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为明确我国褐飞虱田间种群对氟啶虫胺腈的抗性现状及生化抗性机制,2017年-2019年采用稻茎浸渍法测定了采集自7省共13个褐飞虱田间种群对氟啶虫胺腈的抗性,并研究了氟啶虫胺腈抗性种群与其他杀虫剂的交互抗性以及增效剂对氟啶虫胺腈的增效效果。结果表明:近3年来褐飞虱对氟啶虫胺腈产生了中等水平抗性(RR=10.3~30.9)。氟啶虫胺腈抗性品系对呋虫胺、噻虫嗪和烯啶虫胺分别产生了9.1倍、7.9倍和4.1倍的低水平交互抗性,与噻嗪酮、毒死蜱、吡蚜酮、三氟苯嘧啶和吡虫啉不存在交互抗性。增效剂PBO对氟啶虫胺腈抗性品系和浙江龙游19(Longyou-19)田间种群分别具有4.2倍和3.8倍的明显增效作用。综上,褐飞虱田间种群已对氟啶虫胺腈产生中等水平抗性。多功能氧化酶参与了褐飞虱对氟啶虫胺腈的代谢抗性。 相似文献
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新型双酰胺类杀虫剂已广泛用于保障水稻生产,而二化螟作为危害水稻生产的钻蛀性害虫,已经对该类杀虫剂产生了抗性,明确该类杀虫剂抗性分子机制,可为二化螟抗性快速检测和绿色防控提供技术支撑。本文在总结二化螟对双酰胺类杀虫剂抗性现状的基础上,重点综述了近年来有关其抗性分子机制研究的进展,主要包括解毒酶和转运蛋白基因过表达介导的代谢抗性,以及鱼尼丁受体基因突变介导的靶标抗性;指出了该研究领域在抗性分子检测、抗性新基因鉴定、抗性基因调控网络和多重抗性机制等方面存在的问题,并展望了其发展方向,认为:利用高通量测序技术检测害虫种群抗药性;利用多组学技术鉴定新抗性基因及调控网络,以探明多重抗性机制;将反向遗传学工具放射性配基结合及电生理技术深入验证抗性基因功能;需开发靶向抗性基因的dsRNA转基因作物、纳米农药及选择性新型化学杀虫剂,以达到杀虫剂减施增效的目的。 相似文献
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灰飞虱对杀虫剂抗药性的研究进展 总被引:5,自引:0,他引:5
灰飞虱对杀虫剂产生抗药性是其近年来暴发频繁的重要原因。本文综述了国内外关于灰飞虱抗药性的研究成果,包括灰飞虱抗药性的发展、交互抗性、抗性机理、抗性遗传及生物适合度等。田间灰飞虱种群对多种药剂产生了不同程度的抗药性,其中对新烟碱类药剂吡虫啉和昆虫生长调节剂噻嗪酮产生了高水平到极高水平抗性(抗药性倍数分别为44.6~108.8倍和超过200倍),对有机磷类药剂毒死蜱和乙酰甲胺磷(抗药性倍数分别为10~12.6倍和9~13倍)、氨基甲酸酯类药剂甲萘威和残杀威(抗药性倍数分别为29.8~45.3倍和40.1~131.5倍)和拟除虫菊酯类药剂高效氯氰菊酯和溴氰菊酯(抗药性倍数分别为7.8~108.8倍和12~21倍)产生了中等水平到高水平的抗药性,对氟虫腈、阿维菌素和噻虫嗪没有产生抗药性(抗性倍数5倍)。长期大面积使用化学药剂是灰飞虱产生抗药性的重要原因。因此,必须加强灰飞虱的抗性治理,以延缓其抗药性进一步发展。 相似文献
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灰飞虱对几种杀虫剂的抗性 总被引:4,自引:0,他引:4
采用稻苗浸渍法测定了灰飞虱对7种常用杀虫剂的抗性。2011年监测了我国江苏、浙江、安徽三省9个灰飞虱种群对噻虫嗪、烯啶虫胺、毒死蜱、吡蚜酮、噻嗪酮、高效氯氰菊酯及氟虫腈的抗性。结果表明:灰飞虱对噻虫嗪都处于敏感阶段(0.6~2.2倍);对烯啶虫胺处于敏感阶段(0.8~3.0倍);对毒死蜱产生了中-高水平抗性(17.5~83.6倍);对吡蚜酮为敏感到低水平抗性(1.9~5.5倍);对噻嗪酮的抗性为高-极高水平(136.4~271.1倍);对高效氯氰菊酯的抗性为低-中等水平(5.2~34.9倍);对氟虫腈为低水平抗性(0.9~8.0倍)。基于灰飞虱对7种药剂的抗性情况,对田间治理灰飞虱合理使用药剂进行了讨论。 相似文献
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为明确2021—2022年华东4地区灰飞虱田间种群对常用杀虫剂的抗性现状及抗性机理,采用稻苗浸渍法分别测定了江苏仪征、盐城,浙江长兴和安徽庐江4地区灰飞虱田间种群对8种杀虫剂的抗性水平,并测定了3种解毒酶抑制剂增效醚(PBO)、顺丁烯二酸二乙酯(DEM)和磷酸三苯酯(TPP)对噻嗪酮防治灰飞虱的增效作用。结果表明:4个灰飞虱田间种群对噻嗪酮产生了中等至高水平抗性(抗性倍数RR=61.5~148.8);对毒死蜱产生了中等水平抗性(RR=14.9~28.3);对烯啶虫胺(RR=0.7~9.9)、噻虫嗪(RR=1.6~8.3)、呋虫胺(RR=2.9~10.0)和氟啶虫胺腈(RR=2.5~8.7)处于敏感至低水平抗性;对吡蚜酮(RR=1.0~5.0)和三氟苯嘧啶(RR=0.5~2.3)均仍处于敏感水平。增效试验结果显示,3种解毒酶抑制剂对噻嗪酮均无显著增效作用,表明3种解毒酶可能不参与灰飞虱对噻嗪酮的抗性。研究结果可为灰飞虱的田间抗性治理提供科学指导。 相似文献
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为明确河南省不同地区灰飞虱田间种群对12种常用杀虫剂的抗性现状,于2020—2021年,采用稻苗浸渍法分别测定了河南新乡、濮阳、开封、驻马店及信阳等地区灰飞虱田间种群对12种杀虫剂的抗性水平。结果表明:河南省灰飞虱田间种群对噻嗪酮产生了中等水平抗性,抗性倍数 (RR) =14.9~91.1;对吡蚜酮 (RR=6.91~16.7) 和毒死蜱 (RR=8.48~70.0) 产生了低至中等水平抗性;对三唑磷 (RR=1.29~11.1) 处于敏感至中等水平抗性;对噻虫嗪 (RR=0.95~5.19) 和高效氯氟氰菊酯 (RR=3.31~7.24) 处于敏感至低水平抗性;对吡虫啉 (RR=0.89~3.92)、啶虫脒 (RR=1.11~2.33)、烯啶虫胺 (RR=0.16~0.64)、呋虫胺 (RR=1.87~3.86)、异丙威 (RR=0.47~1.37) 和氟啶虫酰胺 (RR=1.63~4.33) 均仍处于敏感水平。研究结果可为河南省田间灰飞虱的可持续性防控以及杀虫剂的科学合理使用提供参考。 相似文献
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甲氨基阿维菌素苯甲酸盐(甲维盐)和虱螨脲是目前生产上防治草地贪夜蛾的主要杀虫剂,为评估其抗性风险,以福建省草地贪夜蛾田间种群为研究对象,在实验室抗性汰选品系选育基础上,采用数量遗传学域性状分析法并结合交互抗性测定,进行草地贪夜蛾对上述两种杀虫剂的抗性风险评估。结果表明:非连续汰选11代和10代后,草地贪夜蛾对甲维盐(F11)和虱螨脲(F10)的抗性倍数分别达30.57倍和11.35倍;抗性现实遗传力分别为0.403和0.555,且前半段筛选的抗性遗传力都远大于后半段;药剂在室内对草地贪夜蛾致死率为50%~90%时,对甲维盐和虱螨脲抗性倍数上升10倍需要汰选8~15代和6~12代。交互抗性测定显示,甲维盐汰选品系对氯虫苯甲酰胺、虱螨脲、虫螨腈无交互抗性,对茚虫威和乙基多杀菌素存在一定交互抗性。虱螨脲汰选品系对氯虫苯甲酰胺、甲维盐、茚虫威、虫螨腈和乙基多杀菌素均无交互抗性。结果表明:草地贪夜蛾对甲维盐和虱螨脲存在快速产生抗性的风险,但可通过与无交互抗性药剂轮用来延缓抗性发展。 相似文献
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利用室内筛选获得的甲氧虫酰肼中等抗性种群(R, 30.57倍)和敏感种群(S),采用浸叶法测定了棉铃虫对12种常用杀虫剂的交互抗性。结果表明抗性种群对虫酰肼产生了13.57倍的中等水平交互抗性;对茚虫威的抗性倍数为3.05倍,无明显交互抗性;而对辛硫磷、毒死蜱、灭多威、高效氯氰菊酯、溴氰菊酯、虫螨腈、虱螨脲、氟啶脲、氟铃脲和甲氨基阿维菌素苯甲酸盐的抗性倍数在0.50 ~2.36倍之间,无交互抗性。试验结果提示,在棉铃虫对甲氧虫酰肼的抗药性治理中,轮换使用与甲氧虫酰肼没有交互抗性的杀虫剂将可有效延缓其抗药性发展。 相似文献
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BACKGROUND: Glutathione S‐transferases (GSTs) have received considerable attention in insects for their roles in insecticide resistance. Laodelphax striatellus (Fallén) is a serious rice pest. L. striatellus outbreaks occur frequently throughout eastern Asia. A key problem in controlling this pest is its rapid adaptation to numerous insecticides. In this research, nine cDNAs encoding GSTs in L. striatellus were cloned and characterised. RESULTS: The cloned GSTs of L. striatellus belonged to six cytosolic classes and a microsomal subgroup. Exposure to sublethal concentrations of each of the six insecticides, DDT, chlorpyrifos, fipronil, imidacloprid, buprofezin and beta‐cypermethrin, quickly induced (6 h) up‐expression of LsGSTe1. The expression of LsGSTs2 was increased by chlorpyrifos, fipronil and beta‐cypermethrin. Furthermore, exposure of L. striatellus to fipronil, imidacloprid, buprofezin and beta‐cypermethrin increased the expression of the LsGSTm gene after 24 or 48 h. CONCLUSION: This work is the first identification of GST genes from different GST groups in Auchenorrhyncha species and their induction characteristics with insecticide types and time. The elevated expression of GST genes induced by insecticides might be related to the enhanced tolerance of this insect to insecticides and xenobiotics. Copyright © 2012 Society of Chemical Industry 相似文献
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Lihua Wang Yueliang Zhang Zhaojun Han Yanhe Liu Jichao Fang 《Pest management science》2010,66(10):1096-1100
BACKGROUND: Laodelphax striatellus (Fallén) is a major pest of cultivated rice and is commonly controlled in China with the organophosphate insecticides. To develop a better resistance management strategy, a chlorpyrifos‐resistant strain of L. striatellus was selected in the laboratory, and its cross‐resistance to other insecticides and possible mechanisms of the chlorpyrifos resistance were investigated. RESULTS: After 25 generations of selection with chlorpyrifos, the selected strain of L. striatellus developed 188‐fold resistance to chlorpyrifos in comparison with the susceptible strain, and showed 14‐ and 1.6‐fold cross‐resistance to dichlorvos and thiamethoxam respectively. There was no apparent cross‐resistance to abamectin. Chlorpyrifos was synergised by the inhibitor triphenyl phosphate; the carboxylesterase synergistic ratio was 3.8 for the selected strain, but only 0.92 for the susceptible strain. The carboxylesterase activity of the selected strain was approximately 4 times that of the susceptible strain, whereas there was no significant change in the activities of alkaline phosphatase, acid phosphatase, glutathione S‐transferase and cytochrome P450 monooxygenase between the strains. The Michaelis constant of acetylcholinesterase, maximum velocity of acetylcholinesterase and median inhibitory concentration of chlorpyrifos‐oxon on acetylcholinesterase were 1.7, 2.5 and 5 times higher respectively in the selected strain. CONCLUSION: The high cross‐resistance to the organophosphate dichlorvos in the chlorpyrifos‐resistant strain suggests that other non‐organophosphate insecticides would be necessary to counter resistance, should it arise in the field. Enhanced activities of carboxylesterase and the acetylcholinesterase insensitivity appear to be important mechanisms for chlorpyrifos resistance in L. striatellus. Copyright © 2010 Society of Chemical Industry 相似文献
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亚致死剂量氟啶虫胺腈对灰飞虱细胞色素P450的影响 总被引:2,自引:0,他引:2
为明确氟啶虫胺腈对灰飞虱Laodelphax striatellus细胞色素P450的影响,评估其抗药性风险,采用点滴法、酶活力分析法和实时荧光定量PCR法分别测定了氟啶虫胺腈对灰飞虱的毒性及对其细胞色素P450酶活力和P450基因表达量的影响。结果表明,氟啶虫胺腈对灰飞虱的致死中量LD_(50)随着虫龄的增加而升高,1~5龄若虫的LD_(50)为0.10~0.94 ng/头,雌、雄成虫的LD_(50)分别为1.09 ng/头和1.07 ng/头。氟啶虫胺腈对4龄若虫的亚致死剂量LD_(10)、LD_(30)和LD_(50)分别为0.17、0.41、0.76 ng/头,处理灰飞虱4龄若虫后可将其体内P450酶活力分别显著提高1.60、1.97和1.22倍;而各处理响应的P450基因的种类和数量不同,但相对表达量均受到诱导;CYP4DE1、CYP426A1、CYP303A1、CYP4C、CYP6FK1和CYP4C71v2的相对表达量表现出时间效应,表达量高峰在处理后24 h或48 h。表明不同亚致死剂量的氟啶虫胺腈在特定时间点可提高相应的细胞色素P450基因表达量,从而使酶蛋白量增加,可能导致灰飞虱体内细胞色素P450酶活力上升。 相似文献
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BACKGROUND: The cabbage whitefly, Aleyrodes proletella L., is emerging as a significant pest of field brassica crops in certain regions of the United Kingdom. In order to investigate the contribution of pesticide resistance to this phenomenon, A. proletella populations were sampled from five different areas in England in 2008 and 2009. Adult residual leaf‐dip bioassays were carried out using pyrethroid and neonicotinoid insecticides. RESULTS: Significant resistance to pyrethroids was found in multiple samples collected from two areas. No evidence of cross‐resistance to neonicotinoids was found in a subset of the pyrethroid‐resistant populations. While the patterns of resistance to different pyrethroids were broadly correlated, the magnitude of resistance factors differed substantially. Survival of strains at a putative diagnostic concentration of lambda‐cyhalothrin was found to provide a guide to their LC50. Significant differences in LC50 were found when different brassica crops were used in the bioassay, although the resistance patterns between strains were maintained. CONCLUSION: Reduced susceptibility to multiple pyrethroid insecticides exists in populations of A. proletella in the United Kingdom, corresponding to recent major outbreaks. The mechanism(s) of resistance are yet to be determined, but molecular structural differences in pyrethroids probably influence the magnitude of cross‐resistance within this group of insecticides. Copyright © 2011 Society of Chemical Industry 相似文献
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The bird cherry-oat aphid (Rhopalosiphum padi L.) is a devastating cereal pest that develops high resistance to organophosphate and carbamate insecticides. Because acetylcholinesterase (ACE) is the target of carbamate and organophosphate insecticides, the resistance mechanism usually involves mutations occurring in ACE-encoding genes, Ace1 and Ace2. Here, we describe a novel polymerase chain reaction (PCR)-based method for the diagnosis of resistance cases associated with the point mutation F368L in the Ace2 gene. We amplified a 127 bp DNA fragment from Ace2 gene using a modified reverse primer, and digested the amplification product using SmaI endonuclease. This procedure enabled a simple and rapid distinction between resistant and susceptible genotypes for F368L mutation. Subsequently, we screened 152 R. padi samples, and found that F368L mutation occurred at low frequency, in both the homozygous (R/R) and heterozygous (R/S) states. Based upon the results of this study, we believe that molecular diagnosis of insecticide resistance should be generalized to genes and mutations involved in this process, toward an optimal accuracy of insecticide applications. 相似文献
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Frederick W. Plapp 《Pesticide biochemistry and physiology》1984,22(2):194-201
Genetic evidence indicates that insecticide resistance in insects is controlled by relatively few genes. In the house fly, Musca domestica L., major resistance genes include one for decreased uptake of insecticides, three for changes at the target sites of insecticide action, and a single gene for metabolic resistance to multiple types of insecticides. The latter gene, which is located on chromosome II, interacts with minor genes located on other chromosomes. The product of the major gene for metabolic resistance appears to be a receptor protein which recognizes and binds xenobiotics, including insecticides and plant defense substances, and then induces synthesis of appropriate detoxifying enzymes. 相似文献
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目前化学防治仍是植物保护的重要手段,化学杀虫剂通过参与昆虫自然选择,诱导其产生可遗传的基因突变,从而导致昆虫抗药性的增加,近年来随着杀虫剂的广泛使用,抗药性已成为植物保护领域亟需解决的重大问题。利用分子生物学手段对由基因变异引起的昆虫抗药性进行解析已成为可能,在现今大多数昆虫抗药性研究中,功能基因组技术已被广泛用于候选基因调控抗药性机制的研究。本文介绍了双元基因表达技术——GAL4/UAS技术、基因干扰技术——RNAi技术和基因编辑技术——CRISPR/Cas9技术这3种有助于阐明昆虫抗药性分子机制的功能基因组技术,综述了这3种功能基因组技术在近几年昆虫抗药性研究中的应用实例,讨论了其目前的发展状况及其优势和局限性,以期在完善的功能基因组技术支持下为昆虫抗药性研究取得更多突破性进展。 相似文献
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Molecular approaches for characterization and use of natural disease resistance in wheat 总被引:3,自引:0,他引:3
Navreet Kaur Kenneth Street Michael Mackay Nabila Yahiaoui Beat Keller 《European journal of plant pathology / European Foundation for Plant Pathology》2008,121(3):387-397
Wheat production is threatened by a constantly changing population of pathogen species and races. Given the rapid ability
of many pathogens to overcome genetic resistance, the identification and practical implementation of new sources of resistance
is essential. Landraces and wild relatives of wheat have played an important role as genetic resources for the improvement
of disease resistance. The use of molecular approaches, particularly molecular markers, has allowed better characterization
of the genetic diversity in wheat germplasm. In addition, the molecular cloning of major resistance (R) genes has recently been achieved in the large, polyploid wheat genome. For the first time this allows the study and analysis
of the genetic variability of wheat R loci at the molecular level and therefore, to screen for allelic variation at such loci in the gene pool. Thus, strategies
such as allele mining and ecotilling are now possible for characterization of wheat disease resistance. Here, we discuss the
approaches, resources and potential tools to characterize and utilize the naturally occurring resistance diversity in wheat.
We also report a first step in allele mining, where we characterize the occurrence of known resistance alleles at the wheat
Pm3 powdery mildew resistance locus in a set of 1,320 landraces assembled on the basis of eco-geographical criteria. From known
Pm3 R alleles, only Pm3b was frequently identified (3% of the tested accessions). In the same set of landraces, we found a high frequency of a Pm3 haplotype carrying a susceptible allele of Pm3. This analysis allowed the identification of a set of resistant lines where new potentially functional alleles would be present.
Newly identified resistance alleles will enrich the genetic basis of resistance in breeding programmes and contribute to wheat
improvement. 相似文献