Small RNAs in development - insights from plants

microRNAs (miRNAs) and small interfering RNAs (siRNAs), which constitute two major classes of endogenous small RNAs in plants, impact a multitude of developmental and physiological processes by imparting sequence specificity to gene and genome regulation. Although lacking the third major class of small RNAs found in animals, Piwi-interacting RNAs (piRNAs), plants have expanded their repertoire of endogenous siRNAs, some of which fulfill similar molecular and developmental functions as piRNAs in animals. Research on plant miRNAs and siRNAs has contributed invaluable insights into small RNA biology, thanks to the highly conserved molecular logic behind the biogenesis and actions of small RNAs. Here, I review progress in the plant small RNA field in the past two years, with an emphasis on recent findings related to plant development. I do not recount the numerous developmental processes regulated by small RNAs; instead, I focus on major principles that have been derived from recent studies and draw parallels, when applicable, between plants and animals.     

植物RNA沉默的分子机制研究进展

RNA沉默（RNA silencing）是真核生物中的一种抵抗外源遗传因子（病毒、转座子或转基因）及调控基凶表达的防御机制。参与植物RNA沉默的酶及蛋白质主要包括6种RNA依赖的RNA聚合酶、4种Dicer-like（DCL）核酸内切酶和10种Argonautes蛋白。植物中4条RNA沉默途径分别由微小RNA（miRNAs）和3种小干扰RNA（siRNAs）介导,包括反式作用siRNAs（ta－siRNAs）、天然反义siRNAs（natsiRNAs）和异染色质siRNAs（hc-siRNAs）。在植物RNA沉默的系统性传播中,由DCL4或DCL2将dsRNAs裁剪为次级SiRNAS,以放大RNA沉默信号和增强沉默效应。     

siRNAs and miRNAs: small RNA molecules for big tasks

Small RNAs have been recently discovered as important regulators of gene expression in Eukaryota. This review compares two categories of small RNAs existing in plants: short interfering RNAs (siRNAs) and microRNAs (miRNAs) and reveals similarities and differences between two intriguing processes: RNA degradation and translational repression directed by small RNAs. The disruption of miRNA-mediated regulation causes developmental abnormalities in plants, proving a fundamental role of miRNAs.     

SRNAome and degradome sequencing analysis reveals specific regulation of sRNA in response to chilling injury in tomato fruit

Plant genomes encode diverse small RNA classes that function in distinct gene‐silencing pathways. To elucidate the intricate regulation of microRNAs (miRNAs) and endogenous small‐interfering RNAs (siRNAs) in response to chilling injury in tomato fruit, the deep sequencing and bioinformatic methods were combined to decipher the small RNAs landscape in the control and chilling‐injured groups. Except for the known miRNAs and ta‐siRNAs, 85 novel miRNAs and 5 ta‐siRNAs members belonging to 3 TAS families (TAS5, TAS9 and TAS10) were identified, 34 putative phased small RNAs and 740 cis/trans‐natural antisense small‐interfering RNAs (nat‐siRNAs) were also found in our results which enriched the tomato small RNAs repository. A large number of genes targeted by those miRNAs and siRNAs were predicted to be involved in the chilling injury responsive process and five of them were verified via degradome sequencing. Based on the above results, a regulatory model that comprehensively reveals the relationships between the small RNAs and their targets was set up. This work provides a foundation for further study of the regulation of miRNAs and siRNAs in the plant in response to chilling injury.     

Identification and characterization of endogenous small interfering RNAs from rice

RNA silencing-mediated small interfering RNAs (siRNAs) and microRNAs (miRNAs) have diverse natural roles, ranging from regulation of gene expression and heterochromatin formation to genome defense against transposons and viruses. Unlike miRNAs, endogenous siRNAs are generally not conserved between species; consequently, their identification requires experimental approaches. Thus far, endogenous siRNAs have not been reported from rice, which is a model species for monocotyledonous plants. We identified a large set of putative endogenous siRNAs from root, shoot and inflorescence small RNA cDNA libraries of rice. Most of these siRNAs are from intergenic regions, although a substantial proportion (22%) originates from the introns and exons of protein-coding genes. Northern and RT–PCR analysis revealed that the expression of some of the siRNAs is tissue specific or developmental stage specific. A total of 25 transposons and 21 protein-coding genes were predicted to be cis-targets of some of the siRNAs. Based on sequence homology, we also predicted 111 putative trans-targets for 44 of the siRNAs. Interestingly, ~46% of the predicted trans-targets are transposable elements, which suggests that endogenous siRNAs may play an important role in the suppression of transposon proliferation. Using RNA ligase-mediated-5′ rapid amplification of cDNA end assays, we validated three of the predicted targets and provided evidence for both cis- and trans-silencing of target genes by siRNAs-guided mRNA cleavage.     

MicroRNAs and cell differentiation in mammalian development

MicroRNAs (miRNAs) are a group of recently discovered small RNAs produced by the cell using a unique process, involving RNA polymerase II, Microprocessor protein complex, and the RNAase III/Dicer endonuclease complex, and subsequently sequestered in an miRNA ribonucleoprotein complex. The biological functions of miRNAs depend on their ability to silence gene expression, primarily via degradation of the target mRNA and/or translational suppression, mediated by the RNA-induced silencing complex (RISC). First discovered in Caenorhabditis elegans (lin-4), miRNAs have now been identified in a wide array of organisms, including plants, zebrafish, Drosophila, and mammals. The expression of miRNAs in multicellular organisms exhibits spatiotemporal, and tissue- and cell-specificity, suggesting their involvement in tissue morphogenesis and cell differentiation. More than 200 miRNAs have been identified or predicted in mammalian cells. Recent studies have demonstrated the importance of miRNAs in embryonic stem cell differentiation, limb development, adipogenesis, myogenesis, angiogenesis and hematopoiesis, neurogenesis, and epithelial morphogenesis. Overexpression (gain-of-function) and inactivation (loss-of-function) are currently the primary approaches to studying miRNA functions. Another family of small RNAs related to miRNAs is the small interfering RNAs (siRNAs), generated by Dicer from long double-stranded RNAs (dsRNAs), and produced from an induced transgene, a viral intruder, or a rogue genetic element. siRNAs silence genes via either mRNA degradation, using the RISC, or DNA methylation. siRNAs are actively being applied in basic, functional genetic studies, particularly in the generation of gene knockdown animals, as well as in gene knockdown studies of cultured cells. These studies have provided invaluable information on the specific function(s) of individual genes. siRNA technology also presents exciting potential as a therapeutic approach in disease prevention and treatment, as suggested by a recent study targeting apolipoprotein B (ApoB) in primates. Further elucidation of how miRNAs and other small RNAs interact with known and yet-to-be identified gene regulatory pathways in the cell should provide us with a more in-depth understanding of the mechanisms regulating cellular function and differentiation, and facilitate the application of small RNA technology in disease control and treatment.     

An inside job for siRNAs

Among the three main categories of small silencing RNAs in insects and mammals-siRNAs, miRNAs, and piRNAs-siRNAs were thought to arise primarily from exogenous sources, whereas miRNAs and piRNAs arise from endogenous loci. Recent work in flies and mice reveals several classes of endogenous siRNAs (endo-siRNAs) that contribute to functions previously reserved for miRNAs and piRNAs, including gene regulation and transposon suppression.     

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.