Identification and Characterization of piRNA-Like Small RNAs in the Gonad of Sea Urchin (Strongylocentrotus nudus)

Piwi-interacting RNAs (piRNAs) and their partner PIWI proteins play an essential role in fertility, germline stem cell development, as well as the basic control and evolution of animal genomes. However, research was rare with regard to piRNA population in sea urchin, a model animal intensively used for development and genetics studies. Utilizing Solexa sequencing, we present an identification of 13,051 piRNA-like RNAs expressed in male gonad of Strongylocentrotus nudus. Out of 202 tested RNAs, 94 sequences were confirmed to express in female gonad using microarray assay, suggesting that both male and female gonads are piRNA-like RNA-enriched organs. These RNAs with "U" at the 5' end or "A" at position of 10, in size from 26 to 30 nucleotides, were predominantly 28?nt in length and tend to be clustered in small regions in genome, achieving the longest piRNA-like RNA-enriched region about 5.5?kb in scaffold78427. Alignment results showed 11 RNAs were homologous to the known piRNAs. Furthermore, BLASTn searching against sea urchin repeat element database showed these piRNA-like RNAs matched to 101 types of DNA transposons and retrotransposons, of which SPRP1, Harbinger-N2, piggyBac-N10, SINE2-1, and piggyBac-N11 were the most frequent hit elements, suggesting a transposon silencing function of these piRNA-like RNAs.     

Cloning and expression analysis of piRNA-like RNAs: adult testis-specific small RNAs in chicken

Many small RNAs have been cloned from animal gonads, for example, endogenous small interfering RNAs (endo-siRNAs) were found in oocytes and piwi-interacting RNAs (piRNAs) were found in testis. Gallus gallus (chicken) is an important model organism, but few small RNAs have been identified from its gonads. In this study, we isolated and cloned 156 small RNAs from adult chicken testes. Since there is a reasonably even distribution from 22 to 33 nt, these small RNAs are slightly longer than miRNAs and endo-siRNAs. Genome mapping indicated that these small RNAs were derived from intergenic regions, exons, introns, and repetitive elements including chicken repeat 1, long terminal repeats, and simple repeats. Since they are similar with piRNAs, we named them piRNA-like RNAs (pil-RNAs). Northern blotting of 16 selected sequences showed that nine are specifically expressed in the adult testis. The vast majority of these pil-RNAs are poorly conserved between species, suggesting that they are unique to the adult chicken testis. Further analysis of the cloned pil-RNAs will improve our understanding of the function of small RNAs in animal gonad development.     

Transposon Defense by Endo-siRNAs,piRNAs and Somatic pilRNAs in Drosophila: Contributions of Loqs-PD and R2D2

Transposable elements are a serious threat for genome integrity and their control via small RNA mediated silencing pathways is an ancient strategy. The fruit fly Drosophila melanogaster has two silencing activities that target transposons: endogenous siRNAs (esiRNAs or endo-siRNAs) and Piwi-interacting small RNAs (piRNAs). The biogenesis of endo-siRNAs involves the Dicer-2 co-factors Loqs-PD, which acts predominantly during processing of dsRNA by Dcr-2, and R2D2, which primarily helps to direct siRNAs into the RNA interference effector Ago2. Nonetheless, loss of either protein is not sufficient to produce a phenotype comparable with a dcr-2 mutation. We provide further deep sequencing evidence supporting the notion that R2D2 and Loqs-PD have partially overlapping function. Certain transposons display a preference for either dsRBD-protein during production or loading; this appeared to correlate neither with overall abundance, classification of the transposon or a specific site of genomic origin. The endo-siRNA biogenesis pathway in germline operates according to the same principles as the existing model for the soma, and its impairment does not significantly affect piRNAs. Expanding the analysis, we confirmed the occurrence of somatic piRNA-like RNAs (pilRNAs) that show a ping-pong signature. We detected expression of the Piwi-family protein mRNAs only barely above background, indicating that the somatic pilRNAs may arise from a small sub-population of somatic cells that express a functional piRNA pathway.     

Transcriptomic profiling of the oyster pathogen Vibrio splendidus opens a window on the evolutionary dynamics of the small RNA repertoire in the Vibrio genus

Work in recent years has led to the recognition of the importance of small regulatory RNAs (sRNAs) in bacterial regulation networks. New high-throughput sequencing technologies are paving the way to the exploration of an expanding sRNA world in nonmodel bacteria. In the Vibrio genus, compared to the enterobacteriaceae, still a limited number of sRNAs have been characterized, mostly in Vibrio cholerae, where they have been shown to be important for virulence, as well as in Vibrio harveyi. In addition, genome-wide approaches in V. cholerae have led to the discovery of hundreds of potential new sRNAs. Vibrio splendidus is an oyster pathogen that has been recently associated with massive mortality episodes in the French oyster growing industry. Here, we report the first RNA-seq study in a Vibrio outside of the V. cholerae species. We have uncovered hundreds of candidate regulatory RNAs, be it cis-regulatory elements, antisense RNAs, and trans-encoded sRNAs. Conservation studies showed the majority of them to be specific to V. splendidus. However, several novel sRNAs, previously unidentified, are also present in V. cholerae. Finally, we identified 28 trans sRNAs that are conserved in all the Vibrio genus species for which a complete genome sequence is available, possibly forming a Vibrio “sRNA core.”     

Arabidopsis lyrata Small RNAs: Transient MIRNA and Small Interfering RNA Loci within the Arabidopsis Genus

Twenty-one-nucleotide microRNAs (miRNAs) and 24-nucleotide Pol IV-dependent small interfering RNAs (p4-siRNAs) are the most abundant types of small RNAs in angiosperms. Some miRNAs are well conserved among different plant lineages, whereas others are less conserved, and it is not clear whether less-conserved miRNAs have the same functionality as the well conserved ones. p4-siRNAs are broadly produced in the Arabidopsis genome, sometimes from active hot spot loci, but it is unknown whether individual p4-siRNA hot spots are retained as hot spots between plant species. In this study, we compare small RNAs in two closely related species (Arabidopsis thaliana and Arabidopsis lyrata) and find that less-conserved miRNAs have high rates of divergence in MIRNA hairpin structures, mature miRNA sequences, and target-complementary sites in the other species. The fidelity of miRNA biogenesis from many less-conserved MIRNA hairpins frequently deteriorates in the sister species relative to the species of first discovery. We also observe that p4-siRNA occupied loci have a slight tendency to be retained as p4-siRNA loci between species, but the most active A. lyrata p4-siRNA hot spots are generally not syntenic to the most active p4-siRNA hot spots of A. thaliana. Altogether, our findings indicate that many MIRNAs and most p4-siRNA hot spots are rapidly changing and evolutionarily transient within the Arabidopsis genus.     

The Fascinating World of RNA Interference

Micro- and short-interfering RNAs represent small RNA family that are recognized as critical regulatory species across the eukaryotes. Recent high-throughput sequencing have revealed two more hidden players of the cellular small RNA pool. Reported in mammals and Caenorhabditis elegans respectively, these new small RNAs are named piwi-interacting RNAs (piRNAs) and 21U-RNAs. Moreover, small RNAs including miRNAs have been identified in unicellular alga Chlamydomonas reinhardtii, redefining the earlier concept of multi-cellularity restricted presence of these molecules. The discovery of these species of small RNAs has allowed us to understand better the usage of genome and the number of genes present but also have complicated the situation in terms of biochemical attributes and functional genesis of these molecules. Nonetheless, these new pools of knowledge have opened up avenues for unraveling the finer details of the small RNA mediated pathways.     

Small RNAs of Rous Sarcoma Virus: Characterization by Two-Dimensional Polyacrylamide Gel Electrophoresis and Fingerprint Analysis

Approximately 15 to 20 different species of small (4 to 7S) RNAs have been purified by two-dimensional polyacrylamide gel electrophoresis of RNA isolated from virions of Schmidt-Ruppin D strain of Rous sarcoma virus. Each species of small RNA has been isolated free of 70S RNA; nine of them, including 5S and 7S RNAs, were also found associated with the 70S genomic RNA. Most of the 4S RNAs are present at an average of less than one copy per virion. The 4S RNAs have T1 RNase (EC 2.7.7.26) fingerprints, which are very similar to those of tRNAs. One of the smallest 4S RNAs, which can act as a primer for initiation of RNA-directed DNA synthesis, is associated with the 70S RNA in 1 to 2 copies per complex, whereas an additional 6 to 8 copies of this molecule are free.     

Detection of 5'- and 3'-UTR-derived small RNAs and cis-encoded antisense RNAs in Escherichia coli

Evidence is accumulating that small, noncoding RNAs are important regulatory molecules. Computational and experimental searches have led to the identification of ~60 small RNA genes in Escherichia coli. However, most of these studies focused on the intergenic regions and assumed that small RNAs were >50 nt. Thus, the previous screens missed small RNAs encoded on the antisense strand of protein-coding genes and small RNAs of <50 nt. To identify additional small RNAs, we carried out a cloning-based screen focused on RNAs of 30–65 nt. In this screen, we identified RNA species corresponding to fragments of rRNAs, tRNAs and known small RNAs. Several of the small RNAs also corresponded to 5′- and 3′-untranslated regions (UTRs) and internal fragments of mRNAs. Four of the 3′-UTR-derived RNAs were highly abundant and two showed expression patterns that differed from the corresponding mRNAs, suggesting independent functions for the 3′-UTR-derived small RNAs. We also detected three previously unidentified RNAs encoded in intergenic regions and RNAs from the long direct repeat and hok/sok elements. In addition, we identified a few small RNAs that are expressed opposite protein-coding genes and could base pair with 5′ or 3′ ends of the mRNAs with perfect complementarity.     

Cloning and Expression Studies of Novel Small RNAs in Tetraploid Cotton

Small RNAs are a group of non-coding RNAs that downregulate gene expression in a sequence-specific manner to control plant growth and development. The objective of the present study was to clone and characterize several small RNAs in cotton. To identify small RNAs that are involved in the development of cotton bolls and fibers, we generated cDNA libraries from cotton bolls at 13?days post-anthesis from two cotton cultivars, Pima Phy 76 (Gossypium bardadense) and Acala 1517?C99 (Gossypium hirsutum). Screening of these libraries identified eight small RNAs, seven of which have not been reported in other plant species and appear to be absent in the known sequences of other plant species. Their predicted target genes are known to be involved in cotton fiber development. The cloned small RNAs displayed lower and differential expression in the examined boll developmental stages using RT-PCR and quantitative RT-PCR. The genetic polymorphism of the small RNAs at the DNA level was evaluated by miRNA-amplified fragment length polymorphism (AFLP) analysis using primers designed from the small miRNA genes in combination with AFLP primers. Homologous small RNA gene sequences were further isolated using this homology-based genotyping approach, and potential hairpin structures were identified. The results represent a novel method to isolate small including miRNA genes at the RNA and DNA levels in many plant species where genome sequences are not available or expressed sequence tags are limited.     

Bombyx small RNAs: genomic defense system against transposons in the silkworm, Bombyx mori

Selfish genetic elements called transposons can insert themselves at new locations in host genomes to modify gene structure and alter gene expression. Expansion of transposons can occur when novel transposition events are transmitted to subsequent generations after germline hopping. Therefore, organisms seem likely to have evolved defense mechanisms to silence transposons in the germline. Recently, small RNAs interacting with Piwi proteins (piwi-interacting RNAs: piRNAs) have been demonstrated to be involved in genomic defense mechanism against transposons. Here, we show that piRNA-like small RNAs are present abundantly in the Bombyx ovary. We cloned 38,493 kinds of Bombyx small RNA from the ovary and performed functional characterization. Bombyx small RNAs showed a unimodal length distribution with a peak at 28nt and a strong bias for U at the 5' end. We found that 12,869 kinds of Bombyx small RNAs were associated with transposons or repetitive sequences. We classified them as repeat-associated small interfering RNAs (rasiRNAs), a subclass of piRNAs. Notably, antisense rasiRNAs have a strong bias toward U at 5' ends; in contrast, sense rasiRNAs have a strong bias toward A at nucleotide position 10, indicating that the piRNA amplification loop proposed in Drosophila is evolutionarily conserved in Bombyx. These results suggest that Bombyx small RNAs regulate transposon activity.     

Production of virus-derived ping-pong-dependent piRNA-like small RNAs in the mosquito soma

The natural maintenance cycles of many mosquito-borne pathogens require establishment of persistent non-lethal infections in the invertebrate host. The mechanism by which this occurs is not well understood, but we have previously shown that an antiviral response directed by small interfering RNAs (siRNAs) is important in modulating the pathogenesis of alphavirus infections in the mosquito. However, we report here that infection of mosquitoes with an alphavirus also triggers the production of another class of virus-derived small RNAs that exhibit many similarities to ping-pong-dependent piwi-interacting RNAs (piRNAs). However, unlike ping-pong-dependent piRNAs that have been described previously from repetitive elements or piRNA clusters, our work suggests production in the soma. We also present evidence that suggests virus-derived piRNA-like small RNAs are capable of modulating the pathogenesis of alphavirus infections in dicer-2 null mutant mosquito cell lines defective in viral siRNA production. Overall, our results suggest that a non-canonical piRNA pathway is present in the soma of vector mosquitoes and may be acting redundantly to the siRNA pathway to target alphavirus replication.     

Genome-wide analysis of single non-templated nucleotides in plant endogenous siRNAs and miRNAs

Plant small RNAs are subject to various modifications. Previous reports revealed widespread 3′ modifications (truncations and non-templated tailing) of plant miRNAs when the 2′-O-methyltransferase HEN1 is absent. However, non-templated nucleotides in plant heterochromatic siRNAs have not been deeply studied, especially in wild-type plants. We systematically studied non-templated nucleotide patterns in plant small RNAs by analyzing small RNA sequencing libraries from Arabidopsis, tomato, Medicago, rice, maize and Physcomitrella. Elevated rates of non-templated nucleotides were observed at the 3′ ends of both miRNAs and endogenous siRNAs from wild-type specimens of all species. ‘Off-sized’ small RNAs, such as 25 and 23 nt siRNAs arising from loci dominated by 24 nt siRNAs, often had very high rates of 3′-non-templated nucleotides. The same pattern was observed in all species that we studied. Further analysis of 24 nt siRNA clusters in Arabidopsis revealed distinct patterns of 3′-non-templated nucleotides of 23 nt siRNAs arising from heterochromatic siRNA loci. This pattern of non-templated 3′ nucleotides on 23 nt siRNAs is not affected by loss of known small RNA 3′-end modifying enzymes, and may result from modifications added to longer heterochromatic siRNA precursors.