反义RNA网络──一种新假说

根据核酸的基本特性和最新研究成果,提出了一种新的假说──反义RNA网络：生物体内存在着许许多多小分子的基因组反义RNA以及与之互补的反反义RNA片段,由于机体的自身修饰作用（或其它机理）,它们彼此不发生复性或杂交.这种反义RNA网络一方面参与调控特定基因在特定部位、特定时间的启动和关闭,维持机体各种功能活动的相对稳定,另一方面对体内突变核酸和体外侵入核酸发挥特异性识别和排斥作用.     

反义RNA及其在植物基因工程领域的应用

随着反义RNA的发现及对其研究的深入,反义RNA技术已被广泛应用于基因调控的研究中。本介绍了反义RNA的概念,并就反义RNA的作用机理和在植物基因工程领域的应用进行了综述。其作用机理包括：在原核生物中反义RNA与引物RNA前体及mRNA分子5′的不同区域进行互补,从而抑制其复制、转录和翻译;在其核生物中反义RNA影响mRNA前体拼接、转移及mRNA分子5′和3′正常修饰。在植物基因工程领域,反义RNA主要应用于抑制果实成熟、抗病、作为反向筛选标记基因、控制花色、控制淀粉合成、控制油料种子中脂肪酸的合成、控制雄性不育等方面。     

反义RNA的作用机理及其在植物基因工程领域的应用

本文综述了反义RNA在原核生物和真核生物中的作用机理,并系统地介绍了反义RNA技术在植物基因过程中的研究进展。     

Validation of antibacterial mechanism of action using regulated antisense RNA expression in Staphylococcus aureus

Validation of antibiotic mode of action in whole bacterial cells is a key step for antibiotic drug discovery. In this study, one potential drug target, enoyl-acyl carrier protein reductase (FabI), an essential enzyme in the fatty acid biosynthesis pathway, was used to evaluate the feasibility of using a regulated antisense RNA interference approach to determine antibiotic mode of action. Antisense isogenic strains expressing antisense RNA to fabI were created using a tetracycline-regulated vector in Staphylococcus aureus. We demonstrated that down-regulation of FabI expression by induction of fabI antisense RNA induces a conditional lethal phenotype. In contrast, partial down-regulation gives a viable cell with a significant increase in sensitivity to FabI-specific inhibitors (i.e., a sensitized phenotype). More importantly, the mode of action for novel FabI inhibitors has been confirmed using this genetic approach in whole cell assay. These results indicate that controlled antisense technology provides a robust tool for defining and tracking the mode of action of novel antibacterial agents.     

The predicted stem-loop structure in the 3′-end of the human norovirus antigenomic sequence is required for its genomic RNA synthesis by its RdRp

The norovirus genome consists of a single positive-stranded RNA. The mechanism by which this single-stranded RNA genome is replicated is not well understood. To reveal the mechanism underlying the initiation of the norovirus genomic RNA synthesis by its RNA-dependent RNA polymerase (RdRp), we used an in vitro assay to detect the complementary RNA synthesis activity. Results showed that the purified recombinant RdRp was able to synthesize the complementary positive-sense RNA from a 100-nt template corresponding to the 3′-end of the viral antisense genome sequence, but that the RdRp could not synthesize the antisense genomic RNA from the template corresponding to the 5′-end of the positive-sense genome sequence. We also predicted that the 31 nt region at the 3′-end of the RNA antisense template forms a stem-loop structure. Deletion of this sequence resulted in the loss of complementary RNA synthesis by the RdRp, and connection of the 31 nt to the 3′-end of the inactive positive-sense RNA template resulted in the gain of complementary RNA synthesis by the RdRp. Similarly, an electrophoretic mobility shift assay further revealed that the RdRp bound to the antisense RNA specifically, but was dependent on the 31 nt at the 3′-end. Therefore, based on this observation and further deletion and mutation analyses, we concluded that the predicted stem-loop structure in the 31 nt end and the region close to the antisense viral genomic stem sequences are both important for initiating the positive-sense human norovirus genomic RNA synthesis by its RdRp.     

反义技术在抗HBV感染中的应用

反义技术是近些年来随着现代分子生物学技术的发展而产生的新的生物医学治疗技术。它采用反义核酸分子抑制、封闭或破坏靶基因组的技术手段,包括反义寡核苷酸、核酶及RNA干扰等。反义分子通过与靶基因异性互补配对结合,阻断靶基因的复制、转录或翻译过程,从而发挥抗病毒作用。针对乙型肝炎病毒的反义技术也有了广泛而深入的研究。根据反义技术在分子、细胞以及动物水平上的研究表明：反义技术能够高效、特异地抑制HBV的复制与表达。     

反义RNA抑制人黑色素瘤细胞表面粘附分子CD44的表达及抑瘤效应

将细胞表面粘附分子ＣＤ４４Ｓ的ｃＤＮＡ反向插入到真核细胞表达载体ｐＭＡＭｎｅｏ－ＣＡＴ和ＭＭＴＶ－ＬＴＲ启动子下游,构成ＣＤ４４Ｓ的反义ＲＮＡ载体．将其用电击法导入ＣＤ４４＋的人黑色素瘤细胞系ＨＭＭ２３９,转录出的反义ＲＮＡ能不同程度地抑制ＨＭＭ２３９表面ＣＤ４４的表达．ＣＤ４４的表达被抑制后,瘤细胞与透明质酸的结合力下降,细胞的体外生长速率不受影响．将其接种裸鼠皮下,发现其致瘤性明显降低     

HYDROLYSIS OF BULGED NUCLEOTIDES IN HYBRIDS FORMED BY RNA AND IMIDAZOLE-DERIVATIZED OLIGO-2′-O-METHYLRIBONUCLEOTIDES

In order to enhance the efficacy of small antisense molecules, we examined a series of antisense oligonucleotides derivatized with functional groups designed to enable them to hydrolyze their RNA target. Solid phase synthetic methods were used to prepare imidazole-derivatized antisense oligo-2′-O-methylribonucleotides. Upon binding, these oligonucleotides create internal bulged bases in the target RNA that serve as sites for hydrolysis. We observed that an oligonucleotide derivatized with a side chain containing two imidazole groups was capable of hydrolyzing 58% of its RNA target when incubated with the target for 48 hours at 37°C and physiological pH.     

Confirmation of the mode of action of an antibacterial inhibitor using regulated antisense RNA

Summary We previously demonstrated that regulated antisense RNA technology enables us to validate and identify the mode of action for some antibiotics. In this study, we have expanded the application of the regulated antisense approach to track the mode of action for a novel inhibitor of polypeptide deformylase (Pdf), which is an attractive target for the development of novel classes of antibacterial agents. We created a pdf antisense isogenic strain in Staphylococcus aureus using a TetR-regulated expression system. We demonstrated that the partial inhibition of pdf expression significantly increased the susceptibility of S. aureus to Pdf-specific inhibitor. This result provides further evidence that the TetR-regulated antisense technology is a robust tool for tracking the mode of action of novel antibacterial agents.     

Regulation of plant gene expression by antisense RNA.

Regulation of gene expression by antisense RNA was first discovered as a naturally-occurring phenomenon in bacteria. Recently natural antisense RNAs have been found in a variety of eukaryotic organisms; their in vivo function is, however, obscure. Deliberate expression of antisense RNA in animal and plant systems has lead to successful down-regulation of specific genes. We will review the current status of antisense gene action in plant systems. The recent discovery that 'sense' genes are able to mimic the action of antisense genes indicates that (anti)sense genes must operate by mechanisms other than RNA-RNA interaction.     

Molecular mechanisms of action of antisense drugs

Given the progress reported during the past decade, a wide range of chemical modifications may be incorporated into potential antisense drugs. These modifications may influence all the properties of these molecules, including mechanism of action. DNA-like antisense drugs have been shown to serve as substrates when bound to target RNAs for RNase Hs. These enzymes cleave the RNA in RNA/DNA duplexes and now the human enzymes have been cloned and characterized. A number of mechanisms other than RNase H have also been reported for non-DNA-like antisense drugs. For example, activation of splicing, inhibition of 5'-cap formation, translation arrest and activation of double strand RNases have all been shown to be potential mechanisms. Thus, there is a growing repertoire of potential mechanisms of action from which to choose, and a range of modified oligonucleotides to match to the desired mechanism. Further, we are beginning to understand the various mechanisms in more detail. These insights, coupled with the ability to rapidly evaluate activities of antisense drugs under well-controlled rapid throughput systems, suggest that we will make more rapid progress in identifying new mechanisms, developing detailed understanding of each mechanism and creating oligonucleotides that better predict what sites in an RNA are most amenable to antisense drugs of various chemical classes.     

Effects of different target sites on antisense RNA-mediated regulation of gene expression

Antisense RNA is a type of noncoding RNA (ncRNA) that binds to complementary mRNA sequences and induces gene repression by inhibiting translation or degrading mRNA. Recently, several small ncRNAs (sRNAs) have been identified in Escherichia coli that act as antisense RNA mainly via base pairing with mRNA. The base pairing predominantly leads to gene repression, and in some cases, gene activation. In the current study, we examined how the location of target sites affects sRNA-mediated gene regulation. An efficient antisense RNA expression system was developed, and the effects of antisense RNAs on various target sites in a model mRNA were examined. The target sites of antisense RNAs suppressing gene expression were identified, not only in the translation initiation region (TIR) of mRNA, but also at the junction between the coding region and 3'' untranslated region. Surprisingly, an antisense RNA recognizing the upstream region of TIR enhanced gene expression through increasing mRNA stability. [BMB Reports 2014; 47(11): 619-624]     

RNA干扰在植物中的作用机理及其应用研究进展

RNA干扰(RNAi)是广泛存在于生物中的一种现象,它是小干扰RNA诱导的转录后基因沉默,是生物抵抗异常DNA的一种保护机制,同时在生物生长发育过程中调控基因的表达.本文综述了近年来有关RNA干扰的发现、作用过程及其机理,分析了它与反义寡核苷酸、核酶、脱氧核酶的小同,并介绍了RNA干扰在植物基因功能、植物抗病毒、作物品种改良等方面的应用,为siRNA干扰的进一步利用提供参考资料.