Cytotoxic ribonucleases and RNA interference (RNAi)

Several cytotoxic ribonucleases (CRs), homologs of the pancreatic RNase A, have been isolated from amphibian oocytes or embryos. Of them, onconase (Onc), the CR that shows antitumor properties and is in phase III clinical trials, was the most extensively researched. Degradation of tRNA by Onc internalized into cells that leads to inhibition of protein synthesis is considered the mechanism of its cytotoxicity. Several findings, however, cannot be explained by nonspecific decline in protein synthesis alone and suggest additional or alternative mechanism(s). We postulate therefore that miRNAs and/or RNA interference (RNAi) may also be targets of CRs. The following arguments support this postulate: (A) miRNAs and siRNAs appear to be unprotected by proteins and therefore, as tRNA, accessible and degradable by CRs; (B) Onc has preferred cleavage sites on tRNAs: their cleavage may generate segments of dsRNA that interfere with translation. Analogous to Dicer, thus, small RNAs with interfering properties may be generated by CRs within the cell; (C) CRs are abundant in oocytes and during embryonic development; their role there is unknown. Since cells undergo perpetual differentiation during embryogenesis it is likely that the function of CRs is to provide additional level of regulation of gene expression via the mechanisms listed in (A) and/or (B).     

Recent progress in the development of RNA interference for plant parasitic nematodes

RNA interference (RNAi), first described for Caenorhabditis elegans , has emerged as a powerful gene silencing tool for investigating gene function in a range of organisms. Recent studies have described its application to plant parasitic nematodes. Genes expressed in a range of cell types are silenced when preparasitic juvenile nematodes take up double-stranded (ds)RNA that elicits a systemic RNAi response. Important developments over the last year have shown that in planta expression of a dsRNA targeting a nematode gene can successfully induce silencing in parasitizing nematodes. When the targeted gene has an essential function, a resistance effect is observed paving the way for the potential use of RNAi technology to control plant parasitic nematodes.     

RNA interference and plant parasitic nematodes

RNA interference (RNAi) has recently been demonstrated in plant parasitic nematodes. It is a potentially powerful investigative tool for the genome-wide identification of gene function that should help improve our understanding of plant parasitic nematodes. RNAi should help identify gene and, hence, protein targets for nematode control strategies. Prospects for novel resistance depend on the plant generating an effective form of double-stranded RNA in the absence of an endogenous target gene without detriment to itself. These RNA molecules must then become available to the nematode and be capable of ingestion via its feeding tube. If these requirements can be met, crop resistance could be achieved by a plant delivering a dsRNA that targets a nematode gene and induces a lethal or highly damaging RNAi effect on the parasite.     

Modulation of the classical multidrug resistance (MDR) phenotype by RNA interference (RNAi)

For reversal of MDR1 gene-dependent multidrug resistance (MDR), two small interfering RNA (siRNA) constructs were designed to inhibit MDR1 expression by RNA interference. SiRNA duplexes were used to treat human pancreatic carcinoma (EPP85-181RDB) and gastric carcinoma (EPG85-257RDB) cells. In both cellular systems, siRNAs could specifically inhibit MDR1 expression up to 91% at the mRNA and protein levels. Resistance against daunorubicin was decreased to 89% (EPP85-181RDB) or 58% (EPG85-257RDB). The data indicate that this approach may be applicable to cancer patients as a specific means to reverse tumors with a P-glycoprotein-dependent MDR phenotype back to a drug-sensitive one.     

Knockdown of the bovine prion gene PRNP by RNA interference (RNAi) technology

Background  

Since prion gene-knockout mice do not contract prion diseases and animals in which production of prion protein (PrP) is reduced by half are resistant to the disease, we hypothesized that bovine animals with reduced PrP would be tolerant to BSE. Hence, attempts were made to produce bovine PRNP (bPRNP) that could be knocked down by RNA interference (RNAi) technology. Before an in vivo study, optimal conditions for knocking down bPRNP were determined in cultured mammalian cell systems. Factors examined included siRNA (short interfering RNA) expression plasmid vectors, target sites of PRNP, and lengths of siRNAs.     

Melon RNA interference (RNAi) lines silenced for Cm-eIF4E show broad virus resistance

Efficient and sustainable control of plant viruses may be achieved using genetically resistant crop varieties, although resistance genes are not always available for each pathogen; in this regard, the identification of new genes that are able to confer broad-spectrum and durable resistance is highly desirable. Recently, the cloning and characterization of recessive resistance genes from different plant species has pointed towards eukaryotic translation initiation factors (eIF) of the 4E family as factors required for the multiplication of many different viruses. Thus, we hypothesized that eIF4E may control the susceptibility of melon (Cucumis melo L.) to a broad range of viruses. To test this hypothesis, Cm-eIF4E knockdown melon plants were generated by the transformation of explants with a construct that was designed to induce the silencing of this gene, and the plants from T2 generations were genetically and phenotypically characterized. In transformed plants, Cm-eIF4E was specifically silenced, as identified by the decreased accumulation of Cm-eIF4E mRNA and the appearance of small interfering RNAs derived from the transgene, whereas the Cm-eIF(iso)4E mRNA levels remained unaffected. We challenged these transgenic melon plants with eight agronomically important melon-infecting viruses, and identified that they were resistant to Cucumber vein yellowing virus (CVYV), Melon necrotic spot virus (MNSV), Moroccan watermelon mosaic virus (MWMV) and Zucchini yellow mosaic virus (ZYMV), indicating that Cm-eIF4E controls melon susceptibility to these four viruses. Therefore, Cm-eIF4E is an efficient target for the identification of new resistance alleles able to confer broad-spectrum virus resistance in melon.     

双链RNA干涉技术(RNAi)在不同生物中应用的研究进展

双链RNA(double～stranded RNA dsRNA )干涉技术可通过降解靶基因的mRNA进行基因干涉,是研究多种生物基因功能的有效手段,目前已在拟南芥、秀丽新小杆线虫、黑腹果蝇、斑马鱼和小鼠等生物中应用,本文拟就其应用特点进行综述。 Abstract:Double stranded RNA could degrade mRNA of target gene.It is a useful way for studying gene function.It is used widely in different creatures,such as Arabidopsis thaliana,Caenorhabditis elegans,Drosophila melanogaster,Zebrafish,Mouse.This review is mainly related to the application of dsRNA in recent years     

Cytotoxic Ribonucleases and RNA Interference (RNAi)

Several cytotoxic ribonucleases (CRs), homologs of the pancreatic RNase A, have been isolated from amphibian oocytes or embryos. Of them, onconase (Onc), the CR that shows antitumor properties and is in phase III clinical trials, was the most extensively researched. Degradation of tRNA by Onc internalized into cells that leads to inhibition of protein synthesis is considered the mechanism of its cytotoxicity. Several findings, however, cannot not be explained by nonspecific decline in protein synthesis alone and suggest additional or alternative mechanism(s). We postulate therefore that miRNAs and/or RNA interference (RNAi) may also be targets of CRs. The following arguments support this postulate: (A) miRNAs and siRNAs appear to be unprotected by proteins and therefore, as tRNA, accessible and degradable by CRs; (B) Onc has preferred cleavage sites on tRNAs: their cleavage may generate segments of dsRNA that interfere with translation. Analogous to Dicer, thus, small RNAs with interfering properties may be generated by CRs within the cell; (c) CRs are abundant in oocytes and during embryonic development; their role there is unknown. Since cells undergo perpetual differentiation during embryogenesis it is likely that the function of CRs is to provide additional level of regulation of gene expression via the mechanisms listed in (A) and/or (B).