水稻雄配子体发育过程中tRNA片段的生物信息学分析

tRNA片段(tRF)是tRNA通过非随机剪切产生的RNA片段, 其产生和功能机制尚不明确; 而在水稻(Oryza sativa)雄配子体发育过程中, 人们对tRNA更是知之甚少。通过高通量测序, 在水稻雄配子体发育过程中发现了长度范围较大的tRFs; 进一步采用logo对tRFs两端的序列进行分析, 发现了4个有序列特征(其中3个未见报道)和1个无序列特征的酶切位点; 通过NCBI Blast预测了tRF靶基因, 发现其大多靶向转座因子。研究结果对揭示tRF产生机制以及水稻雄配子体发育研究有一定的参考价值。     

tRFs结构及其生物学功能

tRFs（tRNA-derived RNA fragments）是来源于tRNA的小分子非编码RNA,由前体tRNA或成熟tRNA经加工和修饰而成,在生物界中广泛存在。tRFs深度测序结果表明,tRFs可能并不是由tRNA随机裂解产生的,而是通过某个特定机制生成。根据来源不同,tRFs可被分为tRF-1、tRF-2、tRF-3、tRF-5和tiR。tRFs具有类似于miRNA的调控功能,并能参与调控基因转录和翻译,细胞增殖以及细胞应激反应。新近研究表明,乳腺癌细胞中某些特异性的tRFs（如tRF^GlyTCC和tRF^AspGTC）,可通过与Y-box结合蛋白1（Y box binding protein 1, YB-1）结合进而抑制癌细胞的生长和转移。另有研究表明,tRFs还可通过细胞色素c介导的信号转导途径来发挥其抑制癌细胞凋亡的功能。由此可见,tRFs在调控癌症发生发展过程中也具有重要调控作用,然而其机制仍不清楚。本文综述了tRFs结构和分布、生物学功能及其作用机制的研究现状,旨在为tRFs相关研究提供参考。     

A particular set of small non-coding RNAs is bound to the distinctive Argonaute protein of Trypanosoma cruzi: Insights from RNA-interference deficient organisms

The study of small RNAs and Argonaute proteins in eukaryotes that are deficient in functional RNA interference could provide insights into novel functions of small RNAs. In this study we describe small non-coding RNAs bound to a distinctive Argonaute protein of Trypanosoma cruzi, TcPIWI-tryp. Co-immunoprecipitation of TcPIWI-tryp followed by deep sequencing of isolated RNA identified abundant small RNAs derived from rRNAs and tRNAs. The small RNA repertoire differed from that of the canonical Argonaute in organisms with functional RNA interference, which could indicate novel biological functions for TcPIWI-tryp in T. cruzi and other members of the trypanosomatid clade.     

Epigenetic germline inheritance in mammals: looking to the past to understand the future

Life experiences can induce epigenetic changes in mammalian germ cells, which can influence the developmental trajectory of the offspring and impact health and disease across generations. While this concept of epigenetic germline inheritance has long been met with skepticism, evidence in support of this route of information transfer is now overwhelming, and some key mechanisms underlying germline transmission of acquired information are emerging. This review focuses specifically on sperm RNAs as causal vectors of inheritance. We examine how they might become altered in the germline, and how different classes of sperm RNAs might interact with other epimodifications in germ cells or in the zygote. We integrate the latest findings with earlier pioneering work in this field, point out major questions and challenges, and suggest how new experiments could address them.