Functional similarity analysis of human virus-encoded miRNAs

miRNAs are a class of small RNAs that regulate gene expression via RNA silencing machinery. Some viruses also encode miRNAs, contributing to the complex virus-host interactions. A better understanding of viral miRNA functions would be useful in designing new preventive strategies for treating diseases induced by viruses. To meet the challenge for how viruses module host gene expression by their encoded miRNAs, we measured the functional similarities among human viral miRNAs by using a method we reported previously. Higher order functions regulated by viral miRNAs were also identified by KEGG pathway analysis on their targets. Our study demonstrated the biological processes involved in virus-host interactions via viral miRNAs. Phylogenetic analysis suggested that viral miRNAs have distinct evolution rates compared with their corresponding genome.     

MicroRNAs and human retroviruses

MicroRNAs (miRNAs) are small non-coding RNAs that control a multitude of critical processes in mammalian cells. Increasing evidence has emerged that host miRNAs serve in animal cells to restrict viral infections. In turn, many viruses encode RNA silencing suppressors (RSS) which are employed to moderate the potency of the cell's miRNA selection against viral replication. Some viruses also encode viral miRNAs. In this review, we summarize findings from human immunodeficiency virus type 1 (HIV-1) and human T-cell leukemia virus type 1 (HTLV-1) that illustrate examples of host cell miRNAs that target the viruses, of RSS encoded by viruses, and of host cell miRNA profile changes that are seen in infected cells. This article is part of a Special Issue entitled: MicroRNAs in viral gene regulation.     

microRNAs相关新型调控技术与疾病治疗

MicroRNA（miRNA）是一类在进化中高度保守的非编码小分子单链RNA(19～25 nt）,在转录后水平调控中发挥重要作用. 越来越多的证据表明,miRNA广泛参与了机体生长发育、细胞增殖与凋亡等多种重要的生理过程,并在病毒感染、恶性肿瘤、心血管与内分泌疾病等多种病理状态下呈异常表达,影响许多疾病的发生、发展及预后. 对miRNA的表达水平进行可控性干预可能成为一种有效的治疗手段. 本文综述了目前用于干预miRNA水平的调控技术,以及疾病治疗相关给药系统的研究进展,提示miRNA相关新型调控技术具有较为广阔的临床应用前景.     

Virus, phage, transposon and their regulatory small non-coding RNAs

Many reports have been accumulated describing not a few microRNAs (miRNAs) in eukaryotes target viral genomes, whereas a number of viruses also encode miRNA genes. These small RNAs play important roles on viral infection and their replication. In germ cells, another small RNA, piRNA is reported to repress endogenous transposons. Furthermore, CRISPR RNA target virus/phage genomes in both archaea and bacteria. Therefore, small RNA is deeply involved in a broad range of biological defense systems. This system may be applied not only to control replication of viruses or phages but also provide implication on regulating the growth of microorganisms including pathogenic bacteria.     

MicroRNAs and their role in viral infection

Recently, a class of about 22 nucleotides (nt) small RNA has been discovered in many eukaryotes, termed microRNAs (miRNAs), which have a variety of functions. Many recent findings have demonstrated that viruses can also encode their own miRNAs. Meanwhile, other findings reveal a relationship between host miRNA and viral infection. These findings suggest a tight relationship between host and viral infection via miRNA pathway. This article introduces the miRNAs encoded by viruses and reviews the advances of the interaction of the mammalian host miRNAs and viral infection.     

MicroRNAs and their role in viral infection

Recently,a class of about 22 nucleotides (nt)small RNA has been discovered in many eukaryotes,termed microRNAs (miRNAs),which have a variety of functions.Many recent findings have demonstrated that viruses can also encode their own miRNAs.Meanwhile,other findings reveal a relationship between host miRNA and viral infection.These findings suggest a tight relationship between host and viral infection via miRNA pathway.This article introduces the miRNAs encoded by viruses and reviews the advances of the interaction of the mammalian host miRNAs and viral infection.     

Evolutionarily conserved function of a viral microRNA

MicroRNAs (miRNAs) are potent RNA regulators of gene expression. Some viruses encode miRNAs, most of unknown function. The majority of viral miRNAs are not conserved, and whether any have conserved functions remains unclear. Here, we report that two human polyomaviruses associated with serious disease in immunocompromised individuals, JC virus and BK virus, encode miRNAs with the same function as that of the monkey polyomavirus simian virus 40 miRNAs. These miRNAs are expressed late during infection to autoregulate early gene expression. We show that the miRNAs generated from both arms of the pre-miRNA hairpin are active at directing the cleavage of the early mRNAs. This finding suggests that despite multiple differences in the miRNA seed regions, the primary target (the early mRNAs) and function (the downregulation of early gene expression) are evolutionarily conserved among the primate polyomavirus-encoded miRNAs. Furthermore, we show that these miRNAs are expressed in individuals diagnosed with polyomavirus-associated disease, suggesting their potential as targets for therapeutic intervention.     

病毒microRNA研究进展

microRNA(miRNA)是一类存在于多细胞生物中长约21-24nt的非编码RNA分子,它们与靶mRNA分子互补结合抑制蛋白翻译或导致mRNA降解,从而调控靶基因表达。miRNA已被证实在多种代谢途径中发挥重要作用,调节包括细胞分化和分裂、细胞凋亡及癌症发生在内的多个细胞过程。利用生物信息学以及分子克隆的方法在线虫、哺乳动物以及植物中已发现超过4000条miRNA。最近在病毒中也发现有miRNA基因存在,通过对病毒miRNA靶基因的预测,推测其在病毒复制过程中发挥重要的调控作用。目前病毒编码的miRNA分子的特点、转录机制、功能、进化保守性以及病毒与宿主miRNA的关系都已有一定的了解。对于病毒相关miRNA研究的深入,必将对认识病毒-宿主相互作用以及相关疾病的治疗带来新的启示。     

常见肝炎病毒感染性疾病相关miRNA功能研究进展

病毒感染引发的疾病一直威胁着人类健康。Mi RNA是真核生物表达的一类重要的小分子RNA,可特异性的调节基因与蛋白的表达。mi RNA的研究为病毒性疾病的发生发展提供了新思路,为目前热点研究领域。随着mi RNA的研究深入,一些病毒感染中相关mi RNA的功能也被相继报道,如有些mi RNA具有抑制病毒感染宿主细胞的功能,有些mi RNA则可促进病毒在宿主细胞中的复制,有些mi RNA却参与病毒相关疾病的发生,还有些mi RNA则可作为病毒感染性疾病的特异性生物标志物。本文主要以两种常见肝炎病毒:HBV、HCV为例来系统阐述mi RNA在病毒感染中的相关功能。     

Identification of microRNAs of the herpesvirus family

Epstein-Barr virus (EBV or HHV4), a member of the human herpesvirus (HHV) family, has recently been shown to encode microRNAs (miRNAs). In contrast to most eukaryotic miRNAs, these viral miRNAs do not have close homologs in other viral genomes or in the genome of the human host. To identify other miRNA genes in pathogenic viruses, we combined a new miRNA gene prediction method with small-RNA cloning from several virus-infected cell types. We cloned ten miRNAs in the Kaposi sarcoma-associated virus (KSHV or HHV8), nine miRNAs in the mouse gammaherpesvirus 68 (MHV68) and nine miRNAs in the human cytomegalovirus (HCMV or HHV5). These miRNA genes are expressed individually or in clusters from either polymerase (pol) II or pol III promoters, and share no substantial sequence homology with one another or with the known human miRNAs. Generally, we predicted miRNAs in several large DNA viruses, and we could neither predict nor experimentally identify miRNAs in the genomes of small RNA viruses or retroviruses.     

MicroRNA调控固有免疫应答的分子机制

MicroRNA（miRNA）是近几年继siRNA之后非编码RNA研究的又一热点．它通过与靶mRNA的特异性结合,在转录后水平上对基因表达进行调控．研究表明,miRNA可能参与脊椎动物固有免疫应答的多个环节．在病原微生物感染时,它们不仅成为重要的固有免疫受体活化后的信号调节分子,而且能够直接干扰病毒复制而发挥抗病毒效应．miRNA可能与经典的固有免疫应答体系共同组成机体抵御病原微生物入侵的“第一道防线”．同时,病原微生物,特别是病毒还可以通过自己编码miRNA或者改变宿主细胞miRNA表达谱直接或间接地干扰很多宿主免疫相关基因的表达,实现逃逸机体免疫清除的目的．因此,miRNA水平的相瓦作用可能是病原微生物与其宿丰展开免疫“博弈”的重要战场．     

MicroRNA-like antivirals

Employing engineered DNA templates to express antiviral microRNA (miRNA) sequences has considerable therapeutic potential. The durable silencing that may be achieved with these RNAi activators is valuable to counter chronic viral infections, such as those caused by HIV-1, hepatitis B, hepatitis C and dengue viruses. Early use of expressed antiviral miRNAs entailed generation of cassettes containing Pol III promoters (e.g. U6 and H1) that transcribe virus-targeting short hairpin RNA mimics of precursor miRNAs. Virus escape from single gene silencing elements prompted later development of combinatorial antiviral miRNA expression cassettes that form multitargeting siRNAs from transcribed long hairpin RNA and polycistronic primary miRNA sequences. Weaker Pol III and Pol II promoters have also been employed to control production of antiviral miRNA mimics, improve dose regulation and address concerns about toxicity caused by saturation of the endogenous miRNA pathway. Efficient delivery of expressed antiviral sequences remains challenging and utilizing viral vectors, which include recombinant adenoviruses, adeno-associated viruses and lentiviruses, has been favored. Investigations using recombinant lentiviruses to transduce CD34+ hematological precursor cells with expressed HIV-1 gene silencers are at advanced stages and show promise in preclinical and clinical trials. Although the use of expressed antiviral miRNA sequences to treat viral infections is encouraging, eventual therapeutic application will be dependent on rigorously proving their safety, efficient delivery to target tissues and uncomplicated large scale preparation of vector formulations. This article is part of a special issue entitled: MicroRNAs in viral gene regulation.     

Cloning and identification of a microRNA cluster within the latency-associated region of Kaposi's sarcoma-associated herpesvirus

MicroRNAs (miRNAs) are small, noncoding regulatory RNA molecules that bind to 3' untranslated regions (UTRs) of mRNAs to either prevent their translation or induce their degradation. Previously identified in a variety of organisms ranging from plants to mammals, miRNAs are also now known to be produced by viruses. The human gammaherpesvirus Epstein-Barr virus has been shown to encode miRNAs, which potentially regulate both viral and cellular genes. To determine whether Kaposi's sarcoma-associated herpesvirus (KSHV) encodes miRNAs, we cloned small RNAs from KSHV-positive primary effusion lymphoma-derived cells and endothelial cells. Sequence analysis revealed 11 isolated RNAs of 19 to 23 bases in length that perfectly align with KSHV. Surprisingly, all candidate miRNAs mapped to a single genomic locale within the latency-associated region of KSHV. These data suggest that viral and host cellular gene expression may be regulated by miRNAs during both latent and lytic KSHV replication.     

Molecular carcinogenesis of hepatocellular carcinoma and intrahepatic cholangiocarcinoma: one step closer to personalized medicine?

Background

It remains unclear whether retroviruses can encode and express an intragenomic microRNA (miRNA). Some have suggested that processing by the Drosha and Dicer enzymes might preclude the viability of a replicating retroviral RNA genome that contains a cis-embedded miRNA. To date, while many studies have shown that lentiviral vectors containing miRNAs can transduce mammalian cells and express the inserted miRNA efficiently, no study has examined the impact on the replication of a lentivirus such as HIV-1 after the deliberate intragenomic insertion of a bona fide miRNA.

Results

We have constructed several HIV-1 molecular clones, each containing a discrete cellular miRNA positioned in Nef. These retroviral genomes express the inserted miRNA and are generally replication competent in T-cells. The inserted intragenomic miRNA was observed to elicit two different consequences for HIV-1 replication. First, the expression of miRNAs with predicted target sequences in the HIV-1 genome was found to reduce viral replication. Second, in one case, where an inserted miRNA was unusually well-processed by Drosha, this processing event inhibited viral replication.

Conclusion

This is the first study to examine in detail the replication competence of HIV-1 genomes that express cis-embedded miRNAs. The results indicate that a replication competent retroviral genome is not precluded from encoding and expressing a viral miRNA.     

Specific enrichment of miRNAs in Arabidopsis thaliana infected with Tobacco mosaic virus.

RNA silencing is a broadly conserved machinery and is involved in many biological events. Small RNAs are key molecules in RNA silencing pathway that guide sequence-specific gene regulations and chromatin modifications. The silencing machinery works as an anti-viral defense in virus-infected plants. It is generally accepted that virus-specific small interfering (si) RNAs bind to the viral genome and trigger its cleavage. Previously, we have cloned and obtained sequences of small RNAs from Arabidopsis thaliana infected or uninfected with crucifer Tobacco mosaic virus. MicroRNAs (miRNAs) accumulated to a higher percentage of total small RNAs in the virus-infected plants. This was partly because the viral replication protein binds to the miRNA/miRNA* duplexes. In the present study, we mapped the sequences of small RNAs other than virus-derived siRNAs to the Arabidopsis genome and assigned each small RNA. It was demonstrated that only miRNAs increased as a result of viral infection. Furthermore, some newly identified miRNAs and miRNA candidates were found from the virus-infected plants despite a limited number of examined sequences. We propose that it is advantageous to use virus-infected plants as a source for cloning and identifying new miRNAs.