Pegtel D Michiel, van de Garde Martijn D B, Middeldorp Jaap M
VU University Medical Center, Department of Pathology, Amsterdam, the Netherlands.
Biochim Biophys Acta. 2011 Nov-Dec;1809(11-12):715-21. doi: 10.1016/j.bbagrm.2011.08.002. Epub 2011 Aug 9.
The class of persistent gamma-herpesviruses has developed a variety of strategies that exploit host-cell regulatory pathways to ensure a long-lasting, well-balanced infection of their host. However when these pathways are deregulated, an otherwise harmless infection can lead to disease including cancer. We recently demonstrated that the human herpes virus 4 (HHV4) also known as Epstein-Barr virus (EBV), encodes for small regulatory non-coding microRNAs (miRNAs) that can be transferred from an infected cell to uninfected neighboring cells. Upon arrival these miRNAs are functional in the recipient cell, in that they are able to down regulate specific target genes. These secreted miRNAs are transported to recipient cells via small nano-sized vesicles (known as exosomes) that are of endosomal origin, formed as intraluminal vesicles (ILV) inside multivesicular bodies (MVB). One question that needs to be addressed is how viral miRNAs are sorted into these exosomes. Mature miRNAs, including those of viral origin, are loaded into RNA-induced silencing complexes (RISC) for gene silencing via blocking mRNA translation and/or initiating mRNA decay. Recent insights indicate that cytoplasmic RNA granules rich in RISC complexes are closely associated with endosomes. In fact, selective components of RISC, including GW182 and Argonaut proteins, miRNAs and mRNAs are present in exosomes. Thus miRNA function, mRNA stability and exosome-mediated intercellular communication converge at the level of endosomes. Since endosomes can be considered as key intracellular cross-roads that regulate communication of cells with their exterior, including neighboring cells, it is perhaps not surprising that viruses have found means to exploit this pathway to their benefit. Little is known however, how and if (micro) RNA species are specifically sorted into ILVs and what (micro)RNA-binding proteins are involved. Here we discuss recent developments relating to intracellular trafficking and function of miRNA-containing protein complexes that EBV may exploit for promoting or restricting miRNAs sorting into exosomes for intercellular regulatory functions. This article is part of a Special Issue entitled: MicroRNAs in viral gene regulation.
持久性γ-疱疹病毒已经发展出多种策略,利用宿主细胞的调控途径来确保对宿主进行持久且平衡良好的感染。然而,当这些途径失调时,原本无害的感染可能会导致包括癌症在内的疾病。我们最近证明,人类疱疹病毒4(HHV4),也称为爱泼斯坦-巴尔病毒(EBV),编码小的调节性非编码微小RNA(miRNA),这些miRNA可以从受感染细胞转移到未受感染的邻近细胞。到达后,这些miRNA在受体细胞中发挥作用,因为它们能够下调特定的靶基因。这些分泌的miRNA通过小的纳米级囊泡(称为外泌体)运输到受体细胞,这些囊泡起源于内体,在多泡体(MVB)内作为腔内囊泡(ILV)形成。一个需要解决的问题是病毒miRNA如何被分选到这些外泌体中。成熟的miRNA,包括那些病毒来源的miRNA,被加载到RNA诱导沉默复合体(RISC)中,通过阻断mRNA翻译和/或启动mRNA降解来实现基因沉默。最近的研究表明,富含RISC复合体的细胞质RNA颗粒与内体密切相关。事实上,RISC的选择性成分,包括GW182和AGO蛋白、miRNA和mRNA都存在于外泌体中。因此,miRNA功能、mRNA稳定性和外泌体介导的细胞间通讯在内体水平上汇聚。由于内体可以被视为调节细胞与其外部(包括邻近细胞)通讯的关键细胞内交叉点,病毒找到利用这条途径为自身谋利的方法也许并不奇怪。然而,关于(微小)RNA种类如何以及是否被特异性分选到ILV中,以及涉及哪些(微小)RNA结合蛋白,我们知之甚少。在这里,我们讨论了与含miRNA蛋白复合体的细胞内运输和功能相关的最新进展,EBV可能利用这些进展来促进或限制miRNA分选到外泌体中以实现细胞间调节功能。本文是名为:病毒基因调控中的微小RNA的特刊的一部分。
