RNA干扰非特异性研究进展

RNA干扰(RNAi)靶向基因治疗是目前研究的热点,其依赖序列特异性的基因表达调节为生物学发展带来重大突破.然而在应用RNAi时所产生的一系列非特异性反应阻碍了RNAi进一步的临床应用,这其中主要包括脱靶基因抑制和内在免疫副反应等.主要从非特异性反应的产生机制、脱靶效应的预测和RNAi非特异性的控制3个方面对近几年研究成果进行综述,探讨临床应用前景.     

RNA干扰机制研究进展

RNAi是多种生物体内由dsRNA介导的同源mRNA降解现象。这是一个高度特异化的过程,涉及多种蛋白质的共同参与。在这一过程中,siRNA的结构影响其两条链装配到RISC中去的能力。除了与RISC结合外,siRNA还引导了RITS复合物结合到同源染色质,介导异染色质化过程。干扰效应的扩散,即系统性沉默可能依赖于跨膜蛋白的转运,并且很可能是在多因素调控下完成的。Abstract: RNA interference (RNAi) is a phenomenon that the double-stranded RNA (dsRNA) intermediates the degradation of complementary mRNA found in many organisms. This is a specifically mechanism involved in kinds of proteins to complete the interference function. Structure of siRNA affects which strand will be assembled into RISC. Another role of siRNA is directing RITS complex to bind with homologue chromosome, and then induces heterochromatinization. Although systemic silence induced by dsRNA is observed in Caenorhabditis elegans and plants, this progress is probably transmembrane protein-dependent, and mostly, the systemic silencing is controlled by multi-factors.     

干扰小RNA序列非依赖性地影响胰腺癌细胞的基因表达

干扰小RNA(small interference RNA, siRNA)是基因敲减的常用工具,广泛用于基因沉默技术和基因功能研究,在临床疾病治疗等方面也有潜在的应用。一般认为,达到一定长度（比如大于27 bp）的双链RNA可以诱导干扰素反应,降低相关基因的表达。目前,siRNA对基因表达的非特异性作用尚不完全清楚。为研究siRNA干扰的非特异基因表达,本研究以胰腺癌细胞HPAC 和BxPC3 为模型,采用高通量测序技术对6种不同干扰小RNA处理及未作处理的HPAC和BxPC3细胞进行转录组测序分析,筛选出干扰小RNA处理后表达量共同下调的基因进行研究。通过生物信息学方法对表达下调基因的功能进行研究,并利用实时荧光定量PCR(qRT-PCR)技术对部分下调基因进行验证。结果表明,短片段双链小RNA能够显著改变细胞的基因表达,而这些基因表达谱的变化是有规律的,特定功能的基因优先发生变化。在表达下调的基因中,某些特定类型的基因变化非常显著,包括氨基酸代谢相关基因、Hedgehog信号途径基因和多巴胺受体D5基因等。这些结果表明,在使用siRNA时需要考虑其序列非依赖性地基因表达调控作用。     

RNA干扰研究进展

RNA干扰(RNA interference,RNAi)是指由双链RNA(double-strandedRNA,dsRNA)启动的序列特异的转录后基因沉默现象,广泛存在于真菌、植物和动物中。它是细胞内由双链RNA诱导降解与其配对的特定mRNA的过程。细胞内双链RNA在酶的作用下,形成20-25碱基大小的小干扰RNA(siRNAs),由siRNAs进一步掺入多组分核酸酶并使其激活,从而精确降解与siRNAs序列相同的mRNA,抑制该基因在细胞内的翻译表达。RNAi技术是近年来迅速发展起来的高效、特异、易操作的基因沉默技术。与反义寡核苷酸等传统方法相比,RNAi技术有着无可比拟的优势。本文就其近年的研究进展作一综述。     

RNA干扰抗病毒感染

RNA干扰是由双链RNA诱导的、关闭同源序列基因表达的机制。它是一种自然存在于植物、线虫、果蝇等真核细胞生物中的抵抗病毒感染方式。随着在哺乳动物细胞培养中成功地诱导RNA干扰,利用RNA干扰预防、治疗病毒感染已成为新的研究热点,并取得了有希望的成果。在未来,有望成为抗病毒感染的有效方法。     

RNA干扰与技术

RNA干扰(RNA interference,RNAi)是由双链RNA诱导的、序列特异的基因沉默机制。它是自然存在于植物、线虫和果蝇中抵抗外来基因(包括病毒、转座子)入侵的方式。在哺乳动物细胞中,能够人工诱导RNA干扰,沉默有同源序列基因表达。这一新技术具有特异性、高效性。因此,正被用来研究人类基因组的功能、肿瘤和抗病毒感染等。     

病毒siRNA介导的RNA干扰途径与机制

RNA干扰(RNAi)是真核生物体内重要的基因表达调控方式之一.RNAi的一种原始的作用是帮助生物体抵抗病毒,早期的研究表明无脊椎动物可以利用RNAi抵抗病毒,但是哺乳动物是否存在这一机制一直存在争议.最新的研究发现了哺乳动物RNAi抗病毒的强有力的证据,并且研究人员认为,这是一种之前被忽视的、全新的免疫途径.值得注意...     

RNA干扰技术治疗疾病

RNA干扰(RNA interference,RNAi)现象最早发现于秀丽隐杆线虫(Caenorhabditis elegans),随后发现该现象普遍存在于真菌、植物和哺乳动物等真核生物,并行使基因调控和抵御外源基因片段侵袭的作用。目前,RNAi分子机制和RNAi在基因功能方面的研究已经取得了突破性的进展。鉴于RNAi在基因沉默中的特异性、高效性和易操作,其在药物筛选和疾病治疗等方面有着广泛的应用前景。然而,RNAi技术用于治疗疾病的安全性尚待确定,分子传递途径也有待进一步的研究。     

RNA interference in immune cells by use of osmotic delivery of siRNA

Delivery of siRNA to immune cells has been one of the major obstacles to widespread application of RNAi in the immunology field. Here, we report that osmotic delivery of siRNA can be used to silence genes in macrophage RAW264.7 without incurring either cytotoxic or immunomodulatory activity. We also showed usefulness of the osmotic delivery in other types of cells including T cell DO11.10. By repeated osmotic delivery of siRNA, long-term gene silencing was readily achieved. When TLR4 was disrupted in RAW264.7 cells for 48 h and the cells were stimulated with the TLR4 ligand LPS, a significant decrease in TNFalpha production was observed. DNA microarray-based gene expression profile analysis showed that gene silencing by osmotic delivery of siRNA was target-specific and the delivery method itself had little influence on overall gene expression.     

Inhibition of virus replication by RNA interference

RNA interference (RNAi) is a sequence-specific gene-silencing mechanism in eukaryotes, which is believed to function as a defence against viruses and transposons. Since its discovery, RNAi has been developed into a widely used technique for generating genetic knock-outs and for studying gene function by reverse genetics. Additionally, inhibition of virus replication by means of induced RNAi has now been reported for numerous viruses, including several important human pathogens such as human immunodeficiency virus type 1, hepatitis C virus, hepatitis B virus, dengue virus, poliovirus and influenza virus A. In this review, we will summarize the current data on RNAi-mediated inhibition of virus replication and discuss the possibilities for the development of RNAi-based antiviral therapeutics.     

RNA interference induced by siRNAs modified with 4'-thioribonucleosides in cultured mammalian cells

Short interfering RNAs (siRNAs) variously modified with 4'-thioribonucleosides against the Photinus luciferase gene were tested for their induction of the RNA interference (RNAi) activity in cultured NIH/3T3 cells. Results indicated that modifications at the sense-strand were well tolerated for RNAi activity except for full modification with 4'-thioribonucleosides. However, the activity of siRNAs modified at the antisense-strand was dependent on the position and the number of modifications with 4'-thioribonucleosides. Since modifications of siRNAs with 4'-thioribonucleosides were well tolerated in RNAi activity compared with that of 2'-O-methyl nucleosides, 4'-thioribonucleosides might be potentially useful in the development of novel and effective chemically modified siRNAs.     

RNA干扰在疾病治疗上的应用

RNA干扰(RNA interference,RNAi)是一种双链RNA分子在mRNA水平上引发的特异性基因沉默现象。RNAi在基因治疗方面表现出了光明的前景,已成功地应用于多种疾病的临床治疗。本文主要介绍了RNAi在疾病治疗上的应用及研究进展。     

Coexpression of Escherichia coli RNase III in silkworm cells improves the efficiency of RNA interference induced by long hairpin dsRNAs

Abstract Long hairpin dsRNA transcribed from chromosomal DNA can induce RNA interference in Bombyx mori cells, although its gene silencing efficiency is lower than that of exogenously introduced double‐stranded RNAs (dsRNAs). To solve this problem, we monitored the nuclear cytoplasmic translocation of the transcribed hairpin dsRNA and analyzed the processing efficiency into mature small interfering RNA (siRNA). Northern blot analysis revealed that the transcribed hairpin dsRNAs were spliced and transported into the cytoplasm, but were not effectively diced into siRNAs. Interestingly, RNAi with hairpin dsRNAs from genome‐integrated IR transgene was stimulated by the coexpression of Escherichia coli RNase III, although this exogenous enzyme seemed to bring about nonspecific cleavage of cellular mRNA.     

The response of mammalian cells to double-stranded RNA

Double-stranded RNA (dsRNA) has long been recognized as a central component of the interferon (IFN) system. It was originally characterized as a key mediator of IFN induction in response to virus infection. Subsequently, it was identified as a prime activator of the antiviral response. In recent years the discovery of the RNA interference (RNAi) pathway in mammals has renewed interest in dsRNA-mediated cellular responses. This has coincided with the identification of key components of the IFN induction pathway. Here, we present an overview of the current knowledge of dsRNA-mediated pathways in mammalian cells and introduce a link between these pathways and application of RNAi.     

RNA干涉技术

RNA干涉(RNAi)技术是利用一些小的双链RNA来高效、特异地阻断体内特定基因的表达,并促使mRNA降解,从而诱使细胞表现出特定基因缺失的表型。本从RNAi技术的历史、作用机制、研究策略、研究现状及应用前景等几个方面进行了综述,预测RNAi将会给基因治疗的发展带来新的希望。