利用RIP-Seq技术鉴定HepG2细胞中与HuR蛋白结合的lncRNAs

长链非编码RNAs（long noncoding RNAs, lncRNAs）可在表观遗传水平、转录水平和转录后水平调节基因的表达,对细胞功能起着重要的调节作用。RNA结合蛋白可与很多的RNA结合,并在转录后水平发挥重要的调节作用。然而,RNA结合蛋白是否可以在细胞内广泛结合lncRNAs对其发挥调节作用,仍需进一步证实。本研究通过RNA结合蛋白免疫沉淀技术联合高通量测序（RNA binding protein immunoprecipitation-high throughput sequencing, RIP-Seq）的方法在人肝癌细胞株HepG2中,鉴定与人抗原R（human antigen R, HuR）蛋白相结合的lncRNA分子,并进行了初步的验证。首先,通过HuR-RIP实验分离与HuR蛋白结合的RNA分子,然后高通量测序及生物信息学分析。根据分析结果,鉴定出HepG2细胞中361条与HuR蛋白结合的lncRNAs分子,包括基因间lncRNA（large intergenic noncoding RNA, LincRNA）、内含子lncRNA、与编码基因正义链有重叠的lncRNA和与编码基因反义链有重叠lncRNA（antisense lncRNA）等。并进一步通过RIP-qPCR技术,对其中20条LincRNA分子进行了定量检测,验证测序结果。在HepG2细胞中敲低HuR基因表达,发现这些LincRNA分子中,11条LincRNA分子表达水平显著降低（P＜0.05）,2条LincRNA显著升高（P＜0.05）,剩余7条LincRNA表达量未发生变化（P＞0.05）。本研究结果说明,HuR在细胞内可以广泛结合lncRNA分子,并且可能对结合的lncRNA分子的表达量产生影响,这也为进一步研究这些lncRNA的功能和HuR调控网络的研究提供了基础。     

Ultra-deep next generation mitochondrial genome sequencing reveals widespread heteroplasmy in Chinese hamster ovary cells

Recent sequencing of the Chinese hamster ovary (CHO) cell and Chinese hamster genomes has dramatically advanced our ability to understand the biology of these mammalian cell factories. In this study, we focus on the powerhouse of the CHO cell, the mitochondrion. Utilizing a high-resolution next generation sequencing approach we sequenced the Chinese hamster mitochondrial genome for the first time and surveyed the mutational landscape of CHO cell mitochondrial DNA (mtDNA). Depths of coverage ranging from ~3,319X to 8,056X enabled accurate identification of low frequency mutations (>1%), revealing that mtDNA heteroplasmy is widespread in CHO cells. A total of 197 variants at 130 individual nucleotide positions were identified across a panel of 22 cell lines with 81% of variants occurring at an allele frequency of between 1% and 99%. 89% of the heteroplasmic mutations identified were cell line specific with the majority of shared heteroplasmic SNPs and INDELs detected in clones from 2 cell line development projects originating from the same host cell line. The frequency of common predicted loss of function mutations varied significantly amongst the clones indicating that heteroplasmic mtDNA variation could lead to a continuous range of phenotypes and play a role in cell to cell, production run to production run and indeed clone to clone variation in CHO cell metabolism. Experiments that integrate mtDNA sequencing with metabolic flux analysis and metabolomics have the potential to improve cell line selection and enhance CHO cell metabolic phenotypes for biopharmaceutical manufacturing through rational mitochondrial genome engineering.     

lncRNAs功能注释和预测

随着测序技术的发展,在各种哺乳动物中发现越来越多的长非编码RNAs（long non-coding RNAs,lncRNAs）,但是大部分lncRNAs的功能却未知.鉴于lncRNAs在众多生物过程如免疫反应、发育和基因印迹中表现出对蛋白编码基因和其它非编码RNAs的重要调节作用,对lncRNAs的功能研究也成为生物学家和生物信息学家研究的热点. 其中,功能注释和预测是目前研究lncRNAs功能的主要方法之一.本文主要对lncRNAs功能注释和预测方法的研究进展作一综述,包括以下几个方面：基于共表达网络的方法、基于miRNAs的方法、基于蛋白质结合的方法、基于表观遗传修饰的方法以及基于ceRNA网络的方法. 为进一步研究lncRNAs的功能提供参考,同时为开发更加有效的注释或预测方法提供线索.     

基因组印记中的长非编码RNA

长非编码RNA(lnc RNA)是长度大于200 bp的一类非编码蛋白的RNA,因其在基因组中含量巨大以及重要的生物学功能引起了学术界的广泛关注.基因组印记是一种表观遗传现象,lnc RNAs通过建立靶基因的印记而发挥重要的生物功能.基因组印记可以用来研究lnc RNAs在转录和转录后水平调控基因表达的分子机制.本文选取6个印记机制研究比较透彻的印记区域,包括Kcnq1/Cdkn1c、Igf2r/Airn、Prader-Willi(PWS)/Angelman(AS)、Snurf/Snrpn、Dlk1-Dio3和H19/Igf2.通过介绍包括基因间lnc RNAs(H19、Ipw和Meg3)、反义lnc RNAs(Kcnq1ot1、Airn、Ube3a-ATS)和增强子lnc RNAs(IG-DMR e RNAs)在内的3种类型lnc RNAs在印记调控中的作用,从而了解lnc RNAs通过顺式或(/和)反式作用多种机制调控亲本特异性靶基因的表达.了解印记基因簇中lnc RNAs的作用方式将有助于我们揭示lnc RNAs在整个基因组中的作用机制.     

Long non-coding RNA Databases in Cardiovascular Research

With the rising interest in the regulatory functions of long non-coding RNAs (lncRNAs) in complex human diseases such as cardiovascular diseases, there is an increasing need in public databases offering comprehensive and integrative data for all aspects of these versatile molecules. Recently, a variety of public data repositories that specialized in lncRNAs have been developed, which make use of huge high-throughput data particularly from next-generation sequencing (NGS) approaches. Here, we provide an overview of current lncRNA databases covering basic and functional annotation, lncRNA expression and regulation, interactions with other biomole-cules, and genomic variants influencing the structure and function of lncRNAs. The prominent lncRNA antisense noncoding RNA in the INK4 locus (ANRIL), which has been unequivocally associated with coronary artery disease through genome-wide association studies (GWAS), serves as an example to demonstrate the features of each individual database.     

长链非编码RNA(lncRNA)及其在昆虫学研究中的进展

长链非编码RNA（long noncoding RNA, lncRNA）是一类转录本长度超过200 nt的非编码RNA,主要通过转录调控和转录后调控调节基因的表达,也可通过影响蛋白质定位和端粒复制发挥其强大的生物学功能。本文在介绍lncRNA的特征、分类及其主要作用机制的基础上,综述了有关昆虫lncRNA的鉴定及功能研究等方面的最新进展。近5年来已经从黑腹果蝇Drosophila melanogaster、小菜蛾Plutella xylostella和褐飞虱Nilaparvata lugens等8种昆虫中鉴定出了大量lncRNA,为进一步研究lncRNA在昆虫生长发育过程中的功能奠定了重要基础。非编码RNA参与调控害虫抗药性的分子机制已经成为昆虫毒理学研究的一个新兴领域,因此本文对有关lncRNA与害虫抗药性关系的最新研究进展也做了介绍。