RNA干扰与抗病毒感染

RNA干扰(RNAi)是由小干扰RNA(siRNA)引发的生物细胞内同源基因的转录后基因沉默(PTGS)现象,是一种古老的生物抵抗外在感染的防御机制。RNAi因其在维持基因组稳定、调控基因表达和保护基因组免受外源核酸侵入等方面发挥的重要作用,已被广泛用于探索基因功能、基因治疗和新药的研发。外源导入siRNA引发的RNAi可以特异性抑制病毒的复制与感染,为抗病毒感染治疗开辟了一条新的途径。     

基因枪在RNA干扰中的应用研究进展

RNA干扰（RNA interference,RNAi）是指双链RNA（double-strand RNA,dsRNA）特异性降解同源mRNA,从而引发基因转录后水平沉默的现象,是一种高效、高特异性抑制基因表达的途径。自1998年Fire等发现RNA干扰现象以来,其特异性降解目的基因的优势吸引了众多研究者的目光。本文在简要综述RNAi技术在基因功能研究、抗病毒治疗,肿瘤基因治疗等领域的应用后,重点归纳了基因枪技术在RNAi研究即siRNA导入细胞中的应用,并简单分析其优势与意义。     

小干扰RNA对庚型肝炎病毒基因在人Huh-7细胞中表达的抑制作用

RNA干扰(RNAi)是由小干扰RNA(siRNA)引发的生物细胞内同源基因的转录后基因沉默现象, 是近年来兴起的一项研究生物基因调控与功能的崭新技术. 庚型肝炎病毒(HGV)是一单正链RNA病毒, 复制时不与宿主细胞基因组整合, 尤其适合用于RNAi的研究. 构建了含HGV完整结构基因并携带筛选标志潮霉素基因的真核表达载体pVAX.EH, 转染Huh-7细胞后, 筛选获得稳定表达HGV 结构蛋白的Huh-7细胞株(Huh-7-EH). RT-PCR和Western blot检测证实, HGV结构基因能在Huh-7-EH细胞中转录、表达, 并能进行剪切和翻译后修饰. 以体外转录法制备了2对靶向HGV E2基因的siRNA(1-E2 siRNA和2-E2 siRNA), 将其导入Huh-7-EH细胞中, 采用Western blot和克隆形成实验证实, HGV 1-E2 siRNA和2-E2 siRNA均能特异性抑制HGV结 构蛋白的表达, 抑制作用可维持1周以上. 其中2-E2 siRNA的抑制作用更强, 转染后对Huh-7-EH细胞潮霉素抗性克隆形成的抑制率达到了99%. Huh-7-EH细胞转染siRNA后对潮霉素敏感, 说 明HGV E2 siRNA不仅使HGV E2区的mRNA降解, 还可使融合在HGV E2区下游的潮霉素mRNA降解. 综上所述, 本实验建立的稳定表达HGV结构蛋白的Huh-7-EH细胞株, 能作为用于研究HGV复制和RNAi的细胞模型; HGV结构基因区的siRNA可同时抑制HGV结构蛋白及其下游的潮霉素基因的表达, 证明RNAi在真核细胞Huh-7-EH内可能存在放大作用.     

肿瘤治疗的新领域--siRNA

siRNA(short interference RNA,siRNA)是21～23nt的短双链RNA,将哺乳动物细胞内特异基因的mRNA特异性降解而使基因失活,引起转录后沉默该基因的作用。本文针对siRNA在肿瘤治疗中的研究现状进行综述。     

siRNA诱导的DNA甲基化与肿瘤的发生

siRNA诱导的基因沉默最早只被认为是发生在细胞质内的转录后水平的调控过程,随着siRNA指导DNA甲基化现象的发现,已证实siRNA可以通过指导基因组表观修饰引起转录水平基因沉默.DNA甲基化曾被预言是致癌作用的一种表观遗传学机制,肿瘤发生过程中抑瘤基因异常沉默涉及到基因启动子区域DNA的甲基化.分析了这两个过程中内在的关系,探索siRNA对肿瘤细胞中基因异常表达的影响和作用.这将有助于肿瘤生物学和表观遗传学的研究,也会为研发防治肿瘤的新方法和新途径提供新的思路.     

siRNA的体内递送

siRNA是一种由siRNA介导的转录后基因沉默。自利用RNAi沉默目的基因获得成功以来, 体内应用RNAi的研究受到高度重视。由于siRNA本身的不稳定性以及体内的复杂环境, siRNA递送的安全性与有效性成为目前关注的重点。文章就目前报道的siRNA体内递送方式进行了综述。     

针对SARS冠状病毒重要蛋白的siRNA设计(英)

RNA干涉(RNA interference, RNAi)是一种特异性地导致转录后基因沉默的现象,在哺乳动物细胞中小分子干扰RNA双链体(small interfering RNA duplexes, siRNA duplexes)可以有效地诱导RNAi现象,为一些疾病的治疗开辟了新的途径.针对SARS冠状病毒(SARS coronavirus, SARS-CoV)中编码5个主要蛋白质的基因,用生物信息学的方法设计了348条候选siRNA靶标.在理论上,相应的siRNA双链体能特异地抑制SARS-CoV靶基因的表达,同时不会影响人体细胞基因的正常表达,这为进一步siRNA类药物的实验研究提供了理论基础.     

针对SARS冠状病毒重要蛋白的siRNA设计(英文)

NA干涉 (RNAinterference ,RNAi)是一种特异性地导致转录后基因沉默的现象 ,在哺乳动物细胞中小分子干扰RNA双链体 (smallinterferingRNAduplexes ,siRNAduplexes)可以有效地诱导RNAi现象 ,为一些疾病的治疗开辟了新的途径 .针对SARS冠状病毒 (SARScoronavirus ,SARS CoV)中编码 5个主要蛋白质的基因 ,用生物信息学的方法设计了3 48条候选siRNA靶标 .在理论上 ,相应的siRNA双链体能特异地抑制SARS CoV靶基因的表达 ,同时不会影响人体细胞基因的正常表达 ,这为进一步siRNA类药物的实验研究提供了理论基础     

Efficient regulation of viral replication by siRNA in a non-human primate surrogate model for hepatitis C

RNA interference (RNAi) represents a new technology which could offer potential applications for the therapeutics of human diseases. RNAi-mediated therapy has recently been shown to be effective toward infectious diseases in in vitro and rodent models, however, it remains unclear whether RNAi therapy with systemic application could be effective in primates. In this study, we examined if RNAi therapy could be effective toward infectious diseases by using a non-human primate surrogate model for hepatitis C. Administration into marmosets of cationic liposome-encapsulated siRNA (CL-siRNA) for GB virus B (GBV-B), which is most closely related to hepatitis C virus, repressed GBV-B replication in a dose-dependent manner. Especially, 5 mg/kg of the CL-siRNA completely inhibited the viral replication. Since the serum interferons (IFNs) were induced by CL-siRNA in vivo, inhibition of viral regulation by anti-GBV-B CL-siRNA may include an antiviral effect of IFN. However, contribution of induced IFN may be partial, since the control CL-siRNA which induced a stronger IFN response than GBV-B CL-siRNA could only delay the viral replication. Our results suggest the feasibility of systemic administration of CL-siRNA as an antiviral strategy.     

Anti-coxsackieviral efficacy of RNA interference is highly dependent on genomic target selection and emergence of escape mutants

Enteroviral diseases are widespread and impose significant importance in medicine. Although the outcome of diseases that are associated with enteroviruses such as myocarditis, pancreatitis, hepatitis, or encephalomyelitis might be fatal, no specific antiviral therapy is yet available. We and others have shown that RNA interference (RNAi) effectively limits picornaviral replication and cytopathogenicity and improves survival in susceptible mice. However, little is known about the dependence of short interfering RNA (siRNA) efficacy on target region selection and emergence of viral escape mutants that may limit the effect of RNAi. The results of our study indicate that antiviral siRNA should be targeted preferentially to nonstructural protein coding regions because siRNA efficacy was consistently found to be superior compared to noncoding or structural protein coding regions. Further more, emergence of viral escape mutants that harbor single point mutations in the central part of the siRNA binding motif are the major factor that limits early therapeutic siRNA efficacy. The appearance of viral escape mutants can be sufficiently suppressed by combined administration of at least three distinct siRNA molecules. Therefore, genomic target selection and viral escape mutants are the most critical factors that limit early RNAi directed against enteroviral genomes. Both obstacles can be circumvented by appropriate target selection and combined siRNA administration.     

Potent and specific inhibition of retrovirus production by coexpression of multiple siRNAs directed against different regions of viral genomes

siRNA-mediated RNA degradation has been demonstrated to act as an antiviral system in many species. Here we describe inhibition of retrovirus production by multiple siRNAs designed to target various regions of the viral genomes. Using murine leukemia virus (MuLV) as a model, we demonstrate that the virus production can be inhibited by 77% in siLTR2 (a siRNA targeting the U3 region of MuLV) expression vector transfected cells. Coexpression of siLTR2 with siPsi2 (a siRNA targeting the 3' Psi (packaging signal sequence) results in 93% suppression of the virus production, suggesting that an increased inhibition of the virus production can be achieved by coexpression of multiple siRNAs to target different regions of the viral RNA simultaneously. Our results also indicate that not all sequences of the viral RNA are equally accessible to siRNA. We show that U3 region of MuLV is more accessible to siRNA, whereas the packaging signal sequence, especially the region adjacent to 5'LTR, is less accessible to siRNA, partly as a result of the binding of Gag precursors. Furthermore, we demonstrate that coexpression of siLTR2 with siPsi2 in virus producer cells leads to 88% knockdown of viral titer, showing the benefit of coexpression of multiple siRNAs for potent suppression of virus production in the setting of an established infection. Moreover, we demonstrate that infection of MuLV in cells that stably coexpress siLTR2 with siPsi2 diminishes by 77%. Taken together, we establish that siRNA-mediated gene silencing can suppress multiple steps of the retrovirus life cycle, offering a potential for both treating virus-associated diseases and preventing viral infection.