How selfish retrotransposons are silenced in Drosophila germline and somatic cells

Transposable elements (TEs) are DNA elements found in the genomes of various organisms. TEs have been highly conserved during evolution, suggesting that they confer advantageous effects to their hosts. However, due to their ability to transpose into virtually any locus, TEs have the ability to generate deleterious mutations in the host genome. In response, a variety of different mechanisms have evolved to mitigate their activities. A main defense mechanism is RNA silencing, which is a gene silencing mechanism triggered by small RNAs. In this review, we address RNA silencing mechanisms that silence retrotransposons, a subset of TEs, and discuss how germline and somatic cells are equipped with different retrotransposon silencing mechanisms.     

Viral suppression of RNA silencing

Gene silencing (RNA silencing) plays a fundamental role in antiviral defense in plants, fungi and invertebrates. Viruses encode proteins that suppress gene silencing to counter host defense. Viral suppressors of RNA silencing (VSRs) have been identified from almost all plant virus genera and some viruses of insects and mammals. Recent studies have revealed that VSRs counter host defense and interfere with host gene regulation by interacting with RNA or important components of the RNA silencing pathway. Here, we review the current understanding of the complex mechanisms of VSRs that have been revealed by recent studies.     

小RNAs在沉默转座因子中的作用

在很多生物基因组中都存在DNA成分的转座序列,它们能够转座到基因组的很多位点,对基因组造成很大的危害,如破坏编码基因、改变基因表达的调节网络、使染色体断裂或造成大范围基因重排等。真核生物已经进化出了多种机制来控制这些寄生核酸序列造成的损伤,以维持基因组完整性。虽然这些机制在不同生物中有些差异,但其中一种主要的机制是通过小RNAs介导的,这些小RNAs包括小干扰RNAs、piwi相互作用的小RNAs、微小RNAs、扫描RNAs和21U-RNAs等。这些小RNAs可以通过DNA水平剪切转座序列,或在转录和(或)转录后水平沉默转座成分。该文就这些小RNAs沉默转座成分的机制和功能做一论述。     

Transposable elements and the epigenetic regulation of the genome

Overlapping epigenetic mechanisms have evolved in eukaryotic cells to silence the expression and mobility of transposable elements (TEs). Owing to their ability to recruit the silencing machinery, TEs have served as building blocks for epigenetic phenomena, both at the level of single genes and across larger chromosomal regions. Important progress has been made recently in understanding these silencing mechanisms. In addition, new insights have been gained into how this silencing has been co-opted to serve essential functions in 'host' cells, highlighting the importance of TEs in the epigenetic regulation of the genome.     

Transposable Element Regulation in Rice and Arabidopsis: Diverse Patterns of Active Expression and siRNA-mediated Silencing

Transposable elements (TEs) are DNA segments that can mediate or cause movement within genomes. We performed a comprehensive, whole-genome analysis of annotated TEs in rice (Oryza sativa L.) and Arabidopsis thaliana, focusing on their expression (mRNA data) and silencing (small RNA data), and we compared these data with annotated genes that are not annotated as transposons. TEs demonstrated higher levels of antisense mRNA expression in comparison to non-TE genes. The majority of the TEs were silenced, as demonstrated by higher levels of small RNAs and a lack of mRNA MPSS data. When TEs were expressed, their activity was usually limited to just one or a few of the mRNA libraries. When we examined TE expression at the whole-genome level and across the complete mRNA dataset, we observed that most activity was contributed by a few highly expressed transposable elements. These TEs were characterized by their low copy number and few matching small RNAs. Our results help define the relationship between gene expression and gene silencing for TEs, and indicate that TE silencing can impact neighboring genes, perhaps via a mechanism of heterochromatin formation and spreading. These data may be used to define active TEs and families of transposable elements that continue to shape plant genomes.     

A "mille-feuille" of silencing: epigenetic control of transposable elements

Despite their abundance in the genome, transposable elements (TEs) and their derivatives are major targets of epigenetic silencing mechanisms, which restrain TE mobility at different stages of the life cycle. DNA methylation, post-translational modification of histone tails and small RNA-based pathways contribute to maintain TE silencing; however, some of these epigenetic marks are tightly interwoven and this complicates the delineation of the exact contribution of each in TE silencing. Recent studies have confirmed that host genomes have evolved versatility in the use of these mechanisms to individualize silencing of particular TEs. These studies also revealed that silencing of TEs is much more dynamic than had been previously thought and can be reversed on the genomic scale in particular cell types or under special environmental conditions. This article is part of a Special Issue entitled "Epigenetic control of cellular and developmental processes in plants".     

植物抗病毒分子机制

在与植物病毒的长期斗争中,植物进化出多种抗病毒机制,其中RNA沉默和R基因介导的病毒抗性是最受人们关注的两种机制.一方面,RNA沉默是植物抵抗病毒侵染的重要手段.植物在病毒侵染过程中可形成病毒来源的双链RNA,经过DCL蛋白的切割、加工形成sRNA,与AGO蛋白结合形成RISC指导病毒RNA的沉默,用于清除病毒.相应地,病毒在与植物的竞争中进化出RNA沉默抑制子,抑制宿主RNA沉默系统以逃避宿主RNA沉默抗病毒反应,增强致病能力.另一方面,植物也进化出R基因介导植物对包括病毒在内的多类病原的抗性.R蛋白直接或间接识别病毒因子,通过一系列的信号转导途径激活植物防御反应,限制病毒的进一步侵染.对植物抗病毒的研究有助于人们对植物抗病分子基础的理解,有重要的科学意义和潜在应用价值.本文综述了植物抗病毒分子机制的重要进展.     

RNA silencing and plant viral diseases

RNA silencing plays a critical role in plant resistance against viruses, with multiple silencing factors participating in antiviral defense. Both RNA and DNA viruses are targeted by the small RNA-directed RNA degradation pathway, with DNA viruses being also targeted by RNA-directed DNA methylation. To evade RNA silencing, plant viruses have evolved a variety of counter-defense mechanisms such as expressing RNA-silencing suppressors or adopting silencing-resistant RNA structures. This constant defense-counter defense arms race is likely to have played a major role in defining viral host specificity and in shaping viral and possibly host genomes. Recent studies have provided evidence that RNA silencing also plays a direct role in viral disease induction in plants, with viral RNA-silencing suppressors and viral siRNAs as potentially the dominant players in viral pathogenicity. However, questions remain as to whether RNA silencing is the principal mediator of viral pathogenicity or if other RNA-silencing-independent mechanisms also account for viral disease induction. RNA silencing has been exploited as a powerful tool for engineering virus resistance in plants as well as in animals. Further understanding of the role of RNA silencing in plant-virus interactions and viral symptom induction is likely to result in novel anti-viral strategies in both plants and animals.     

Viral suppressors of RNA silencing

The suppression of RNA silencing by plant viruses represents a viral adaptation to a novel host antiviral defense. Three types of viral suppressors have been identified through the use of a variety of silencing suppression assays. The first two types of suppressor are capable of a complete or partial reversal of pre-existing RNA silencing; the third type does not reverse RNA silencing but can instead prevent its systemic signaling.     

转录后基因沉默--植物抵御外来病毒入侵的一种机制

基因沉默是近几年来在转基因植物中发现的一种后生遗传现象。基因沉默大体可以分为两类：位置效应引起的基因沉默和同源依赖的基因沉默。其中,同源依赖的基因沉默又可以分为转录水平的基因沉默和转录后水平的基因沉默。基因沉默的发现使得人们对植物和病毒的相互关系有了一个新的认识。基因沉默研究中所发现的转录后基因沉默现象是植物抵御病毒入侵、保持自身基因组完整性的一种防御机制,是植物与病毒共进化的结果。对于沉默产生的机理,尤其是转录后基因沉默,已经提出不少模型,但是都未能较全面地解释基因沉默中出现的各种实验现象。该文现就实验所取得的相关结果、转录后基因沉默机制和植物对病毒防御机制的相互关系,以及其研究进展进行综述。     

A structural perspective of the protein–RNA interactions involved in virus-induced RNA silencing and its suppression

Small RNAs, including small interfering RNAs (siRNAs), microRNAs (miRNAs) and Piwi-associated interfering RNAs (piRNAs), are powerful gene expression regulators. This RNA-mediated regulation results in sequence-specific inhibition of gene expression by translational repression and/or mRNA degradation. siRNAs and miRNAs are generated by RNase III enzymes and subsequently loaded into Argonaute protein, a key component of the RNA induced silencing complex (RISC), to form the core of the RNA silencing machinery. RNA silencing acts as an ancient cell defense system against molecular parasites, such as transgenes, viruses and transposons. RNA silencing also plays an important role in the control of development. In plants, RNA silencing serves as a potent antiviral defense system. In response, many viruses have developed strategies to suppress RNA silencing. The striking sequence diversity among viral suppressors suggests that different viral suppressors could target different components of the RNA silencing machinery at different steps in different suppressing modes. Significant progresses have been made in this field for the past 5 years on the basis of structural information derived from RNase III family proteins, Dicer fragments and homologs, Argonaute homologs and viral suppressors. In this paper, we will review the current progress on the understanding of molecular mechanisms of RNA silencing; highlight the structural principles determining the protein–RNA recognition events along the RNA silencing pathways and the suppression mechanisms displayed by viral suppressors.     

Quelling targets the rDNA locus and functions in rDNA copy number control

Background  

RNA silencing occurs in a broad range of organisms. Although its ancestral function is probably related to the genome defense mechanism against repetitive selfish elements, it has been found that RNA silencing regulates different cellular processes such as gene expression and chromosomal segregation. In Neurospora crassa, a RNA silencing mechanism, called quelling, acts to repress the expression of transgenes and transposons, but until now no other cellular functions have been shown to be regulated by this mechanism.