昆虫钠通道的结构和与击倒抗性有关的基因突变

击倒抗性(kdr)是指昆虫和其他节肢动物由于它们的神经系统对DDT和拟除虫菊酯类杀虫剂的敏感性降低而引起的抗性。电压敏感的钠通道是DDT和拟除虫菊酯类杀虫剂的主要靶标。已知拟除虫菊酯是通过改变位于神经膜上的这类通道而发挥其杀虫效果的,钠通道基因的点突变是产生kdr抗性的主要原因。40年来kdr抗性一直是重要的研究课题,但近10年来在kdr分子生物学方面取得了很大进展。本文主要综述了1996年以来所取得的新进展,着重于钠通道的结构、在14种害虫中与kdr抗性相关的钠通道基因突变及其氨基酸序列的多态性。这些结果有助于对拟除虫菊酯改变钠通道的功能及其机理作进一步探究。     

击倒抗性和钠离子通道

综述了击倒抗性与钠离子通道关系的研究进展。毒理学和电生理学的研究表明,在许多拟除虫菊酯类杀虫剂抗性昆虫中存在击倒抗性。分子遗传学研究进一步发现,击倒抗性与钠离子通道位点连锁。最近的研究表明,昆虫神经系统对拟除虫菊酯类杀虫剂敏感性下降的击倒抗性机制是钠离子通道结构基因突变。但仍有一些问题,如突变的保守性和分布,需要进一步研究、阐明。     

臭虫击倒抗性基因突变检测及抗性测定

近20多年,臭虫（Cimex spp.）在世界范围内成为常见的卫生害虫,其防治主要采用化学防治,但很多种群发现击倒抗性（Knockdown resistance gene, kdr）基因突变的存在以及抗药性。监测kdr的发生频率以及不同种群对农药的抗性对臭虫有效防治很重要,但我国对臭虫种群的抗药性报道很少。本试验采用点滴法测定了1个温带臭虫Cimex lectularius野外种群对氯虫苯甲酰胺、呋虫胺、吡虫啉、噻虫嗪和高效氯氰菊酯等5种药剂的毒性及抗性水平,使用区分剂量快速鉴定抗性方法对2个温带臭虫和2个热带臭虫Cimex hemipterus种群对高效氯氰菊酯的抗性水平进行了检测,此外用PCR方法检测8个臭虫地理种群（1个温带臭虫实验室种群,1个温带臭虫野外种群和6个热带臭虫野外种群）174个个体的kdr突变频率。点滴法结果表明,5种杀虫剂对温带臭虫的毒性是吡虫啉和呋虫胺>噻虫嗪>氯虫苯甲酰胺和高效氯氰菊酯,测试的野外温带臭虫种群仅对噻虫嗪无明显抗性。热带臭虫2个野外种群对高效氯氰菊酯的抗性均远高于温带臭虫。在温带臭虫的实验室种群中未检测到突变,在野外种群中检测到了V419L和L925I突变,可分为2种基因型类型（A：无突变位点;B：同时有L925I和V419L）,而在热带臭虫的6个种群检测到M918I和L1014F突变,只有1种基因型类型,即M918I和L1014F双位点突变。温带臭虫1个野外种群及热带臭虫6个野外种群kdr突变的存在与臭虫对高效氯氰菊酯敏感密切关联。基于kdr基因突变检测结果推测我国臭虫种群广泛存在对拟除虫菊酯的抗性。     

昆虫钠离子通道基因突变及其与杀虫剂抗性关系的研究进展

昆虫电压门控钠离子通道(voltage-gated sodium channel)存在于所有可兴奋细胞的细胞膜上,在动作电位的产生和传导上起重要作用,是有机氯和拟除虫菊酯杀虫剂的靶标位点。在农业和医学害虫控制过程中,由于有机氯和拟除虫菊酯杀虫剂的广泛使用,抗药性问题日益突出。其中,由于钠离子通道基因突变,降低了钠离子通道对有机氯和拟除虫菊酯类杀虫剂的亲和性,从而产生击倒抗性(knock-down resistance, kdr),已成为抗性产生的重要机制之一。本文综述了昆虫钠离子通道的跨膜拓扑结构、功能、进化及其基因的克隆;更重要的是总结了已报道的40多种昆虫40个钠离子通道基因非同义突变,以及钠离子通道基因选择性mRNA剪接和编辑,以及它们与杀虫剂抗性的关系;也评述了钠离子通道基因突变引起蛋白质结构的改变,从而对杀虫剂抗性的影响机制。这些研究对于进一步鉴定与杀虫剂抗性相关的突变及抗性机制,开发有机氯和拟除虫菊酯类杀虫剂抗性分子监测方法具有重要意义。     

有机磷和拟除虫菊酯抗性棉铃虫靶标抗性的分子机理(英文)

对有机磷和拟除虫菊酯抗性 (R)棉铃虫靶标抗性的分子机理 ,即乙酰胆碱酯酶 (AChE)和钠通道敏感度降低进行了研究。根据AChE的动力学常数表明 ,R品系AChE的活性和Vmax值分别是S品系的 1 0 9和 1 2 3倍 ,但R品系的AChE的Km 值仅是S品系的 0 6 7倍。R品系AChE对DDVP和马拉硫磷的Ki值分别是S品系的 0 4 4和 0 55。这表明AChE发生了质的变化。还应用PCR技术对抗性棉铃虫的击倒抗性 (kdr)进行了鉴定 ,克隆了钠通道的IIS6序列、IIS5和IIS6连接片段以及II和III连接片段 ,测序后比较了R和S品系以及其它昆虫的同源性 ,结果在氨基酸水平未发现有任何差异 ,这表明该抗性棉铃虫品系不涉及kdr。     

电压门控钠通道的变异与机体疾患

通道病理学是当今国际学术发展中一门新兴学科。本文将针对有关电压门控钠通道的变异所导致的机体疾患,如高血钾性周期性麻痹,先天性肌强直等骨骼肌疾患,ＬＱＴ３,原发笥心室纤颤等心脏病及其所涉及的钠通道突变体,通道的突变位点和电生理性质等一些研究资料与进展作一概括介绍。     

电压门控钠通道结构与功能的适应性进化

电压门控钠通道是细胞兴奋性的重要分子基础,在进化演变中远早于神经元。伴随从细菌到脊椎动物的适应性演变,电压门控钠通道逐渐呈现出复杂的结构、功能和亚型多样性,且与诸多人类疾病密切相关。明确电压门控钠通道时空演变的适应性进化,解析电压门控钠通道的功能和结构多样性与人类重大疾病发生机制的相关性,有助于推进电压门控钠通道靶向临床诊疗新策略和新药的发现。     

与拟除虫菊酯抗性相关的烟粉虱钠通道基因突变及其检测

通过RT-PCR克隆了烟粉虱Bemisia tabaci (Gennadius) 南京种群(B-生物型)的钠离子通道结构域ⅡS4-6 cDNA片段,证实了与拟除虫菊酯抗性相关的是位于第925位亮氨酸到异亮氨酸的突变(L925I),并建立了L925I突变的PASA检测技术。与SUD-S敏感品系相比,2002年采自南京棉花上的烟粉虱种群对氯氰菊酯具有77倍的抗性,用氯氰菊酯对该种群进行多次筛选后,该种群对氯氰菊酯的抗药性提高到227倍。PASA检测结果表明筛选后的南京种群中100%个体都具有L925I突变(61.1%的个体为L925I突变纯合子,38.9%的个体为杂合子),而未筛选的南京种群只有75%个体具有L925I突变(35%个体为L925I突变纯合子,40%的个体为杂合子,25%的个体为野生型)。该结果表明了烟粉虱钠离子通道L925I突变与对拟除虫菊酯抗性密切相关。还讨论了烟粉虱对拟除虫菊酯抗性的代谢机理。     

苦参碱对棉铃虫幼虫神经细胞钠通道的影响

用全细胞膜片钳技术研究了生物碱类植物杀虫剂苦参碱对棉铃虫Helicoverpa armigera幼虫离体培养中枢神经细胞钠离子通道门控过程的影响。结果表明： 苦参碱对棉铃虫幼虫神经细胞所表达的TTX （tetradotoxin, 河豚毒素)敏感钠通道具有浓度依赖性阻滞作用,1,10和100 μmol/L的苦参碱作用5 min后,分别使钠电流峰值较给药前下降（12.49±1.67）%、（18.79±2.16）%和（43.15±8.17）% (n=8, P<0.05)。苦参碱使钠电流的电流 电压关系曲线上移,但并不改变其激活电压、峰电压和电流电压关系曲线的形状。苦参碱对钠通道的阻滞作用可能是其具有某些毒理效应的离子基础。     

Chronology of sodium channel mutations associated with pyrethroid resistance in Aedes aegypti

Aedes aegypti is the primary mosquito vector of dengue, yellow fever, Zika and chikungunya. Current strategies to control Ae. aegypti rely heavily on insecticide interventions. Pyrethroids are a major class of insecticides used for mosquito control because of their fast acting, highly insecticidal activities and low mammalian toxicity. However, Ae. aegypti populations around the world have begun to develop resistance to pyrethroids. So far, more than a dozen mutations in the sodium channel gene have been reported to be associated with pyrethroid resistance in Ae. aegypti. Co-occurrence of resistance-associated mutations is common in pyrethroid-resistant Ae. aegypti populations. As global use of pyrethroids in mosquito control continues, new pyrethroid-resistant mutations keep emerging. In this microreview, we compile pyrethroid resistance-associated mutations in Ae. aegypti in a chronological order, as they were reported, and summarize findings from functional evaluation of these mutations in an in vitro sodium channel expression system. We hope that the information will be useful for tracing possible evolution of pyrethroid resistance in this important human disease vector, in addition to the development of methods for global monitoring and management of pyrethroid resistance in Ae. aegypti.     

Point mutations in the Drosophila sodium channel gene para associated with resistance to DDT and pyrethroid insecticides

The gene para in Drosophila melanogaster encodes an α subunit of voltage-activated sodium channels, the presumed site of action of DDT and pyrethroid insecticides. We used an existing collection of Drosophila para mutants to examine the molecular basis of target-site resistance to pyrethroids and DDT. Six out of thirteen mutants tested were associated with a largely dominant, 10- to 30-fold increase in DDT resistance. The amino acid lesions associated with these alleles defined four sites in the sodium channel polypeptide where a mutational change can cause resistance: within the intracellular loop between S4 and S5 in homology domains I and III, within the pore region of homology domain III, and within S6 in homology domain III. Some of these sites are analogous with those defined by knockdown resistance (kdr) and super-kdr resistance-associated mutations in houseflies and other insects, but are located in different homologous units of the channel polypeptide. We find a striking synergism in resistance levels with particular heterozygous combinations of para alleles that appears to mimic the super-kdr double mutant housefly phenotype. Our results indicate that the alleles analyzed from natural populations represent only a subset of mutations that can confer resistance. The implications for the binding site of pyrethroids and mechanisms of target-site insensitivity are discussed. Received: 9 May 1997 / Accepted: 21 July 1997     

Two novel sodium channel mutations associated with resistance to indoxacarb and metaflumizone in the diamondback moth,Plutella xylostella

Indoxacarb and metaflumizone belong to a relatively new class of sodium channel blocker insecticides (SCBIs). Due to intensive use of indoxacarb, field‐evolved indoxacarb resistance has been reported in several lepidopteran pests, including the diamondback moth Plutella xylostella, a serious pest of cruciferous crops. In particular, the BY12 population of P. xylostella, collected from Baiyun, Guangdong Province of China in 2012, was 750‐fold more resistant to indoxacarb and 70‐fold more resistant to metaflumizone compared with the susceptible Roth strain. Comparison of complementary DNA sequences encoding the sodium channel genes of Roth and BY12 revealed two point mutations (F1845Y and V1848I) in the sixth segment of domain IV of the PxNa_v protein in the BY population. Both mutations are located within a highly conserved sequence region that is predicted to be involved in the binding sites of local anesthetics and SCBIs based on mammalian sodium channels. A significant correlation was observed among 10 field‐collected populations between the mutant allele (Y1845 or I1848) frequencies (1.7% to 52.5%) and resistance levels to both indoxacarb (34‐ to 870‐fold) and metaflumizone (1‐ to 70‐fold). The two mutations were never found to co‐exist in the same allele of PxNa_v, suggesting that they arose independently. This is the first time that sodium channel mutations have been associated with high levels of resistance to SCBIs. F1845Y and V1848I are molecular markers for resistance monitoring in the diamondback moth and possibly other insect pest species.     

Polymorphism of intron-1 in the voltage-gated sodium channel gene of Anopheles gambiae s.s. populations from Cameroon with emphasis on insecticide knockdown resistance mutations

Sequence variation at the intron-1 of the voltage-gated sodium channel gene in Anopheles gambiae M- and S-forms from Cameroon was assessed to explore the number of mutational events originating knockdown resistance ( kdr ) alleles. Mosquitoes were sampled between December 2005 and June 2006 from three geographical areas: (i) Magba in the western region; (ii) Loum, Tiko, Douala, Kribi, and Campo along the Atlantic coast; and (iii) Bertoua, in the eastern continental plateau. Both 1014S and 1014F kdr alleles were found in the S-form with overall frequencies of 14% and 42% respectively. Only the 1014F allele was found in the M-form at lower frequency (11%). Analysis of a 455 bp region of intron-1 upstream the kdr locus revealed four independent mutation events originating kdr alleles, here named MS1 -1014F, S1-1014S and S2-1014S kdr- intron-1 haplotypes in S-form and MS3-1014F kdr- intron-1 haplotype in the M-form. Furthermore, there was evidence for mutual introgression of kdr 1014F allele between the two molecular forms, MS1 and MS3 being widely shared by them. Although no M/S hybrid was observed in analysed samples, this wide distribution of haplotypes MS1 and MS3 suggests inter-form hybridizing at significant level and emphasizes the rapid diffusion of the kdr alleles in Africa. The mosaic of genetic events found in Cameroon is representative of the situation in the West–Central African region and highlights the importance of evaluating the spatial and temporal evolution of kdr alleles for a better management of insecticide resistance.     

Inheritance of L1014F and M918T sodium channel mutations associated with pyrethroid resistance in Myzus persicae

Two amino acid substitutions (L1014F and M918T) in the voltage-gated sodium channel confer target-site resistance to pyrethroid insecticides in the peach potato aphid, Myzus persicae. Pyrethroid-resistant and -susceptible M. persicae clones with various combinations of these mutations were crossed under laboratory conditions, and the genotypes of aphid progeny were analysed by direct DNA sequencing of the IIS4-S6 region of the sodium channel gene. Segregation patterns showed that in aphids heterozygous for both L1014F and M918T, both mutations were present in the same resistance allele. Despite these mutations appearing largely recessive in other pest species, such aphids exhibited strong resistance to pyrethroids in leaf-dip bioassays. These results have important implications for the spread and management of pyrethroid resistance in field populations.