Volume: 15, Issue: 3

Perspective

Epitranscriptomics: Toward A Better Understanding of RNA Modifications

Xushen Xiong, Chengqi Yi, Jinying Peng

目前,研究人员已在RNA分子上发现了超过100种转录后修饰,这些转录后修饰对维持生命体的正常生命活动至关重要。绝大部分的修饰都发生在非编码RNA上,过去的研究也都集中在非编码RNA的修饰上。近年来,随着对6-甲基腺嘌呤在全转录组上的定位方法的开发,以及其修饰酶(writer),去修饰酶(eraser)和特异性结合蛋白(reader)的发现,研究人员对信使RNA上该修饰的生物学功能研究取得了很大的进展。除6-甲基腺嘌呤外,研究人员也陆续在信使RNA上鉴定到假尿嘧啶,5-甲基胞嘧啶,5-羟基胞嘧啶,1-甲基腺嘌呤等修饰,并且获得了相应的全转录组修饰谱图。随着在全转录组水平上对修饰的鉴定,定位及生物学功能的研究,一个新的研究领域¬——表观转录组学(epitranscriptomics)逐渐形成。尽管对该领域的研究已经取得一定进展,但是尚有许多未知的问题需要进一步的研究。在本文中,我们从以下6个方面讨论了表观转录组学未来的发展方向以及研究过程中可能会遇到的难点:全转录组RNA修饰测序技术的发展;表观转录组学相关的生物信息工具的开发;修饰酶,去修饰酶,和特异性结合蛋白的鉴定;表观转录组学的数据库的建立;信使RNA上的修饰的生物学功能研究;以及不同的修饰的整合性研究。

Page 147-153

Review Article

The RNA Modification N6-methyladenosine and Its Implications in Human Disease

Pedro J. Batista

Impaired gene regulation lies at the heart of many disorders, including developmental diseases and cancer. Furthermore, the molecular pathways that control gene expression are often the target of cellular parasites, such as viruses. Gene expression is controlled through multiple mechanisms that are coordinated to ensure the proper and timely expression of each gene. Many of these mechanisms target the life cycle of the RNA molecule, from transcription to translation. Recently, another layer of regulation at the RNA level involving RNA modifications has gained renewed interest of the scientific community. The discovery that N6-methyladenosine (m6A), a modification present in mRNAs and long noncoding RNAs, can be removed by the activity of RNA demethylases, launched the field of epitranscriptomics; the study of how RNA function is regulated through the addition or removal of post-transcriptional modifications, similar to strategies used to regulate gene expression at the DNA and protein level. The abundance of RNA post-transcriptional modifications is determined by the activity of writer complexes (methylase) and eraser (RNA demethylase) proteins. Subsequently, the effects of RNA modifications materialize as changes in RNA structure and/or modulation of interactions between the modified RNA and RNA binding proteins or regulatory RNAs. Disruption of these pathways impairs gene expression and cellular function. This review focuses on the links between the RNA modification m6A and its implications in human diseases.
基因表达调控障碍是引起包括发育缺陷、肿瘤等在内的多种疾病的关键因素。而调控基因表达的分子信号通路往往是胞内寄生生物,如病毒等的靶点。基因的表达受到多种机制的共同调控,这些机制协调作用,确保每个基因正确及时的表达。这些机制中很大一部分是通过靶向RNA分子生命周期的转录及翻译的过程来发挥作用。近期,另一层涉及RNA修饰对RNA水平进行调控的新机制重新引起了科学界的兴趣。N6-甲基腺苷(N6-methyladenosine,m6A)修饰存在于信使RNA(mRNAs)和长链非编码RNA(long noncoding RNAs)上,该修饰可被RNA去甲基化酶移除。这一发现开拓了一项新的研究领域——转录组表观遗传学。转录组表观遗传学主要研究RNA转录后修饰如何影响RNA的功能,这与此前研究DNA及蛋白水平调控基因表达的机制类似。RNA转录后修饰水平由“书写器”(RNA甲基化酶)和“擦除器”(RNA去甲基化酶)活性决定。而RNA修饰主要通过改变RNA的结构以及/或调整被修饰RNA与RNA结合蛋白或调节性RNA的相互作用实现其功能。这些信号通路的破坏将会影响基因的表达及细胞的功能。本综述着重介绍RNA修饰m6A与不同人类疾病的关联。

Page 154-163

Review Article

Silencing of Transposable Elements by piRNAs in Drosophila: An Evolutionary Perspective

Shiqi Luo, Jian Lu

Transposable elements (TEs) are DNA sequences that can move within the genome. TEs have greatly shaped the genomes, transcriptomes, and proteomes of the host organisms through a variety of mechanisms. However, TEs generally disrupt genes and destabilize the host genomes, which substantially reduce fitness of the host organisms. Understanding the genomic distribution and evolutionary dynamics of TEs will greatly deepen our understanding of the TE-mediated biological processes. Most TE insertions are highly polymorphic in Drosophila melanogaster, providing us a good system to investigate the evolution of TEs at the population level. Decades of theoretical and experimental studies have well established “transposition-selection” population genetics model, which assumes that the equilibrium between TE replication and purifying selection determines the copy number of TEs in the genome. In the last decade, P-element-induced wimpy testis (PIWI)-interacting RNAs (piRNAs) were demonstrated to be master repressors of TE activities in Drosophila. The discovery of piRNAs revolutionized our understanding of TE repression, because it reveals that the host organisms have evolved an adaptive mechanism to defend against TE invasion. Tremendous progress has been made to understand the molecular mechanisms by which piRNAs repress active TEs, although many details in this process remain to be further explored. The interaction between piRNAs and TEs well explains the molecular mechanisms underlying hybrid dysgenesis for the I-R and P-M systems in Drosophila, which have puzzled evolutionary biologists for decades. The piRNA repression pathway provides us an unparalleled system to study the co-evolutionary process between parasites and host organisms.
转座元件是可以在基因组内移动的DNA序列,通过各种机制影响宿主生物体的基因组,转录组和蛋白质组。由于转座元件在基因组中随机跳跃,其受到很强的负选择压力,但是它们复制特别快,传统种群遗传学认为“转座-选择”平衡决定了转座元件在基因组中的拷贝数。近年的研究发现与PIWI蛋白结合的piRNA是果蝇中抑制转座元件的重要机制。piRNA的发现揭示了宿主生物体已经发展出一种适应性机制来防御转座元件入侵。piRNA和转座元件的相互作用很好的解释了果蝇中一些经典的杂交不育现象(如P-M和I-R系统)。piRNA抑制途径为我们提供了一个研究基因组中的寄生生物体与宿主生物共同演化的绝佳系统。

Page 164-176

Review Article

Transcriptional and Post-transcriptional Gene Regulation by Long Non-coding RNA

Iain M. Dykes, Costanza Emanueli

Advances in genomics technology over recent years have led to the surprising discovery that the genome is far more pervasively transcribed than was previously appreciated. Much of the newly-discovered transcriptome appears to represent long non-coding RNA (lncRNA), a heterogeneous group of largely uncharacterised transcripts. Understanding the biological function of these molecules represents a major challenge and in this review we discuss some of the progress made to date. One major theme of lncRNA biology seems to be the existence of a network of interactions with microRNA (miRNA) pathways. lncRNA has been shown to act as both a source and an inhibitory regulator of miRNA. At the transcriptional level, a model is emerging whereby lncRNA bridges DNA and protein by binding to chromatin and serving as a scaffold for modifying protein complexes. Such a mechanism can bridge promoters to enhancers or enhancer-like non-coding genes by regulating chromatin looping, as well as conferring specificity on histone modifying complexes by directing them to specific loci.
长非编码RNA(long non-coding RNA, lncRNA)是基因组学技术发展中的重大新发现,它具有高度异质性,但没有描述其功能和特点的转录本,这对理解它的生物学功能和意义带来了巨大的挑战。全基因组关联分析发现这些lncRNA基因富有多态性特征或者疾病相关联的多态性特征。因此,lncRNA的生物学功能研究对其厘清lncRNA本身或其疾病相关性是具有重大意义的。这篇综述整合了目前对lncRNA的研究,全面介绍了它的发现历程、多样性以及主要生物学功能。lncRNA的发现得益于测序技术的发展,由于其本身具有多样性的特点,使得它的生物学功能也具有多样化。lncRNA既可从转录后水平上调控基因表达,也可从转录水平上调控基因表达。在转录后调控机制上,lncRNA可与microRNA(miRNA)通路相互作用形成一个调控网络:lncRNA不仅是miRNA的主要来源,也作为miRNA的负调控因子。在转录调控机制上,lncRNA通过结合核染色质或者作为修饰蛋白复合体的支架来搭建DNA与蛋白质之间的调控桥梁。同时,lncRNA还通过调节核染色质循环以及招募特异性的组蛋白修饰复合物到特定位点的方式来搭建启动子到增强子或增强子相似非编码基因之间的调控桥梁。

Page 177-186

Review Article

Primate-specific Long Non-coding RNAs and MicroRNAs

Hassaan Mehboob Awan, Abdullah Shah, Farooq Rashid, Ge Shan

Non-coding RNAs (ncRNAs) are critical regulators of gene expression in essentially all life forms. Long ncRNAs (lncRNAs) and microRNAs (miRNAs) are two important RNA classes possessing regulatory functions. Up to date, many primate-specific ncRNAs have been identified and investigated. Their expression specificity to primate lineage suggests primate-specific roles. It is thus critical to elucidate the biological significance of primate or even human-specific ncRNAs, and to develop potential ncRNA-based therapeutics. Here, we have summarized the studies regarding regulatory roles of some key primate-specific lncRNAs and miRNAs.
几乎在所有的生命体中,非编码RNAs(ncRNAs)都是基因表达的关键调控因子,而两种重要的非编码RNAs:长非编码RNAs(lncRNA)和microRNAs(miRNAs)具有多种调控功能。如今,许多灵长类特异表达的非编码RNAs被陆续发现和研究,而它们在灵长类动物中的特异表达暗示了他们具有特别的功能。因此揭示这些(甚至是人类特异的)非编码RNAs生物学作用以及开发基于一些有潜力的非编码RNAs的治疗手段具有重要意义。本文中,我们对一些灵长类特异的lncRNAs和miRNAs调控作用的研究成果进行了总结。

Page 187-195

Review Article

Enhancer-derived RNA: A Primer

Feng Liu

Enhancer-derived RNAs (eRNAs) are a group of RNAs transcribed by RNA polymerase II from the domain of transcription enhancers, a major type of cis-regulatory elements in the genome. The correlation between eRNA production and enhancer activity has stimulated studies on the potential role of eRNAs in transcriptional regulation. Additionally, eRNA has also served as a marker for global identification of enhancers. Here I review the brief history and fascinating properties of eRNAs.
增强子RNA(eRNA)是以增强子这一远端基因调控位点为模板转录而成的非编码RNA。有研究表明eRNA能够促进增强子与基因启动子的相互作用从而调节基因表达。近年来基于高通量测序的eRNA检测方法还被广泛用于绘制基因组里活跃的增强子图谱。本文将介绍eRNA这类非编码RNA的生物学特性以及它们在表观基因组学研究的应用。

Page 196-200

Review Article

Non-coding Transcripts from Enhancers: New Insights into Enhancer Activity and Gene Expression Regulation

Hongjun Chen, Guangshi Du, Xu Song, Ling Li

Long non-coding RNAs (lncRNAs) have gained widespread interest in the past decade owing to their enormous amount and surprising functions implicated in a variety of biological processes. Some lncRNAs exert function as enhancers, i.e., activating gene transcription by serving as the cis-regulatory molecules. Furthermore, recent studies have demonstrated that many enhancer elements can be transcribed and produce RNA molecules, which are termed as enhancer RNAs (eRNAs). The eRNAs are not merely the by-product of the enhancer transcription. In fact, many of them directly exert or regulate enhancer activity in gene activation through diverse mechanisms. Here, we provide an overview of enhancer activity, transcription of enhancer itself, characteristics of eRNAs, as well as their roles in regulating enhancer activity and gene expression.
经过十余年的探索,目前已经发现lncRNA在生长发育、细胞凋亡、肿瘤发生等众多生理病理过程中以多种形式发挥调控效应,其生物学功能也受到科研工作者的重视。lncRNA可通过与其他生物大分子的相互作用发挥功能,并通过顺式或反式作用的方式调节目的基因的表达。新近研究表明基因增强子也可以进行转录,其转录产物被称为增强子RNA(enhancer RNA,eRNA)。研究显示这些eRNA能够发挥类似于lncRNA的基因表达调控功能。本文以增进对eRNA的了解为目的,对增强子、增强子的转录、eRNA的特点以及eRNA的作用机制进行讨论,并探讨了eRNAs如何介导增强子的功能以及如何调节基因表达。

Page 201-207

Research Article

Downregulation of miR-503 Promotes ESCC Cell Proliferation, Migration, and Invasion by Targeting Cyclin D1

Lanfang Jiang, Zitong Zhao, Leilei Zheng, Liyan Xue, Qimin Zhan, Yongmei Song

Esophageal squamous cell carcinoma (ESCC) is one of the most aggressive cancers in China, but the underlying molecular mechanism of ESCC is still unclear. Involvement of microRNAs has been demonstrated in cancer initiation and progression. Despite the reported function of miR-503 in several human cancers, its detailed anti-oncogenic role and clinical significance in ESCC remain undefined. In this study, we examined miR-503 expression by qPCR and found the downregulation of miR-503 expression in ESCC tissue relative to adjacent normal tissues. Further investigation in the effect of miR-503 on ESCC cell proliferation, migration, and invasion showed that enhanced expression of miR-503 inhibited ESCC aggressive phenotype and overexpression of CCND1 reversed the effect of miR-503-mediated ESCC cell aggressive phenotype. Our study further identified CCND1 as the target gene of miR-503. Thus, miR-503 functions as a tumor suppressor and has an important role in ESCC by targeting CCND1.
食管癌是恶性程度最高的癌种之一,其死亡率占世界癌症相关死亡率的第六位。中国的食管癌患者数量居世界首位。根据病理学分类,可将食管癌分为两种亚型,即食管鳞状细胞癌(ESCC)和食管腺癌(EAC),而中国的食管癌患者绝大部分是食管鳞状细胞癌﹙﹥90%﹚。目前,食管鳞状细胞癌的临床治疗手段有限,中国食管癌患者的五年生存率低于20%。因此,进一步探究食管鳞癌的发病机理、筛选食管鳞癌诊断的分子标志物、寻找有效的药物靶点具有重要的临床意义。microRNAs与食管癌的发生、转移和预后密切相关,miR-503被报道在多种肿瘤中发挥抑癌基因的作用,但其在食管癌中的作用机制尚不明确。本文是关于miR-503在食管癌中作用机制的研究。我们研究发现miR-503在食管癌组织中的表达低于配对的癌旁组织;功能研究发现,miR-503可抑制食管癌细胞的增殖、侵袭和迁移并导致细胞周期G1/S期的阻滞。细胞周期蛋白CyclinD1与食管癌的发生发展密切相关。数据库预测、Western Blot、结合荧光素酶报告基因实验表明CCND1是miR-503的靶基因。过表达miR-503可以抑制CCND1 mRNA和蛋白水平的表达。回复实验结果表明CCND1可以部分回复miR-503对细胞恶性表型的抑制作用。qPCR结果显示,CCND1 mRNA在食管癌组织中的表达低于其在配对的癌旁正常组织中的表达,且与miR-503的表达呈负相关。以上结果说明miR-503通过靶向CCND1抑制食管癌细胞的恶性表型,miR-503在食管癌中发挥抑癌基因的作用。

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