非编码RNA和RNA沉默

生物体内存在大量的非编码RNA ,它们形态各异 ,功能也千差万别 ,在生物的生长、发育、分化进程中扮演着不同的角色 ,尤其是siRNA ,它是RNA沉默的诱因。RNA沉默是真核生物特有的现象 ,它需要一系列因子的参与 ,其中RNA依赖性的RNA聚合酶是沉默起始的关键 ,Dicer酶是形成siRNA的基础 ,而RNA沉默诱导复合体 (RSIC)等是发生RNA沉默“链式反应”的关键因子     

Noncoding RNA genes

Some genes produce RNAs that are functional instead of encoding proteins. Noncoding RNA genes are surprisingly numerous. Recently, active research areas include small nucleolar RNAs, antisense riboregulator RNAs, and RNAs involved in X-dosage compensation. Genome sequences and new algorithms have begun to make systematic computational screens for noncoding RNA genes possible.     

基因印记与lncRNA

基因印记是一种表观遗传调控机制,在二倍体哺乳动物的发育过程中,基因印记可以调控来自亲代的等位基因差异表达。非编码RNA是不编码蛋白质的RNA,它在RNA水平调控基因表达。研究表明大多数印记基因中存在长非编码RNA（长度>200nt的非编码RNA）的转录,长非编码RNA主要通过顺式的转录干扰作用来实现基因印记。同时基因印记及其相关的长非编码RNA异常表达与许多先天疾病相关,迄今已发现数十种人类遗传疾病与基因印记有关,而lncRNA引起的基因印记在疾病的发生和治疗中起着重要作用。     

长链非编码RNA与表观遗传调控

近年来,表观遗传学(epigenetics)备受关注.表观遗传调控的方式主要包括DNA甲基化、组蛋白修饰和染色质重塑等.ENCODE计划及随后的研究发现,人类基因组中仅有很小一部分DNA序列负责编码蛋白质,而其余大部分被转录为非编码RNA(non-codingRNA,ncRNA).其中长链非编码RNA(long non-codingRNA,lncRNA)是一类长度大于200nt并且缺乏蛋白质编码能力的RNA分子.越来越多的研究表明,lncRNAs能够通过表观遗传调控、转录调控以及转录后调控等多个层面调节基因的表达,从而参与细胞增殖、分化和凋亡等多种生物学过程.本文将着重综述lncRNAs在表观遗传调控中的作用及其最新的研究进展.     

长链非编码RNA研究进展

长链非编码RNA(long noncoding RNAs,lncRNAs)是一类长度超过200nt的非编码RNA分子,通过信号分子、诱饵分子、引导分子、支架分子等4种方式在转录水平和转录后水平调控基因的表达。lncRNAs的表达水平相对于蛋白编码基因较低,但它们在X染色体沉默、基因组印迹、染色体修饰、转录激活、转录干扰以及核内运输等方面具有重要的功能。相对于研究较多的非编码小RNA,lncRNAs的功能目前尚不完全清楚。该文从lncRNAs的起源、分类、分子机制、功能和进化等方面综述了lncRNAs的研究进展,为进一步探究lncRNAs的功能和作用机制提供依据。     

ALDB: A Domestic-Animal Long Noncoding RNA Database

Background

Long noncoding RNAs (lncRNAs) have attracted significant attention in recent years due to their important roles in many biological processes. Domestic animals constitute a unique resource for understanding the genetic basis of phenotypic variation and are ideal models relevant to diverse areas of biomedical research. With improving sequencing technologies, numerous domestic-animal lncRNAs are now available. Thus, there is an immediate need for a database resource that can assist researchers to store, organize, analyze and visualize domestic-animal lncRNAs.

Results

The domestic-animal lncRNA database, named ALDB, is the first comprehensive database with a focus on the domestic-animal lncRNAs. It currently archives 12,103 pig intergenic lncRNAs (lincRNAs), 8,923 chicken lincRNAs and 8,250 cow lincRNAs. In addition to the annotations of lincRNAs, it offers related data that is not available yet in existing lncRNA databases (lncRNAdb and NONCODE), such as genome-wide expression profiles and animal quantitative trait loci (QTLs) of domestic animals. Moreover, a collection of interfaces and applications, such as the Basic Local Alignment Search Tool (BLAST), the Generic Genome Browser (GBrowse) and flexible search functionalities, are available to help users effectively explore, analyze and download data related to domestic-animal lncRNAs.

Conclusions

ALDB enables the exploration and comparative analysis of lncRNAs in domestic animals. A user-friendly web interface, integrated information and tools make it valuable to researchers in their studies. ALDB is freely available from http://res.xaut.edu.cn/aldb/index.jsp.     

新型非编码小RNA——Piwi-interacting RNA(piRNA)

piRNA(Piwi-interacting RNA)是最近从哺乳动物睾丸组织中发现的一类能与PIWI蛋白质相互作用,且长度分布在26～31nt的新型小分子单链RNA,主要综述piRNA的相关研究进展.     

Transposon-derived Long Noncoding RNA in Plants

转座子是基因组的重要组分, 影响基因组的结构与稳定。长链非编码RNA (lncRNA)在转录及转录后水平调控多个生物学过程。转座子与lncRNA是物种进化的重要驱动力。含有转座子序列的lncRNA在自然界广泛存在。该文对植物lncRNA的发掘策略和功能研究进行概述, 围绕植物转座子来源lncRNA (TE-lncRNA)的分布和功能展开综述, 并对植物TE-lncRNA的调控机制、表观修饰及育种潜势等进行探讨与展望。     

转座子来源的植物长链非编码RNA

转座子是基因组的重要组分, 影响基因组的结构与稳定。长链非编码RNA (lncRNA)在转录及转录后水平调控多个生物学过程。转座子与lncRNA是物种进化的重要驱动力。含有转座子序列的lncRNA在自然界广泛存在。该文对植物lncRNA的发掘策略和功能研究进行概述, 围绕植物转座子来源lncRNA (TE-lncRNA)的分布和功能展开综述, 并对植物TE-lncRNA的调控机制、表观修饰及育种潜势等进行探讨与展望。     

Noncoding RNA: from dark matter to bright star

正The central dogma states that genes encoded in the DNA should be first transcribed into messenger RNA (mRNA) and then translated into functional proteins (Crick, 1970). This dogma has been written in numerous textbooks and learned by myriad students. However, along with the completion of the human genome project in June 2000, an astonishing fact was revealed:only 1.5%of the human genome encodes for proteins (Lander et al., 2001; Venter et al., 2001). This fact