小分子RNA抵御转座元件对基因组的侵袭

真核生物在漫长的进化繁衍过程中,一直处在抵御转座元件对基因组侵害的"斗争"中。在过去的十多年中,越来越多的证据指明,小分子RNA扮演了这样一个抵御转座子侵袭的角色。尽管这种抵御侵害的策略对于不同物种各具特点,但它们都呈现出惊人相似的共同特征。基本上,所有的机制都包含三个组成部分:首先,转座元件促使产生小分子RNA,在某些物种中主要是Piwi-interacting RNAs,而在其他物种中主要是small interfering RNAs;第二,作用于活跃转座子的小分子RNA通过RNA依赖性RNA聚合酶或切割机制进行扩增;第三,这些小分子RNA与含有Argonaute蛋白或Piwi蛋白的效应复合物相结合,从而作用于目标转座子的转录本,实现转录后沉默,或作用于目标转座子DNA,抑制染色质修饰和DNA甲基化。这些属性特征构成了一个限制由转座元件活动所造成的严重后果的系统,从而防止转座子侵袭所带来的突变积累,基因表达谱的改变,以及生殖腺发育不良和不育。     

3' end formation of PIWI-interacting RNAs in vitro

PIWI-interacting RNAs (piRNAs) are 23-30 nucleotides small RNAs that act with PIWI proteins to silence transposon activity in animal gonads. In contrast to microRNAs and small interfering RNAs, the biogenesis of piRNAs, including how 3' ends are formed, remains largely unknown. Here, by using lysate from BmN4, a silkworm ovary-derived cell line, we have developed a cell-free system that recapitulates key steps of piRNA biogenesis: loading of long single-stranded precursor RNAs into PIWI proteins with 5'-nucleotide bias, followed by Mg(2+)-dependent 3' to 5' exonucleolytic trimming and 2'-O-methylation at 3' ends. Importantly, 3' end methylation is tightly coupled with trimming and yet is not a prerequisite for determining the mature piRNA length. Our system provides a biochemical framework for dissecting piRNA biogenesis.     

Multiple leader RNAs and messenger RNAs are transcribed from the la crosse virus small genome segment

Nucleotide sequencing has demonstrated that the Small genome segment of Bunyaviruses contains the genetic information for two viral proteins (N and NS_s) in overlapping reading frames (Akashi and Bishop, 1983; Cabradilla et al., in press). Using 3′ end-labeled genome probes, La Crosse virus (LAC) infected cells were shown to contain three leader RNAs, which start at position 1 and terminate at approximate positions 74, 95, and 115 from the 3′ end of the genome. Primer extension and S1 mapping studies have shown that LAC-infected cells contain seven mRNAs, five of which initiate at positions 1, 74, 101, 117, and 123 and two more which initiate at approximate positions 147 and 159 from the 3′ end of the Small genome segment. The existence of multiple leader RNAs and mRNAs from the Small genome segment may allow access to both overlapping reading frames by ribosomes that still initiate only at 5′ proximal AUGs, without the need to splice the mRNA.     

Non-coding RNAs: lessons from the small nuclear and small nucleolar RNAs

Recent advances have fuelled rapid growth in our appreciation of the tremendous number, diversity and biological importance of non-coding (nc)RNAs. Because ncRNAs typically function as ribonucleoprotein (RNP) complexes and not as naked RNAs, understanding their biogenesis is crucial to comprehending their regulation and function. The small nuclear and small nucleolar RNPs are two well studied classes of ncRNPs with elaborate assembly and trafficking pathways that provide paradigms for understanding the biogenesis of other ncRNPs.     

Small RNAs: regulators and guardians of the genome

Small non-coding RNAs comprise several classes and sizes, but all share a unifying function in cellular physiology: epigenetic regulation of gene expression. Here, we review the salient aspects of recent studies on the biogenesis and function of three classes of small RNAs: miRNAs, siRNAs, and piRNAs. Although the mechanisms are becoming clear by which siRNA-triggered mRNA cleavage silences genes, more studies are needed on several issues regarding miRNA-mediated translation repression. Piwi proteins have been suggested to co-operate in amplifying piRNA biogenesis to maintain transposon silencing in the germ line genome, but details of this process are still unknown as well as the functional consequences of piRNA expression at discrete genomic loci.     

Analysis of a piwi-related gene implicates small RNAs in genome rearrangement in tetrahymena

During development of the somatic macronucleus from the germline micronucleus in ciliates, chromosome rearrangements occur in which specific regions of DNA are eliminated and flanking regions are healed, either by religation or construction of telomeres. We identified a gene, TWI1, in Tetrahymena thermophila that is homologous to piwi and is required for DNA elimination. We also found that small RNAs were specifically expressed prior to chromosome rearrangement during conjugation. These RNAs were not observed in TWI1 knockout cells and required PDD1, another gene required for rearrangement, for expression. We propose that these small RNAs function to specify sequences to be eliminated by a mechanism similar to RNA-mediated gene silencing.     

The burgeoning importance of PIWI-interacting RNAs in cancer progression

PIWI-interacting RNAs(pi RNAs) are a class of small noncoding RNA molecules that specifically bind to piwi protein family members to exert regulatory functions in germ cells. Recent studies have found that pi RNAs, as tissue-specific molecules, both play oncogenic and tumor suppressive roles in cancer progression, including cancer cell proliferation, metastasis, chemoresistance and stemness. Additionally, the atypical manifestation of pi RNAs and PIWI proteins in various malignancies presents a ...     

Conversations between kingdoms: small RNAs

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植物小分子RNA研究进展

植物体内存在多种不同类型的小分子RNA(small RNA,sRNA),在调节植物生长发育、抑制转座子活性和抵御逆境等过程中发挥着重要的作用。近年来,人们在sRNA的产生机制、效应复合物的形成和对靶基因的调控方式及其生物学功能等方面的研究取得了很大进展。该文对这些进展作简要介绍。     

Regulatory small RNAs

Recent years have been marked by a burst of studies on the role of various RNAs in the regulation of gene expression. These regulatory effects act on the level of both chromatin in the nuclei and the cytoplasm during translation. The review papers of this issue are mainly dedicated to different types of small RNAs of 20–30 nucleotides. The small RNAs control diverse cellular functions including genome protection against transpositions of mobile elements of the genome.     

Exploration of small RNAs

For several decades, only a limited number of noncoding RNAs, such as ribosomal and transfer RNA, have been studied in any depth. In recent years, additional species of noncoding RNAs have increasingly been discovered. Of these, small RNA species attract particular interest because of their essential roles in processes such as RNA silencing and modifications. Detailed analyses revealed several pathways associated with the function of small RNAs. Although these pathways show evolutional conservation, there are substantial differences. Advanced technologies to profile RNAs have accelerated the field further resulting in the discovery of an increasing number of novel species, suggesting that we are only just beginning to appreciate the complexity of small RNAs and their functions. Here, we review recent progress in novel small RNA exploration, including discovered small RNA species, their pathways, and devised technologies.