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).     

Probing Xist RNA Structure in Cells Using Targeted Structure-Seq

The long non-coding RNA (lncRNA) Xist is a master regulator of X-chromosome inactivation in mammalian cells. Models for how Xist and other lncRNAs function depend on thermodynamically stable secondary and higher-order structures that RNAs can form in the context of a cell. Probing accessible RNA bases can provide data to build models of RNA conformation that provide insight into RNA function, molecular evolution, and modularity. To study the structure of Xist in cells, we built upon recent advances in RNA secondary structure mapping and modeling to develop Targeted Structure-Seq, which combines chemical probing of RNA structure in cells with target-specific massively parallel sequencing. By enriching for signals from the RNA of interest, Targeted Structure-Seq achieves high coverage of the target RNA with relatively few sequencing reads, thus providing a targeted and scalable approach to analyze RNA conformation in cells. We use this approach to probe the full-length Xist lncRNA to develop new models for functional elements within Xist, including the repeat A element in the 5’-end of Xist. This analysis also identified new structural elements in Xist that are evolutionarily conserved, including a new element proximal to the C repeats that is important for Xist function.     

多特征融合的植物长链非编码RNA的预测

长链非编码RNA(Long non-coding RNA, lncRNA)是一类被定义为转录本的长度大于200 nt、没有蛋白编码能力的RNA转录本。研究表明,lncRNA在调节植物生长发育、表观遗传反应以及各种胁迫反应中起重要作用。但是与人类和动物相比,植物lncRNA的研究仍然处于起步阶段。目前,如何从大量的转录本中准确地挑选出lncRNA仍然是植物lncRNA研究领域的重要问题之一。本文构建了新的植物lncRNA和mRNA数据集,分析了数据集中植物lncRNA的序列及结构特征,提取了序列的k-mer频数信息、二级结构信息、开放阅读框信息以及序列的几何柔性等特征,基于SVM(Support Vector Machine, SVM)算法,用Jackknife检验对植物lncRNA进行了预测,并且计算了各种特征融合后对植物lncRNA预测结果的影响,准确率达到了96.14%。     

一个肝癌相关长链非编码RNA的克隆及序列分析

最近我们利用新一代测序(next generation sequencing,NGS)技术对肝细胞癌(hepatocellular carcinoma,HCC)患者活检标本及正常对照肝组织样品进行高通量RNA测序(RNA-sequencing,RNA-Seq),在肝癌样品中染色体11q13.1区域检测到几个相邻的RNA-Seq信号峰,而在正常对照组织中没有检测到,且该染色体区域目前尚无已知基因登录,提示这几个RNA-Seq峰可能代表一个或多个未知的新基因.以此为线索,证实这几个RNA-Seq峰来自同一个新基因,并克隆了该基因全长序列,在克隆该基因全长序列时,发现该基因编码的RNA存在多种剪接形式,最长的转录本为3 562 bp.将该基因编码的12条代表性RNA转录本序列递交到美国国立生物技术信息中心(National Center for Biotechnology Information,NCBI)的GenBank数据库中,GenBank ID号分别为KC136297~KC136308.该基因编码的RNA没有发现明显的开放阅读框(open reading fragment,ORF),提示该基因可能编码长链非编码RNA(long non-coding RNA,lncRNA).为了探讨该lncRNA基因可能的转录调控机制,我们用生物信息学方法预测了该lncRNA基因潜在启动子区域,发现在其转录起始位点上游-719~-469 bp处有一个潜在的启动子,其中包含7个Sp1、1个STAT5和1个EGR1转录因子结合位点.该lncRNA在肝细胞癌发生发展过程中的作用机制值得进一步深入研究.     

The C-Terminal Domain of SRA1p Has a Fold More Similar to PRP18 than to an RRM and Does Not Directly Bind to the SRA1 RNA STR7 Region

Steroid receptor activator RNA protein (SRA1p) is the translation product of the bi-functional long non-coding RNA steroid receptor activator RNA 1 (SRA1) that is part of the steroid receptor coactivator-1 acetyltransferase complex and is indicated to be an epigenetic regulatory component. Previously, the SRA1p protein was suggested to contain an RNA recognition motif (RRM) domain. We have determined the solution structure of the C-terminal domain of human SRA1p by NMR spectroscopy. Our structure along with sequence comparisons among SRA1p orthologs and against authentic RRM proteins indicates that it is not an RRM domain but rather an all-helical protein with a fold more similar to the PRP18 splicing factor. NMR spectroscopy on the full SRA1p protein suggests that this structure is relevant to the native full-length context. Furthermore, molecular modeling indicates that this fold is well conserved among vertebrates. Amino acid variations in this protein seen across sequenced human genomes, including those in tumor cells, indicate that mutations that disrupt the fold occur vary rarely and highlight that its function is well conserved. SRA1p had previously been suggested to bind to the SRA1 RNA, but NMR spectra of SRA1p in the presence of its 80-nt RNA target suggest otherwise and indicate that this protein must be part of a multi-protein complex in order to recognize its proposed RNA recognition element.     

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。     

Effects of GWAS-Associated Genetic Variants on lncRNAs within IBD and T1D Candidate Loci

Long non-coding RNAs are a new class of non-coding RNAs that are at the crosshairs in many human diseases such as cancers, cardiovascular disorders, inflammatory and autoimmune disease like Inflammatory Bowel Disease (IBD) and Type 1 Diabetes (T1D). Nearly 90% of the phenotype-associated single-nucleotide polymorphisms (SNPs) identified by genome-wide association studies (GWAS) lie outside of the protein coding regions, and map to the non-coding intervals. However, the relationship between phenotype-associated loci and the non-coding regions including the long non-coding RNAs (lncRNAs) is poorly understood. Here, we systemically identified all annotated IBD and T1D loci-associated lncRNAs, and mapped nominally significant GWAS/ImmunoChip SNPs for IBD and T1D within these lncRNAs. Additionally, we identified tissue-specific cis-eQTLs, and strong linkage disequilibrium (LD) signals associated with these SNPs. We explored sequence and structure based attributes of these lncRNAs, and also predicted the structural effects of mapped SNPs within them. We also identified lncRNAs in IBD and T1D that are under recent positive selection. Our analysis identified putative lncRNA secondary structure-disruptive SNPs within and in close proximity (+/−5 kb flanking regions) of IBD and T1D loci-associated candidate genes, suggesting that these RNA conformation-altering polymorphisms might be associated with diseased-phenotype. Disruption of lncRNA secondary structure due to presence of GWAS SNPs provides valuable information that could be potentially useful for future structure-function studies on lncRNAs.     

LncRNA SRA mediates cell migration,invasion, and progression of ovarian cancer via NOTCH signaling and epithelial–mesenchymal transition

Long non-coding RNA (lncRNA) is a newly identified regulator of tumor formation and tumor progression. The function and expression of lncRNAs remain to be fully elucidated, but recent studies have begun to address their importance in human health and disease. The lncRNA, SRA, known as steroid receptor activator, acts as an important modulator of gynecological cancer, and its expression may affect biological functions including proliferation, apoptosis, steroid formation, and muscle development. However, it is still not well known whether SRA is involved in the regulation of ovarian cancer. The present study investigated the molecular function and association between SRA expression and clinicopathological factors. In ovarian cancer cell lines, SRA knockdown and overexpression regulated cell migration, proliferation, and invasion. Both in vivo and in vitro experiments using knockdown and overexpression showed that SRA potently regulated epithelial–mesenchymal transition (EMT) and NOTCH pathway components.Further, clinical data confirmed that SRA was a significant predictor of overall survival (OS) and progression-free survival and patients with ovarian cancer exhibiting high expression of SRA exhibited higher recurrence rates than patients with low SRA expression. In conclusion, the present study indicates that SRA has clinical significance as its expression can predict the prognosis of ovarian cancer patients. High expression of the lncRNA SRA is strongly correlated with recurrence-free survival of ovarian cancer patients.     

长链非编码RNA的微RNA海绵作用与呼吸系统疾病

长链非编码RNA（long non-coding RNAs, lncRNAs）是一类由长度大于200个核苷酸组成的长链非编码序列。lncRNAs具有较长的序列,使得lncRNAs具有复杂的二级及三级结构,这也是lncRNAs结合DNA、RNA和蛋白质及其行使复杂功能的结构基础。MicroRNA（miRNAs)是长度在19到25个核苷酸之间的非编码单链RNA分子,是目前研究最多的小分子非编码RNA。而lncRNAs通过结合或者螯合miRNA来调节miRNA丰度,发挥lncRNA的“海绵”作用,从而调控一系列的病理生理过程。lncRNAs及miRNA在呼吸系统疾病的发生、发展、治疗和预后起重要作用。本文就lncRNAs及其“海绵”作用对呼吸系统疾病的影响及可能的机制进行综述。