MicroRNA precursors in motion: exportin-5 mediates their nuclear export

The discovery of microRNSs (miRNAs) has changed the paradigm of gene regulation, leaving us with numerous exciting questions regarding what these molecules do and how they originate. A model for miRNA biogenesis has emerged recently, yet several key factors--including the identity of the miRNA nuclear export receptor--remained unknown. However, recent studies have shown that exportin-5 (Exp5), a Ran-dependent importin-beta-related transport receptor, mediates nuclear export of miRNA precursors (pre-miRNAs).     

A New Short Oligonucleotide-Based Strategy for the Precursor-Specific Regulation of microRNA Processing by Dicer

The precise regulation of microRNA (miRNA) biogenesis seems to be critically important for the proper functioning of all eukaryotic organisms. Even small changes in the levels of specific miRNAs can initiate pathological processes, including carcinogenesis. Accordingly, there is a great need to develop effective methods for the regulation of miRNA biogenesis and activity. In this study, we focused on the final step of miRNA biogenesis; i.e., miRNA processing by Dicer. To test our hypothesis that RNA molecules can function not only as Dicer substrates but also as Dicer regulators, we previously identified by SELEX a pool of RNA oligomers that bind to human Dicer. We found that certain of these RNA oligomers could selectively inhibit the formation of specific miRNAs. Here, we show that these specific inhibitors can simultaneously bind both Dicer and pre-miRNAs. These bifunctional riboregulators interfere with miRNA maturation by affecting pre-miRNA structure and sequestering Dicer. Based on these observations, we designed a set of short oligomers (12 nucleotides long) that were capable of influencing pre-miRNA processing in vitro, both in reactions involving recombinant human Dicer and in cytosolic extracts. We propose that the same strategy may be used to develop effective and selective regulators to control the production of any miRNA. Overall, our findings indicate that the interactions between pre-miRNAs and other RNAs may form very complex regulatory networks that modulate miRNA biogenesis and consequently gene expression.     

A precursor microRNA in a cancer cell nucleus

In line with their broad-based effects, microRNAs (miRNAs), small non-coding RNA molecules ~22 nucleotides long that silence target mRNAs, are thought to act as oncogenes or tumor suppressor genes based on their inhibition of tumor-suppressive and oncogenic mRNAs, respectively. We and others previously showed that global downregulation of miRNAs, a common feature of human tumors, is functionally relevant to oncogenesis as impairment of miRNA biogenesis enhanced transformation in both cancer cells and a K-Ras-driven model of lung cancer. The dysregulation of miRNA biosynthesis in cancer emerges as a cancer-specific mechanism that enhances its tumorigenic capacity. These observations are further supported by the fact that frameshift mutations of TARBP2 occur in sporadic and hereditary carcinomas with microsatellite instability and that DICER1 mutations are associated with familial pleuropulmonary blastoma. Accordingly, it was reported that reduced expression of miRNA-processing factors is associated with poor prognosis in lung cancer and ovarian cancer. Recently we have also demonstrated the presence of Exportin 5 (XPO5) inactivating mutations in tumors with microsatellite instability. This observed genetic defect is responsible for nuclear retention of pre-miRNAs, thereby reducing miRNA processing. The characterized mutant form of the XPO5 protein lacks a C-terminal region that contributes to the formation of the pre-miRNA/XPO5/Ran-GTP ternary complex and the protein itself, as well as pre-miRNAs accumulating in the nucleus of cancer cells. Most importantly, the restoration of XPO5 function reverses the impaired export of pre-miRNAs and has tumor suppressor features. Our data suggest a cancer-specific mechanism to guide the subcellular distribution of miRNA precursors and prevent them from being processed to the active mature miRNA. The control of the miRNA biosynthesis pathway is emerging as an important mechanism in defining the spatiotemporal pattern of miRNA expression in cancer cells.     

A precursor microRNA in a cancer cell nucleus: Get me out of here!

In line with their broad-based effects, microRNAs (miRNAs), small non-coding RNA molecules ∼22 nucleotides long that silence target mRNAs, are thought to act as oncogenes or tumor suppressor genes based on their inhibition of tumor-suppressive and oncogenic mRNAs, respectively. We and others previously showed that global downregulation of miRNAs, a common feature of human tumors, is functionally relevant to oncogenesis as impairment of miRNA biogenesis enhanced transformation in both cancer cells and a K-Ras-driven model of lung cancer. The dysregulation of miRNA biosynthesis in cancer emerges as a cancer-specific mechanism that enhances its tumorigenic capacity. These observations are further supported by the fact that frameshift mutations of TARBP2 occur in sporadic and hereditary carcinomas with microsatellite instability and that DICER1 mutations are associated with familial pleuropulmonary blastoma. Accordingly, it was reported that reduced expression of miRNA-processing factors is associated with poor prognosis in lung cancer and ovarian cancer. Recently we have also demonstrated the presence of Exportin 5 (XPO5) inactivating mutations in tumors with microsatellite instability. This observed genetic defect is responsible for nuclear retention of pre-miRNAs, thereby reducing miRNA processing. The characterized mutant form of the XPO5 protein lacks a C-terminal region that contributes to the formation of the pre-miRNA/XPO5/Ran-GTP ternary complex and the protein itself, as well as pre-miRNAs accumulating in the nucleus of cancer cells. Most importantly, the restoration of XPO5 function reverses the impaired export of pre-miRNAs and has tumor suppressor features. Our data suggest a cancer-specific mechanism to guide the subcellular distribution of miRNA precursors and prevent them from being processed to the active mature miRNA. The control of the miRNA biosynthesis pathway is emerging as an important mechanism in defining the spatiotemporal pattern of miRNA expression in cancer cells.     

Precursor microRNA-programmed silencing complex assembly pathways in mammals

Assembly of microRNA ribonucleoproteins (miRNPs) or RNA-induced silencing complexes (RISCs) is essential for the function of miRNAs and initiates from processing of precursor miRNAs (pre-miRNAs) by Dicer or by Ago2. Here, we report an in?vitro miRNP/RISC assembly assay programmed by pre-miRNAs from mammalian cell lysates. Combining in?vivo studies in Dicer Knockout cells reconstituted with wild-type or catalytically inactive Dicer, we find that the miRNA loading complex (miRLC) is the primary machinery linking pre-miRNA processing to?miRNA loading. We show that a miRNA precursor deposit complex (miPDC) plays a crucial role in Dicer-independent miRNA biogenesis and promotes?miRNP assembly of certain Dicer-dependent miRNAs. Furthermore, we find that 5'-uridine, 3'-mid base pairing, and 5'-mid mismatches within pre-miRNAs promote their assembly into miPDC. Our studies provide a comprehensive view of miRNP/RISC assembly pathways in mammals, and our assay provides a versatile platform for further mechanistic dissection of such pathways in mammals.     

Monocyte chemoattractant protein-induced protein 1 directly degrades viral miRNAs with a specific motif and inhibits KSHV infection

Kaposi''s sarcoma-associated herpesvirus (KSHV) expresses miRNAs during latency. However, regulation of viral miRNAs remains largely unknown. Our prior studies demonstrated that MCPIP1 regulates KSHV miRNA biogenesis by degrading most KSHV pre-miRNAs through its RNase activity. Some viral pre-miRNAs are partially resistant to degradation by MCPIP1. Here, we further characterized MCPIP1 substrate specificity and its antiviral potential against KSHV infection. In vitro cleavage assays and binding assays showed that MCPIP1 cleavage efficiency is related to binding affinity. Motif-based sequence analysis identified that KSHV pre-miRNAs that are well degraded by MCPIP1 have a 5-base motif (M5 base motif) within their terminal loops and this motif region consists of multiple pyrimidine-purine-pyrimidine (YRY) motifs. We further demonstrated that mutation of this M5 base motif within terminal loop of pre-miRNAs inhibited MCPIP1-mediated RNA degradation. We also revealed that MCPIP1 has an antiviral effect against KSHV infection. MCPIP1 can reduce the expression of Dicer, which in turn restricts KSHV infection. Conclusively, our findings demonstrated that MCPIP1 inhibited KSHV infection and suppressed viral miRNA biogenesis by directly degrading KSHV pre-miRNAs and altering the expression of miRNA biogenesis factors.     

SNPs in human miRNA genes affect biogenesis and function

MicroRNAs (miRNAs) are 21–25-nucleotide-long, noncoding RNAs that are involved in translational regulation. Most miRNAs derive from a two-step sequential processing: the generation of pre-miRNA from pri-miRNA by the Drosha/DGCR8 complex in the nucleus, and the generation of mature miRNAs from pre-miRNAs by the Dicer/TRBP complex in the cytoplasm. Sequence variation around the processing sites, and sequence variations in the mature miRNA, especially the seed sequence, may have profound affects on miRNA biogenesis and function. In the context of analyzing the roles of miRNAs in Schizophrenia and Autism, we defined at least 24 human X-linked miRNA variants. Functional assays were developed and performed on these variants. In this study we investigate the affects of single nucleotide polymorphisms (SNPs) on the generation of mature miRNAs and their function, and report that naturally occurring SNPs can impair or enhance miRNA processing as well as alter the sites of processing. Since miRNAs are small functional units, single base changes in both the precursor elements as well as the mature miRNA sequence may drive the evolution of new microRNAs by altering their biological function. Finally, the miRNAs examined in this study are X-linked, suggesting that the mutant alleles could be determinants in the etiology of diseases.     

动物细胞核内miRNA的加工过程

microRNA(miRNA)是存在于真核生物中的一类大的基因家族,与其靶mRNA分子一起形成了生物体内复杂的调控网络。miRNA在基因表达调节过程中的关键性作用涉及到发育时序的控制、造血细胞的分化、细胞凋亡、细胞增殖以及器官的形成等方面。其中最值得探讨的问题是miRNA的生物发生过程及其调控机制。近年来,miRNA在动物细胞核中加工机制的研究取得了较大的进展。在细胞核中,RNA多聚酶II指导的miRNA基因的转录,微处理器作用下的pri-miRNA的剪切及exportin-5协助下的pre-miRNA的输出过程彼此协调,共同而有序的完成miRNA在细胞核中的加工过程。