Experimental detection of miRNA target sites is a costly and time-consuming process, even though identification of miRNA targets is critical to unraveling their functions in various biological processes. To identify miRNA targets, we developed miRTar Hunter, a novel computational approach for predicting target sites regardless of the presence or absence of a seed match or evolutionary sequence conservation. Our approach is based on a dynamic programming algorithm that incorporates more sequence-specific features and reflects the properties of various types of target sites that determine diverse aspects of complementarities between miRNAs and their targets. We evaluated the performance of our algorithm on 532 known human miRNA:target pairs and 59 experimentally-verified negative miRNA:target pairs, and also compared our method with three popular programs for 481 miRNA:target pairs. miRTar Hunter outperformed three popular existing algorithms in terms of recall and precision, indicating that our unique scheme to quantify the determinants of complementary sites is effective at detecting miRNA targets. miRTar Hunter is now available at http://203.230.194.162/~kbkim.     

昆虫miRNA研究进展

微小RNA(microRNA,miRNA)广泛存在于不同的生物体内,是一类长度为19～24 nt的内源性单链非编码小RNA,主要通过其种子区域与靶基因的开放阅读框(open reading frame,ORF)和3'非翻译区(untranslated region,UTR)进行结合,进而在转录后水平调控基因表达,miR...     

Clustered miRNAs and their role in biological functions and diseases

MicroRNAs (miRNAs) are endogenous, small non‐coding RNAs known to regulate expression of protein‐coding genes. A large proportion of miRNAs are highly conserved, localized as clusters in the genome, transcribed together from physically adjacent miRNAs and show similar expression profiles. Since a single miRNA can target multiple genes and miRNA clusters contain multiple miRNAs, it is important to understand their regulation, effects and various biological functions. Like protein‐coding genes, miRNA clusters are also regulated by genetic and epigenetic events. These clusters can potentially regulate every aspect of cellular function including growth, proliferation, differentiation, development, metabolism, infection, immunity, cell death, organellar biogenesis, messenger signalling, DNA repair and self‐renewal, among others. Dysregulation of miRNA clusters leading to altered biological functions is key to the pathogenesis of many diseases including carcinogenesis. Here, we review recent advances in miRNA cluster research and discuss their regulation and biological functions in pathological conditions.     

MicroRNAs as genetic sculptors: Fishing for clues

microRNAs (miRNAs) encode small RNA molecules of ～22nts in length that regulate the deadenylation, translation, and decay of their target mRNAs. The identification of miRNAs in plants and animals has uncovered a new layer of gene regulation with important implications for development, cellular homeostasis and disease. Because each miRNA is predicted to regulate several hundred genes, a major challenge in the field remains to elucidate the precise roles for each miRNA and to understand the physiological relevance of individual miRNA–target interactions in vivo. Despite the wide variety of biological contexts where miRNAs function, a common theme emerges, whereby miRNAs shape gene expression within both spatial and temporal dimensions by removing messages from previous cellular states as well as modulating the levels of actively transcribed genes. This review will focus on the role that the teleost Danio rerio (zebrafish) has played in shaping our understanding of miRNA function in vertebrates.     

Identification and Characteristics of microRNAs from Army Worm,Spodoptera frugiperda Cell Line Sf21

microRNAs play important regulatory role in all intrinsic cellular functions. Amongst lepidopteran insects, miRNAs from only Bombyx mori have been studied extensively with a little focus on Spodoptera sp. In the present study, we identified a total of 226 miRNAs from Spodoptera frugiperda cell line Sf21. Of the total, 116 miRNAs were well conserved within other insects, like B. mori, Drosophila melanogaster and Tribolium castenum while the remaining 110 miRNAs were identified as novel based on comparative analysis with the insect miRNA data set. Landscape distribution analysis based on Sf21 genome assembly revealed clustering of few novel miRNAs. A total of 5 miRNA clusters were identified and the largest one encodes 5 miRNA genes. In addition, 12 miRNAs were validated using northern blot analysis and putative functional role assignment for 6 Sf miRNAs was investigated by examining their relative abundance at different developmental stages of Spodoptera litura and body parts of 6^th instar larvae. Further, we identified a total of 809 potential target genes with GO terms for selected miRNAs, involved in different metabolic and signalling pathways of the insect. The newly identified miRNAs greatly enrich the repertoire of insect miRNAs and analysis of expression profiles reveal their involvement at various steps of biochemical pathways of the army worm.