H1启动子siRNA载体的构建及应用

利用双链RNA(dsRNA)调控基因表达已经成为研究基因功能的有力工具。用人H1启动子构建了pBS／H1PS小干扰RNA(siRNA)表达载体,用于在哺乳动物细胞中产生特异性dsRNA转录产物。通过对293细胞中的PSMA7分子进行表达抑制,证明该siRNA载体能够有效产生针对靶基因的RNA干扰(RNAi)效应。     

RNA干扰在疾病治疗方面的应用研究

RNA干扰是由双链RNA引起的序列特异的基因沉默现象。由于RNA干扰能在细胞组织及动物模型中沉默疾病相关基因,因此,RNA干扰也是各种疾病治疗的有效手段。在哺乳动物细胞内诱导RNA干扰可以通过导入小干扰RNA（siRNA）,或是以质粒、病毒为载体表达短的发夹RNA（shRNA）而实现。本文介绍了RNA干扰在疾病治疗方面的应用,并就其面临的挑战进行讨论。     

RNA干扰技术在哺乳动物中的应用

RNA干扰(RNAi)是生物界普遍存在的一种抵御外来基因和病毒感染的进化保守机制.RNAi是由双链RNA触发的转录后基因沉默机制,具有序列特异性,在哺乳动物细胞中,RNAi由21～23个核苷酸组成的双链RNA引发.小干扰RNA(siRNA)可以在体外合成或通过表达载体在哺乳动物细胞内合成.由于RNAi技术具有快速、简单和特异性强等特点,在基因功能研究、抗病毒治疗和抗肿瘤治疗等方面有广泛的应用前景.     

针对leader序列的siRNA能够有效抑制SARS冠状病毒多个mRNA的表达

小干扰RNAs(siRNAs)能够有效降解具有互补序列的RNA.在SARS-CoV的基因组RNA和所有亚基因组RNA的5′端均有一段共同的leader序列,而且该leader序列在不同的病毒分离物中高度保守,因此leader序列可作为一个用于抑制SARS-CoV复制的有效靶点.研究表明,针对leader序列化学合成的siRNA和DNA载体表达的shRNA都可以有效抑制SARS-CoV mRNA的表达.Leader序列特异的siRNA或shRNA不仅可以有效抑制leader与报告基因EGFP融合基因的表达,而且还可以有效抑制leader与刺突蛋白(spikeprotein)、膜蛋白(membrane protein)和核衣壳蛋白(nucleocapsid protein)基因的融合转录产物的表达.结果表明,针对leader序列的RNA干扰可以发展成为一种抗SARS-CoV治疗的有效策略.     

RNA干扰技术及其在肝纤维化中的应用

RNA干扰(RNA interference,RNAi)是近几年发展起来的新技术,是外源和内源性双链RNA在生物体内诱导同源靶基因的mRNA特异性降解,因而抑制相应基因表达,导致转录后基因沉默的现象.尽管RNA干扰发现的时间较短,但由于其具有操作简单、成本低、特异性高和高效性等特点,因而发展迅速.小干扰RNA(small interfering RNA,siRNA)的可制备使RNAi在很多领域有了应用的前景,尤其是在复杂多变的肝脏疾病中.肝纤维化(hepatic fibrosis,HF)是多种慢性肝病发展的共同病理基础,RNAi技术在其基因治疗领域拥有广阔的前景.RNAi具有能够调节细胞增殖、抑制致病基因的表达、影响细胞的信号转导等方面的作用,可能成为肝纤维化有效的潜在治疗手段.     

干扰RNA的非靶免疫副作用及其siRNA序列设计与化学修饰

siRNA介导的RNA干扰技术已经成为基因功能研究和开展疾病治疗的有用工具.近年发现,siRNA在哺乳动物体内可激活天然免疫系统,诱导干扰素等炎症因子的分泌,并且可非特异性抑制某些非靶基因的表达,有可能极大限制RNA干扰技术的应用.进行高效特异性siRNA的设计和修饰,以保持或者增强siRNA的特异性靶基因沉默作用,又消除siRNA对机体的非靶免疫副作用,成为使siRNA安全有效应用于临床治疗的关键.     

表达siRNA的重组腺相关病毒载体的构建和鉴定

腺相关病毒(AAV)载体介导的RNA干扰(RNAi)可在哺乳动物细胞中长期特异性抑制同源基因表达。本研究以AAV Helper-Free System中的转移质粒pAAV-MCS为基础,引入增强型绿色荧光蛋白(EGFP)基因和H1启动子,将该质粒改造为可表达小干扰RNA(siRNA)和EGFP的质粒pAAV-EGFP-H1。该质粒与辅助质粒共转染包装细胞后,获得了具有感染性的重组AAV(rAAV)。以EGFP为靶基因的干扰实验证明:所得rAAV可以产生siRNA并能够特异性抑制EGFP靶基因表达;荧光显微镜观察、FACS分析和Real-time PCR方法均表明重组病毒rAAV-H1-sh EGFP引起EGFP的表达降低大于60%。     

Spl基因RNA干扰载体的构建及鉴定

目的:构建干扰载体pSilencer 3.1-spl,并初步研究其对Spl基因的干扰作用.方法:根据Spl cDNA编码序列,设计并合成针对Spl基因的特异性RNA干扰片段,并将其克隆入pSilencer 3.1-Hl neo干扰载体中,构建Spl基因小干扰RNA(siRNA)真核表达载体pSilencer 3.1-Spl;分别将阴性对照载体pSilencer 3.1与重组载体pSilencer 3.1-Spl经脂质体LipofectAMINE2000介导转染HeLa细胞,采用RT-PCR、Western blot方法分别检测Spl基因的转录与表达水平.结果:构建了Spl基因siRNA真核表达载体pSilencer 3.1-Spl,经酶切、测序鉴定证实克隆正确,并在mRNA水平和蛋白水平证实了载体的干扰效果.结论:特异性siRNA能明显抑制Spl基因在HeLa细胞中的表达,为进一步研究Spl的生物学功能和作用机制奠定了实验基础.     

利用人U6 snRNA启动子构建RNA干扰质粒载体

RNA干扰技术已经成为基因功能研究等领域的有力工具,构建带有筛选标记的siRNA载体可以在细胞中持续抑制靶基因的表达.为了利用RNAi技术开展生物学研究,在克隆载体pUC19的基础上改造构建了人类细胞小干扰RNA（small interference RNA,siRNA）表达质粒pUC19NU.该质粒具有新霉素抗性标记和真核细胞复制起点,利用连入的人U6 snRNA启动子起始siRNA的转录.以EGFP 和p53为靶基因的干扰实验证明,所构建的siRNA表达质粒可以显著抑制细胞外源性增强绿色荧光蛋白（enhanced green fluorescent protein,EGFP）及细胞内源性p53蛋白的表达,而且抑制效果具有特异性.     

RNA聚合酶Ⅱ启动子调控RNA 干扰在肿瘤治疗中的应用前景

RNA干扰是双链RNA介导的特异性转录后基因表达沉默现象.由于双链小干扰RNA介导的RNA干扰技术设计简便、作用迅速、效果明显,目前已被广泛应用于基因功能和重大疾病治疗的研究,尤其为肿瘤治疗提供了一条新途径.利用RNA干扰技术通过调节肿瘤发生发展相关基因的表达可制定出一系列有效的抗癌策略.然而在现行大多数策略中往往采用不可调控的RNA聚合酶Ⅲ启动子(H1,U6)表达经典的发夹结构RNA,经由Dicer酶切割成功能性siRNA,因此缺乏组织细胞靶向性和抗癌效率.最新研究表明,采用RNA聚合酶Ⅱ启动子可弥补由RNA聚合酶Ⅲ启动子调控RNA干扰缺陷和不足.此外,运用病毒载体特别是具有靶向和溶瘤效应的肿瘤特异性复制腺病毒,介导RNA聚合酶Ⅱ启动子调控表达siRNA有望成为更有效的治疗手段.     

Genome-wide application of RNAi to the discovery of potential drug targets

Progress is being made in the development of RNA interference-based (RNAi-based) strategies for the control of gene expression. It has been demonstrated that small interfering RNAs (siRNAs) can silence the expression of target genes in a sequence-specific manner in mammalian cells. Various groups, including our own, have developed systems for vector-mediated specific RNAi. Vector-based siRNA- (or shRNA) expression libraries directed against the entire human genome and siRNA libraries based on chemically synthesized oligonucleotides now allow the rapid identification of functional genes and potential drug targets. Use of such libraries will enhance our understanding of numerous biological phenomena and contribute to the rational design of drugs against heritable, infectious and malignant diseases.     

多种小分子干扰RNA联合抑制乙型肝炎病毒的体外研究

小分子干扰RNA(siRNA)能够在哺乳动物细胞中引起包括病毒基因在内的基因沉默。为了研究多种siRNA联合应用在体外抑制乙型肝炎病毒(HBV)复制中的效果,本研究设计了12种针对不同HBV靶点的siRNA,转染可稳定分泌HBV颗粒的HepG22.2.15细胞,并采用了酶联免疫法检测上清液中HBsAg和HBeAg的含量,实时定量PCR法检测细胞中HBV的DNA含量。结果发现这12种分子均能在不同程度上抑制病毒复制。进一步研究表明它们对HBV的抑制作用在一定程度上存在剂量效应和协同作用,单分子siRNA在80nmol/L处对HBsAg和HBeAg的抑制率分别可达到约80%和60%,而多分子siRNA组合在20nmol/L处对HBsAg就能达到90%的抑制率,但对HBeAg表达的抑制率提高不明显。单分子siRNA在80nmol/L处对HBVDNA复制的抑制率可达到90%以上,而多分子siRNA组合在20nmol/L处对DNA含量就能达到约90%的抑制率。本研究的结果为进一步开发新的联合应用多种siRNA治疗HBV的途径打下了基础。     

The effects of thiophosphate substitutions on native siRNA gene silencing

RNA mediated interference has emerged as a powerful tool in controlling gene expression in mammalian cells. We investigated the gene silencing properties of six thiophosphate substituted siRNAs (all based on a commercial luciferase medium silencer) compared to that of unmodified siRNA. We also examined the cytotoxicity and dose-response using several thiophosphate modified siRNAs with unmodified siRNA. Our results show that two thiophosphate siRNA sequences convert from medium to high silencers with the addition of four randomly placed thiophosphates. Both thiophosphate siRNAs have a statistically significant difference in luciferase gene silencing (5% and 6% activity) relative to the unmodified native medium silencer referred to as siRNA-2 (18% activity) and four other thiophosphate siRNAs that maintain their medium silencing capability. This indicates that specific thiophosphate substitutions may alter native siRNA function. Further, this shows that thiophosphate siRNAs with the same nucleotide sequence but with different sulfur modification positions have different silencing effects. Both the native siRNA and the thio siRNAs showed a concentration dependent relationship, i.e., with concentration increase, the luciferase gene silencing effect also increased. Confirming cytotoxicity experiments showed no significant changes when HeLa cells were treated with 10nM thiophosphate siRNAs over the course of several days. These results suggest that specific placement of thiophosphates could play an important role in the development of siRNAs as therapeutics by engineering in properties such as strength of binding, nuclease sensitivity, and ultimately efficacy.     

Specific gene silencing using small interfering RNAs in fish embryos

Recently, small interfering RNAs (siRNAs) have been used for gene knockdown in mammalian cultured cells, but their utility in fish has remained unexplored. Here we demonstrate a siRNA-mediated gene silencing technique in rainbow trout embryos. We found that siRNAs effectively suppressed the transient expression of episomally located foreign GFP genes at an early developmental stage and inhibited the expression of GFP genes in stable transgenic trout embryos. Similar gene silencing was observed with an siRNA against the endogenous tyrosinase A gene. siRNAs interfered with the expression of maternally inherited mRNA. siRNAs did not affect non-relevant gene expression and siRNAs with a 4 base mismatch did not affect target gene expression. siRNA gene silencing is therefore highly sequence-specific. Our findings are the first evidence that siRNA-mediated gene silencing is effective in fish. This technique could be a powerful tool for studying gene function during embryonic development in aquacultural fish species, zebrafish, and medaka.     

A simple strategy for generation of gene knockdown constructs with convergent H1 and U6 promoters

RNA interference (RNAi) is a powerful tool for functional genetic studies in model organisms and mammalian cells. To facilitate rapid construction of gene knockdown constructs and RNAi libraries for known genes of mammalian cells, a new and simple strategy to produce small interfering RNA (siRNA) expression vectors with two opposing polymerase III promoters was developed. The design involved a one-step PCR amplification and single cloning procedure to construct a dual promoter siRNA expression vector. The forward primer is identical for all PCR reactions, only a single reverse primer that contains the siRNA targeting sequence has to be synthesized in the construction of each individual vector. This single primer design is cost-effective and it reduces the risk of sequence errors during synthesis of long oligos. Sense and antisense strands of siRNA duplexes were transcribed from the same template and this eliminated the need to synthesize long hairpin-forming oligonucleotides. Our study demonstrated that this vector design could mediate potent inhibition of expression of both exogenous and endogenous genes in mammalian cells.     

Milligram scale production of potent recombinant small interfering RNAs in Escherichia coli

Small interfering RNAs (siRNAs) are invaluable research tools for studying gene functions in mammalian cells. siRNAs are mainly produced by chemical synthesis or by enzymatic digestion of double‐stranded RNA (dsRNA) produced in vitro. Recently, bacterial cells, engineered with ectopic plant viral siRNA binding protein p19, have enabled the production of “recombinant” siRNAs (pro‐siRNAs). Here, we describe an optimized methodology for the production of milligram amount of highly potent recombinant pro‐siRNAs from Escherichia coli cells. We first optimized bacterial culture medium and tested new designs of pro‐siRNA production plasmid. Through the exploration of multiple pro‐siRNA related factors, including the expression of p19 protein, (dsRNA) generation method, and the level of RNase III, we developed an optimal pro‐siRNA production plasmid. Together with a high–cell density fed‐batch fermentation method in a bioreactor, we have achieved a yield of ~10 mg purified pro‐siRNA per liter of bacterial culture. The pro‐siRNAs produced by the optimized method can achieve high efficiency of gene silencing when used at low nanomolar concentrations. This new method enables fast, economical, and renewable production of pure and highly potent bioengineered pro‐siRNAs at the milligram level. Our study also provides important insights into the strategies for optimizing the production of RNA products in bacteria, which is an under‐explored field.     

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。