Small RNA profiling and characterization of piRNA clusters in the adult testes of the common marmoset,a model primate

Small RNAs mediate gene silencing by binding Argonaute/Piwi proteins to regulate target RNAs. Here, we describe small RNA profiling of the adult testes of Callithrix jacchus, the common marmoset. The most abundant class of small RNAs in the adult testis was piRNAs, although 353 novel miRNAs but few endo-siRNAs were also identified. MARWI, a marmoset homolog of mouse MIWI and a very abundant PIWI in adult testes, associates with piRNAs that show characteristics of mouse pachytene piRNAs. As in other mammals, most marmoset piRNAs are derived from conserved clustered regions in the genome, which are annotated as intergenic regions. However, unlike in mice, marmoset piRNA clusters are also found on the X chromosome, suggesting escape from meiotic sex chromosome inactivation by the X-linked clusters. Some of the piRNA clusters identified contain antisense-orientated pseudogenes, suggesting the possibility that pseudogene-derived piRNAs may regulate parental functional protein-coding genes. More piRNAs map to transposable element (TE) subfamilies when they have copies in piRNA clusters. In addition, the strand bias observed for piRNAs mapped to each TE subfamily correlates with the polarity of copies inserted in clusters. These findings suggest that pachytene piRNA clusters determine the abundance and strand-bias of TE-derived piRNAs, may regulate protein-coding genes via pseudogene-derived piRNAs, and may even play roles in meiosis in the adult marmoset testis.     

Cloning, characterization and widespread expression analysis of testicular piRNA-like chicken RNAs

Piwi-interacting RNAs (piRNAs) are small RNAs abundant in the germline that have been implicated in germline development and maintenance of genomic integrity across several animal species including human, mouse, rat, zebrafish and drosophila. Tens of thousands of piRNAs have been discovered, yet abundant piRNAs have still not been detected in various eukaryotic organisms. This is a report on the characterization, cloning and expression profiling of piRNA-like chicken RNAs. Here, we identified 19 piRNAs, each 23–39 nucleotides long, from chicken testis using a small RNA cDNA library and T-A cloning methods. Three different pilRNAs were selected according to size, homology and secondary structure for temporal and spatial expression by Q-PCR technology in different tissues at five growth and four development stages of Chinese indigenous Rugao chickens (RG) and introduced recessive white feather chickens (RW). We found that, consistent to other organisms, pilRNA-encoding sequences within the chicken genome were asymmetrically distributed on the chromosomes while displaying a preference for intergenic regions across the genome. Interestingly, unlike miRNAs with unique stem-loop structures (mature miRNAs form stem section and the rest form loop section), distinct secondary structures of pilRNAs were predicted. In addition, chicken pilRNAs were not only abundant in the germline but also existed in somatic tissues, where, expression levels were influenced mainly by different pilRNAs, breed and gender. Taken together, our results suggest that two distinct secondary structures exist between pilRNAs and miRNAs, which may clarify the splicing and processing mechanisms of the two small RNAs are possible different. Moreover, our results suggest that pilRNAs may not only be confined to development and maintenance of the germline but may also play important roles in somatic tissues. Additionally, different pilRNAs may be involved in the unique regulatory machinery of complex biological processes.     

Identification of piRNAs in the central nervous system

Piwi-interacting RNAs (piRNAs) are small noncoding RNAs generated by a conserved pathway. Their most widely studied function involves restricting transposable elements, particularly in the germline, where piRNAs are highly abundant. Increasingly, another set of piRNAs derived from intergenic regions appears to have a role in the regulation of mRNA from early embryos and gonads. We report a more widespread expression of a limited set of piRNAs and particularly focus on their expression in the hippocampus. Deep sequencing of extracted RNA from the mouse hippocampus revealed a set of small RNAs in the size range of piRNAs. These were confirmed by their presence in the piRNA database as well as coimmunoprecipitation with MIWI. Their expression was validated by Northern blot and in situ hybridization in cultured hippocampal neurons, where signal from one piRNA extended to the dendritic compartment. Antisense suppression of this piRNA suggested a role in spine morphogenesis. Possible targets include genes, which control spine shape by a distinctive mechanism in comparison to microRNAs.     

Characterization of Sus scrofa Small Non-Coding RNAs Present in Both Female and Male Gonads

Small non-coding RNAs (sncRNAs) are indispensable for proper germ cell development, emphasizing the need for greater elucidation of the mechanisms of germline development and regulation of this process by sncRNAs. We used deep sequencing to characterize three families of small non-coding RNAs (piRNAs, miRNAs, and tRFs) present in Sus scrofa gonads and focused on the small RNA fraction present in both male and female gonads. Although similar numbers of reads were obtained from both types of gonads, the number of unique RNA sequences in the ovaries was several times lower. Of the sequences detected in the testes, 2.6% of piRNAs, 9% of miRNAs, and 10% of tRFs were also present in the ovaries. Notably, the majority of the shared piRNAs mapped to ribosomal RNAs and were derived from clustered loci. In addition, the most abundant miRNAs present in the ovaries and testes are conserved and are involved in many biological processes such as the regulation of homeobox genes, the control of cell proliferation, and carcinogenesis. Unexpectedly, we detected a novel sncRNA type, the tRFs, which are 30–36-nt RNA fragments derived from tRNA molecules, in gonads. Analysis of S. scrofa piRNAs show that testes specific piRNAs are biased for 5′ uracil but both testes and ovaries specific piRNAs are not biased for adenine at the 10^th nucleotide position. These observations indicate that adult porcine piRNAs are predominantly produced by a primary processing pathway or other mechanisms and secondary piRNAs generated by ping-pong mechanism are absent.     

抑制基因组转座子活性的小RNAs在生育调节中的作用

小RNAs可以在转录和转录后水平沉默转座子, 最近发现的几类小RNAs(piRNAs、endo-siRNAs)均具有抑制转座子活性的作用, 其中, 果蝇piRNAs、小鼠piRNAs、小鼠endo-siRNAs及其相关蛋白主要在生殖系表达, 说明小RNAs作用途径在生殖系转座子沉默中扮演着重要角色。最新的研究揭示了小RNAs、转座子沉默、生殖生育调节之间的联系, 然而其具体作用机制尚未得到阐明。文章综述了小RNAs对基因组转座子活性的控制及其在生育调节中的作用。     

PRG-1 and 21U-RNAs interact to form the piRNA complex required for fertility in C. elegans

In metazoans, Piwi-related Argonaute proteins have been linked to germline maintenance, and to a class of germline-enriched small RNAs termed piRNAs. Here we show that an abundant class of 21 nucleotide small RNAs (21U-RNAs) are expressed in the C. elegans germline, interact with the C. elegans Piwi family member PRG-1, and depend on PRG-1 activity for their accumulation. The PRG-1 protein is expressed throughout development and localizes to nuage-like structures called P granules. Although 21U-RNA loci share a conserved upstream sequence motif, the mature 21U-RNAs are not conserved and, with few exceptions, fail to exhibit complementarity or evidence for direct regulation of other expressed sequences. Our findings demonstrate that 21U-RNAs are the piRNAs of C. elegans and link this class of small RNAs and their associated Piwi Argonaute to the maintenance of temperature-dependent fertility.     

Identification of m RNA-like non-coding RNAs and validation of a mighty one named MAR in Panax ginseng

Increasing evidence suggests that long non-coding RNAs(lnc RNAs) play significant roles in plants.However,little is known about lnc RNAs in Panax ginseng C.A.Meyer,an economically significant medicinal plant species.A total of3,688 m RNA-like non-coding RNAs(mlnc RNAs),a class of lnc RNAs,were identified in P.ginseng.Approximately 40% of the identified mlnc RNAs were processed into small RNAs,implying their regulatory roles via small RNA-mediated mechanisms.Eleven mi RNA-generating mlnc RNAs also produced si RNAs,suggesting the coordinated production of mi RNAs and si RNAs in P.ginseng.The mlnc RNA-derived small RNAs might be 21-,22-,or 24-nt phased and could be generated from both or only one strand of mlnc RNAs,or from super long hairpin structures.A full-length mlnc RNA,termed MAR(multiple-function-associated mlnc RNA),was cloned.It generated the most abundant si RNAs.The MAR si RNAs were Researchpredominantly 24-nt and some of them were distributed in a phased pattern.A total of 228 targets were predicted for 71 MAR si RNAs.Degradome sequencing validated 68 predicted targets involved in diverse metabolic pathways,suggesting the significance of MAR in P.ginseng.Consistently,MAR was detected in all tissues analyzed and responded to methyl jasmonate(Me JA) treatment.It sheds light on the function of mlncRNAs in plants.     

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.     

Identification of novel non-coding RNAs as potential antisense regulators in the archaeon Sulfolobus solfataricus

By generating a specialized cDNA library from the archaeon Sulfolobus solfataricus, we have identified 57 novel small non-coding RNA (ncRNA) candidates and confirmed their expression by Northern blot analysis. The majority was found to belong to one of two classes, either antisense or antisense-box RNAs, where the latter only exhibit partial complementarity to RNA targets. The most prominent group of antisense RNAs is transcribed in the opposite orientation to the transposase genes, encoded by insertion elements (transposons). Thus, these antisense RNAs may regulate transposition of insertion elements by inhibiting expression of the transposase mRNA. Surprisingly, the class of antisense RNAs also contained RNAs complementary to tRNAs or sRNAs (small-nucleolar-like RNAs). For the antisense-box ncRNAs, the majority could be assigned to the class of C/D sRNAs, which specify 2'-O-methylation sites on rRNAs or tRNAs. Five C/D sRNAs of this group are predicted to target methylation at six sites in 13 different tRNAs, thus pointing to the widespread role of these sRNA species in tRNA modification in Archaea. Another group of antisense-box RNAs, lacking typical C/D sRNA motifs, was predicted to target the 3'-untranslated regions of certain mRNAs. Furthermore, one of the ncRNAs that does not show antisense elements is transcribed from a repeat unit of a cluster of small regularly spaced repeats in S. solfataricus which is potentially involved in replicon partitioning. In conclusion, this is the first report of stably expressed antisense RNAs in an archaeal species and it raises the prospect that antisense-based mechanisms are also used widely in Archaea to regulate gene expression.     

Cloning and expression profiling of small RNAs expressed in the mouse ovary

Small noncoding RNAs have been suggested to play important roles in the regulation of gene expression across all species from plants to humans. To identify small RNAs expressed by the ovary, we generated mouse ovarian small RNA complementary DNA (srcDNA) libraries and sequenced 800 srcDNA clones. We identified 236 small RNAs including 122 microRNAs (miRNAs), 79 piwi-interacting RNAs (piRNAs), and 35 small nucleolar RNAs (snoRNAs). Among these small RNAs, 15 miRNAs, 74 piRNAs, and 21 snoRNAs are novel. Approximately 70% of the ovarian piRNAs are encoded by multicopy genes located within the repetitive regions, resembling previously identified repeat-associated small interference RNAs (rasiRNAs), whereas the remaining approximately 30% of piRNA genes are located in nonrepetitive regions of the genome with characteristics similar to the majority of piRNAs originally cloned from the testis. Since these two types of piRNAs display different structural features, we categorized them into two classes: repeat-associated piRNAs (rapiRNAs, equivalent of the rasiRNAs) and non-repeat-associated piRNAs (napiRNAs). Expression profiling analyses revealed that ovarian miRNAs were either ubiquitously expressed in multiple tissues or preferentially expressed in a few tissues including the ovary. Ovaries appear to express more rapiRNAs than napiRNAs, and sequence analyses support that both may be generated through the "ping-pong" mechanism. Unique expression and structural features of these ovarian small noncoding RNAs suggest that they may play important roles in the control of folliculogenesis and female fertility.     

Piwis and piwi-interacting RNAs in the epigenetics of cancer

An increasing body of evidence suggests that cancer cells acquire "stem-like" epigenetic and signaling characteristics during the tumorigenic process, including global DNA hypo-methylation, gene-specific DNA hyper-methylation, and small RNA deregulation. RNAs have been known to be epigenetic regulators, both in stem cells and in differentiated cells. A novel class of small RNAs, called piwi-interacting RNAs (piRNAs), maintains genome integrity by epigenetically silencing transposons via DNA methylation, especially in germline stem cells. piRNAs interact exclusively with the Piwi family of proteins. The human Piwi ortholog, Hiwi, has been found to be aberrantly expressed in a variety of human cancers and in some, its expression correlates with poor clinical prognosis. However, there has been little investigation into the potential role that Piwi and piRNAs might play in contributing to the "stem-like" epigenetic state of a cancer. This review will highlight the current evidence supporting the importance of Piwi and piRNAs in the epigenetics of cancer and provide a potential model for the role of Piwi and piRNAs in tumorigenesis.     

The emerging role of small non-coding RNA in renal cell carcinoma

Noncoding RNAs are transcribed in the most regions of the human genome, divided into small noncoding RNAs (less than 200 nt) and long noncoding RNAs (more than 200 nt) according to their size. Compelling evidences suggest that small noncoding RNAs play critical roles in tumorigenesis and tumor progression, especially in renal cell carcinoma. MiRNA, the most famous small noncoding RNA, has been comprehensively explored for its fundamental role in cancer. And several miRNA-based therapeutic strategies have been applied to several ongoing clinical trials. However, piRNAs and tsRNAs, have not received as much research attention, because of several technological limitations. Nevertheless, some studies have revealed the presence of aberration of piRNAs and tsRNAs in renal cell carcinoma, highlighting a potentially novel mechanism for tumor onset and progression. In this review, we provide an overview of three classes of small noncoding RNA: miRNAs, piRNAs and tsRNAs, that have been reported dysregulation in renal cell carcinoma and have the potential for advancing diagnosis, prognosis and therapeutic applications of this disease.