Antiviral RNA Silencing Initiated in the Absence of RDE-4, a Double-Stranded RNA Binding Protein,in Caenorhabditis elegans

Small interfering RNAs (siRNAs) processed from double-stranded RNA (dsRNA) of virus origins mediate potent antiviral defense through a process referred to as RNA interference (RNAi) or RNA silencing in diverse organisms. In the simple invertebrate Caenorhabditis elegans, the RNAi process is initiated by a single Dicer, which partners with the dsRNA binding protein RDE-4 to process dsRNA into viral siRNAs (viRNAs). Notably, in C. elegans this RNA-directed viral immunity (RDVI) also requires a number of worm-specific genes for its full antiviral potential. One such gene is rsd-2 (RNAi spreading defective 2), which was implicated in RDVI in our previous studies. In the current study, we first established an antiviral role by showing that rsd-2 null mutants permitted higher levels of viral RNA accumulation, and that this enhanced viral susceptibility was reversed by ectopic expression of RSD-2. We then examined the relationship of rsd-2 with other known components of RNAi pathways and established that rsd-2 functions in a novel pathway that is independent of rde-4 but likely requires the RNA-dependent RNA polymerase RRF-1, suggesting a critical role for RSD-2 in secondary viRNA biogenesis, likely through coordinated action with RRF-1. Together, these results suggest that RDVI in the single-Dicer organism C. elegans depends on the collective actions of both RDE-4-dependent and RDE-4-independent mechanisms to produce RNAi-inducing viRNAs. Our study reveals, for the first time, a novel siRNA-producing mechanism in C. elegans that bypasses the need for a dsRNA-binding protein.     

RNA沉默机制及其抗病毒应用

RNA沉默是发生在植物 (转录后基因沉默或共抑制 )、动物 (RNA干扰 )和真菌 (消除作用 )等真核生物细胞中的一种对外源遗传因子 (转座子、转基因或病毒 )的特异性和高效率的降解机制。随着对植物病毒分子遗传学认识的加深和对寄主防御系统研究的深入 ,发现了许多控制植物病毒病的方法 ,不过迄今为止最为成功的是通过RNA沉默机制获取抗病毒工程植株。在陈述了RNA沉默机制的研究最新进展基础上 ,提出了如何充分利用该机制进行植物抗病毒转基因研究。     

烟草花叶病毒和黄瓜花叶病毒双价RNA沉默抗病载体的快速构建*

利用重组PCR技术将烟草花叶病毒(TMV)部分移动蛋白基因（△MP）和黄瓜花叶病毒（CMV）部分复制酶基因（△Rep）连接起来,获得全长约1000 bp的MP-Rep融合基因,将所得融合基因以反向重复的方式与大豆内含子相连,并定向插入到植物表达载体pBIN438上35S启动子下游,构建了含两种不同病毒来源基因的植物表达载体pBIN438-MP-Rep（i/r）。酶切和PCR鉴定证明所构建的载体与预期的设计完全一致。该研究结果为利用RNA沉默原理进行植物广谱抗病研究奠定了基础。     

Identification and Characterization of Two Novel bla KLUC Resistance Genes through Large-Scale Resistance Plasmids Sequencing

Plasmids are important antibiotic resistance determinant carriers that can disseminate various drug resistance genes among species or genera. By using a high throughput sequencing approach, two groups of plasmids of Escherichia coli (named E1 and E2, each consisting of 160 clinical E. coli strains isolated from different periods of time) were sequenced and analyzed. A total of 20 million reads were obtained and mapped onto the known resistance gene sequences. As a result, a total of 9 classes, including 36 types of antibiotic resistant genes, were identified. Among these genes, 25 and 27 single nucleotide polymorphisms (SNPs) appeared, of which 9 and 12 SNPs are nonsynonymous substitutions in the E1 and E2 samples. It is interesting to find that a novel genotype of bla _KLUC, whose close relatives, bla _KLUC-1 and bla _KLUC-2, have been previously reported as carried on the Kluyvera cryocrescens chromosome and Enterobacter cloacae plasmid, was identified. It shares 99% and 98% amino acid identities with Kluc-1 and Kluc-2, respectively. Further PCR screening of 608 Enterobacteriaceae family isolates yielded a second variant (named bla _KLUC-4). It was interesting to find that Kluc-3 showed resistance to several cephalosporins including cefotaxime, whereas bla _KLUC-4 did not show any resistance to the antibiotics tested. This may be due to a positively charged residue, Arg, replaced by a neutral residue, Leu, at position 167, which is located within an omega-loop. This work represents large-scale studies on resistance gene distribution, diversification and genetic variation in pooled multi-drug resistance plasmids, and provides insight into the use of high throughput sequencing technology for microbial resistance gene detection.     

Ribosomal Protein S29 Regulates Metabolic Insecticide Resistance through Binding and Degradation of CYP6N3

Background

Many diseases are transmitted by mosquitoes, including malaria, dengue fever, yellow fever, filariasis, and West Nile fever. Chemical control plays a major role in managing mosquito-borne diseases. However, excessive and continuous application of insecticides has caused the development of insecticide resistance in many species including mosquito, and this has become the major obstacle to controlling mosquito-borne diseases. Insecticide resistance is the result of complex polygenic inheritance, and the mechanisms are not well understood. Ribosomal protein RPS29 was found to be associated with DM resistance in our previous study. In this study, we aim to further investigate the involvement of RPS29 in deltamethrin resistance.

Methodology and Principal Findings

In this study, tandem affinity purification was used to identify proteins that can interact with RPS29. Among the candidate proteins, CYP6N3, a member of the CYP450 superfamily, was identified, and binding to RPS29 was confirmed in vitro and in vivo by GST pull-down and immunofluorescence. CCK-8 assay was used to investigate the RPS29-CTP6N3 interaction in relation to DM resistance. CYP6N3 overexpression significantly enhanced DM resistance and insect cell viability, but this was reversed by RPS29 overexpression. Western blot was used to study the mechanism of interaction between RPS29 and CYP6N3. RPS29 increases CYP6N3 protein degradation through the proteasome.

Conclusions and Significance

These observations indicate that CYP6N3, a novel RPS29-interacting partner, could stimulate deltamethrin resistance in mosquito cells and RPS29 overexpression targeted CYP6N3 for proteosomal degradation, abrogating the CYP6N3-associated resistence to deltamethrin. Our findings provide a novel mechanism associated with CYP450s mediated DM resistance.     

CYP6 P450 Enzymes and ACE-1 Duplication Produce Extreme and Multiple Insecticide Resistance in the Malaria Mosquito Anopheles gambiae

Malaria control relies heavily on pyrethroid insecticides, to which susceptibility is declining in Anopheles mosquitoes. To combat pyrethroid resistance, application of alternative insecticides is advocated for indoor residual spraying (IRS), and carbamates are increasingly important. Emergence of a very strong carbamate resistance phenotype in Anopheles gambiae from Tiassalé, Côte d''Ivoire, West Africa, is therefore a potentially major operational challenge, particularly because these malaria vectors now exhibit resistance to multiple insecticide classes. We investigated the genetic basis of resistance to the most commonly-applied carbamate, bendiocarb, in An. gambiae from Tiassalé. Geographically-replicated whole genome microarray experiments identified elevated P450 enzyme expression as associated with bendiocarb resistance, most notably genes from the CYP6 subfamily. P450s were further implicated in resistance phenotypes by induction of significantly elevated mortality to bendiocarb by the synergist piperonyl butoxide (PBO), which also enhanced the action of pyrethroids and an organophosphate. CYP6P3 and especially CYP6M2 produced bendiocarb resistance via transgenic expression in Drosophila in addition to pyrethroid resistance for both genes, and DDT resistance for CYP6M2 expression. CYP6M2 can thus cause resistance to three distinct classes of insecticide although the biochemical mechanism for carbamates is unclear because, in contrast to CYP6P3, recombinant CYP6M2 did not metabolise bendiocarb in vitro. Strongly bendiocarb resistant mosquitoes also displayed elevated expression of the acetylcholinesterase ACE-1 gene, arising at least in part from gene duplication, which confers a survival advantage to carriers of additional copies of resistant ACE-1 G119S alleles. Our results are alarming for vector-based malaria control. Extreme carbamate resistance in Tiassalé An. gambiae results from coupling of over-expressed target site allelic variants with heightened CYP6 P450 expression, which also provides resistance across contrasting insecticides. Mosquito populations displaying such a diverse basis of extreme and cross-resistance are likely to be unresponsive to standard insecticide resistance management practices.     

Genome-Wide Double-Stranded RNA Sequencing Reveals the Functional Significance of Base-Paired RNAs in Arabidopsis

The functional structure of all biologically active molecules is dependent on intra- and inter-molecular interactions. This is especially evident for RNA molecules whose functionality, maturation, and regulation require formation of correct secondary structure through encoded base-pairing interactions. Unfortunately, intra- and inter-molecular base-pairing information is lacking for most RNAs. Here, we marry classical nuclease-based structure mapping techniques with high-throughput sequencing technology to interrogate all base-paired RNA in Arabidopsis thaliana and identify ∼200 new small (sm)RNA–producing substrates of RNA–DEPENDENT RNA POLYMERASE6. Our comprehensive analysis of paired RNAs reveals conserved functionality within introns and both 5′ and 3′ untranslated regions (UTRs) of mRNAs, as well as a novel population of functional RNAs, many of which are the precursors of smRNAs. Finally, we identify intra-molecular base-pairing interactions to produce a genome-wide collection of RNA secondary structure models. Although our methodology reveals the pairing status of RNA molecules in the absence of cellular proteins, previous studies have demonstrated that structural information obtained for RNAs in solution accurately reflects their structure in ribonucleoprotein complexes. Furthermore, our identification of RNA–DEPENDENT RNA POLYMERASE6 substrates and conserved functional RNA domains within introns and both 5′ and 3′ untranslated regions (UTRs) of mRNAs using this approach strongly suggests that RNA molecules are correctly folded into their secondary structure in solution. Overall, our findings highlight the importance of base-paired RNAs in eukaryotes and present an approach that should be widely applicable for the analysis of this key structural feature of RNA.     

Spatial and Temporal Potato Intensification Drives Insecticide Resistance in the Specialist Herbivore,Leptinotarsa decemlineata

Landscape-scale intensification of individual crops and pesticide use that is associated with this intensification is an emerging, environmental problem that is expected to have unequal effects on pests with different lifecycles, host ranges, and dispersal abilities. We investigate if intensification of a single crop in an agroecosystem has a direct effect on insecticide resistance in a specialist insect herbivore. Using a major potato pest, Leptinotarsa decemlineata, we measured imidacloprid (neonicotinoid) resistance in populations across a spatiotemporal crop production gradient where potato production has increased in Michigan and Wisconsin, USA. We found that concurrent estimates of area and temporal frequency of potato production better described patterns of imidacloprid resistance among L. decemlineata populations than general measures of agricultural production (% cropland, landscape diversity). This study defines the effects individual crop rotation patterns can have on specialist herbivore insecticide resistance in an agroecosystem context, and how impacts of intensive production can be estimated with general estimates of insecticide use. Our results provide empirical evidence that variation in the intensity of neonicotinoid-treated potato in an agricultural landscape can have unequal impacts on L. decemlineata insecticide insensitivity, a process that can lead to resistance and locally intensive insecticide use. Our study provides a novel approach applicable in other agricultural systems to estimate impacts of crop rotation, increased pesticide dependence, insecticide resistance, and external costs of pest management practices on ecosystem health.     

用慢病毒转染RNAi技术沉默胆固醇7α羟化酶的基因表达，降低肝细胞中胆汁酸的分泌

为了降低生物人工肝(bioartificial liver system)中肝细胞胆汁酸的分泌,构建了胆固醇7α羟化酶慢病毒RNA干涉载体,并转染人肝脏细胞(L-02).根据绿色荧光蛋白的表达评估转染效率后进行流式分选,获得高表达慢病毒干涉载体的细胞,并以野生型L-02细胞和仅转染pSicoR空载体的L-02细胞作对照,观察肝细胞胆固醇7α羟化酶的表达以及培养上清中总胆汁酸含量.利用半定量PCR、实时荧光定量PCR及Western-blot等实验方法检测了转染细胞中基因的干涉效果,结果显示:与对照组相比,在mRNA水平,转染慢病毒siRNA载体的L-02细胞,其胆固醇7α羟化酶基因的表达量仅为野生型L-02细胞表达量的31.2%,为转染pSicoR空载体的L-02细胞的34.1%,干涉效率分别为68.8%和65.9%,均具有显著差异(P＜0.05);Western-blot结果显示胆固醇7α羟化酶在蛋白质水平表达也明显受到抑制,表明转染慢病毒siRNA下调了肝细胞中胆固醇7α羟化酶基因的表达,减少了胆汁酸的分泌.以上研究结果表明,利用RNAi技术可以获得低表达胆固醇7α羟化酶基因的肝细胞,并有效降低肝细胞中胆汁酸的分泌,为临床上生物人工肝的构建及应用奠定基础.     

Conserved Sequences of Replicase Gene-Mediated Resistance to <Emphasis Type="Italic">Potyvirus</Emphasis> through RNA Silencing

Nuclear inclusion protein b (NIb) genes of three Potato virus Y isolates PVY-SD1 (O strain), PVY-SD4 (N strain), PVY-SD5 (NTN strain), and Tobacco etch virus isolate TEV-SD1 in Shandong Province were cloned and sequenced. Sequence analysis showed that the sequence homology of the entire NIb gene among the four viruses ranged from 65% to 95%. Hairpin RNA (hpRNA) constructs were designed based on five conserved regions derived from PVY-SD1 and introduced into tobacco plants. After asexual propagation, the transgenic plants were analyzed for resistance to PVY-SD1, PVY-SD4, PVY-SD5, and TEV-SD1. We obtained resistance ratios of 26.2%, 22.7%, 36.4%, 20.3%, and 21.7% to PVY-SD1. When inoculated with the PVY-SD5 virus, the transgenic plants had resistance ratios ranging from 2.4% to 15.9%, but no resistance at all to the other viruses, PVY-SD4 and TEV-SD1. No correlation was found between resistance of transgenic plants and the transgene copy numbers. Northern blot and small interfering RNA (siRNA) analysis demonstrated that the resistance was attributable to RNA silencing. Genetic analysis demonstrated that virus resistance was stably inherited in progeny T₁ and T₂. These results indicate that the siRNA molecules against conserved regions can confer virus resistance but are restricted to viruses with more than 90% sequence homology.     

Interaction of CarD with RNA Polymerase Mediates Mycobacterium tuberculosis Viability,Rifampin Resistance,and Pathogenesis

Mycobacterium tuberculosis infection continues to cause substantial human suffering. New chemotherapeutic strategies, which require insight into the pathways essential for M. tuberculosis pathogenesis, are imperative. We previously reported that depletion of the CarD protein in mycobacteria compromises viability, resistance to oxidative stress and fluoroquinolones, and pathogenesis. CarD associates with the RNA polymerase (RNAP), but it has been unknown which of the diverse functions of CarD are mediated through the RNAP; this question must be answered to understand the CarD mechanism of action. Herein, we describe the interaction between the M. tuberculosis CarD and the RNAP β subunit and identify point mutations that weaken this interaction. The characterization of mycobacterial strains with attenuated CarD/RNAP β interactions demonstrates that the CarD/RNAP β association is required for viability and resistance to oxidative stress but not for fluoroquinolone resistance. Weakening the CarD/RNAP β interaction also increases the sensitivity of mycobacteria to rifampin and streptomycin. Surprisingly, depletion of the CarD protein did not affect sensitivity to rifampin. These findings define the CarD/RNAP interaction as a new target for chemotherapeutic intervention that could also improve the efficacy of rifampin treatment of tuberculosis. In addition, our data demonstrate that weakening the CarD/RNAP β interaction does not completely phenocopy the depletion of CarD and support the existence of functions for CarD independent of direct RNAP binding.     

Delivery of dsRNA through topical feeding for RNA interference in the citrus sap piercing‐sucking hemipteran,Diaphorina citri

RNA interference (RNAi) is a powerful means to study functional genomics in insects. The delivery of dsRNA is a challenging step in the development of RNAi assay. Here, we describe a new delivery method to increase the effectiveness of RNAi in the Asian citrus psyllid Diaphorina citri. Bromophenol blue droplets were topically applied to fifth instar nymphs and adults on the ventral side of the thorax between the three pairs of legs. In addition to video recordings that showed sucking of the bromophenol blue by the stylets, dissected guts turned blue indicating that the uptake was through feeding. Thus, we called the method topical feeding. We targeted the abnormal wing disc gene (awd), also called nucleoside diphosphate kinase (NDPK), as a reporter gene to prove the uptake of dsRNA via this method of delivery. Our results showed that dsRNA‐awd caused reduction of awd expression and nymph mortality. Survival and lifespan of adults emerged from treated nymphs and treated adults were affected. Silencing awd caused wing malformation in the adults emerged from treated nymphs. Topical feeding as a delivery of dsRNA is highly efficient for both nymphs and adults. The described method could be used to increase the efficiency of RNAi in D. citri and other sap piercing‐sucking hemipterans.