西花蓟马对烯啶虫胺、噻虫胺和噻虫嗪的抗性风险和抗性稳定性

为明确使用新烟碱类杀虫剂烯啶虫胺、噻虫胺和噻虫嗪防治入侵害虫西花蓟马的抗性风险及抗性稳定性,本研究采用芸豆浸药法对西花蓟马敏感种群初羽化雌成虫进行连续筛选获得抗性种群,根据抗性现实遗传力计算公式分析西花蓟马对上述3种杀虫剂的抗性风险,预测其抗性发展速度,并测定抗性稳定性。结果表明: 经过30代抗性筛选,西花蓟马对烯啶虫胺、噻虫胺和噻虫嗪均达到高水平抗性(44.7、45.5和32.7倍)。西花蓟马对噻虫胺、烯啶虫胺和噻虫嗪的抗性发展速度依次降低,抗性现实遗传力分别为0.1503、0.1336和0.1258。对抗性种群在无选择压力下继续饲养10代,西花蓟马对烯啶虫胺、噻虫胺和噻虫嗪的抗性水平均出现一定程度的下降,但均未能恢复到敏感性水平。抗性选育后,西花蓟马若虫与成虫对杀虫剂的敏感性差异显著缩小,西花蓟马敏感种群及抗性种群若虫对上述3种杀虫剂的敏感性显著高于成虫。西花蓟马对烯啶虫胺、噻虫胺和噻虫嗪均存在高抗风险,噻虫嗪的抗性上升速度较慢且抗性稳定性最低。因此,在西花蓟马若虫期使用噻虫嗪有利于西花蓟马防治。     

北京和云南地区西花蓟马对多杀菌素类药剂产生抗药性

【目的】了解我国西花蓟马Frankliniella occidentalis(Pergande)对多杀菌素等药剂的抗药性现状,为西花蓟马的有效防治提供参考。【方法】2011—2015年,采用叶管药膜法对北京和云南地区西花蓟马进行了抗药性监测。【结果】与室内敏感品系相比,北京地区西花蓟马田间种群对多杀菌素的抗性倍数达到80~150倍,对乙基多杀菌素抗性倍数高达7 730倍,对乙基多杀菌素的LC50值5年间最高增加了258倍,对甲维盐和噻虫嗪具有中等水平抗性,对阿维菌素和虫螨腈处于敏感或低水平抗性;昆明地区西花蓟马对乙基多杀菌素的抗性水平达到305倍的极高抗水平,对其它药剂相对敏感或处于低水平抗性。【结论】北京和云南地区西花蓟马对多杀菌素类药剂已经产生高水平抗药性,应密切关注抗性发展动态,同时进一步研究其抗性机制。     

西花蓟马对吡虫啉、辛硫磷和甲维盐的抗性风险和抗性稳定性

为有效控制西花蓟马的危害,采用吡虫啉、辛硫磷和甲维盐药液浸泡芸豆法,分别对西花蓟马敏感种群成虫进行抗性选育,获得抗性种群,应用抗性现实遗传力分析抗性遗传和抗性风险.结果表明:经过32代、32代和24代抗性选育,西花蓟马对吡虫啉、辛硫磷和甲维盐的抗性分别达到13.8、29.4和39.0倍.西花蓟马对吡虫啉、辛硫磷和甲维盐的现实抗性遗传力分别为0.112、0.166和0.259,西花蓟马对甲维盐的抗性上升速度最快,辛硫磷次之,吡虫啉最低.经过药剂筛选后,西花蓟马若虫与成虫对杀虫剂的敏感性差异较敏感种群显著缩小.停止用药剂筛选后继续饲养12代,西花蓟马对吡虫啉、辛硫磷和甲维盐的抗性水平都有一定程度下降,但都没有恢复到敏感性水平.西花蓟马对吡虫啉、辛硫磷和甲维盐具有较高水平抗性的风险,其中对吡虫啉的抗性发展速度相对较慢,且下降速度较快,因此选用吡虫啉防治西花蓟马更合适.     

西花蓟马抗噻虫胺种群对杀虫剂的交互抗性及机制

噻虫胺是具有内吸和触杀等多种作用方式的新烟碱类杀虫剂,常用于防治入侵害虫西花蓟马。为明确抗性风险,本文研究了西花蓟马抗噻虫胺种群对多种杀虫剂的交互抗性及其机制。经过45代筛选,西花蓟马对噻虫胺产生了高水平抗性(56.8倍)。生物测定结果表明: 西花蓟马高抗噻虫胺种群与噻虫嗪、吡虫啉、毒死蜱、三氟氯氰菊酯、甲维盐存在中等水平交互抗性(18.6>RR₅₀>11.3),对辛硫磷及灭多威具有低水平交互抗性,与溴虫腈和多杀菌素不存在交互抗性。胡椒基丁醚(PBO)与磷酸三苯酯(TPP)对杀灭西花蓟马抗噻虫胺种群(CL)、云南田间种群(YN)和敏感种群(S)均有显著增效作用。西花蓟马抗噻虫胺种群细胞色素P₄₅₀含量(3.6倍)、细胞色素b₅含量(2.9倍)及O-脱甲基酶活性(4.9倍)和羧酸酯酶活性(2.5倍)均显著高于敏感种群,表明多功能氧化酶及羧酸酯酶活性增强是西花蓟马对噻虫胺产生抗性的重要机制。     

六种常见杀虫剂对西花蓟马和花蓟马的毒力测定

为了明确常用杀虫剂对入侵害虫西花蓟马和本地近缘优势种花蓟马的毒力作用,在室内采用菜豆浸渍饲喂法,分别测定了6种常用杀虫剂对云南昆明地区两种蓟马2龄若虫、雌虫及雄虫的毒力。结果表明:6种杀虫剂对西花蓟马和花蓟马2龄若虫和成虫的LC_(50)以6%乙基多杀菌素的最低,对西花蓟马和花蓟马2龄若虫和成虫LC_(50)值分别为:0.611、0.333 mg/L和1.731、1.202 mg/L;LC_(50)值以10%吡丙醚最高,对西花蓟马和花蓟马2龄若虫和成虫LC_(50)值分别为1238.005、845.819 mg/L和9037.110、4766.376 mg/L。6种杀虫剂对西花蓟马和花蓟马各虫态的毒力作用依次为:乙基多杀菌素阿维菌素溴氰菊酯啶虫脒吡虫啉吡丙醚,且所有供试杀虫剂对西花蓟马LC_(50)均大于花蓟马,对雌虫LC_(50)大于雄虫。说明了蓟马雌虫对杀虫剂的敏感度低于雄虫,且生物源杀虫剂的室内杀虫效果强于化学杀虫剂,是西花蓟马防治中优先选择的杀虫剂。     

西花蓟马对吡虫啉的抗性机制及交互抗性研究

为了解西花蓟马Frankliniella occidentalis(Pergande)对吡虫啉的抗性风险,本文就吡虫啉的交互抗性和抗性机制(增效剂和酶活性)进行了研究。结果表明,经过35代筛选,西花蓟马对吡虫啉的抗性上升到21.26倍。西花蓟马对吡虫啉与阿维菌素和甲维盐存在中等水平交互抗性,与氯氟氰菊酯、灭多威和毒死蜱存在低水平交互抗性。增效剂试验表明,三丁基三硫磷酸酯(DEF)、磷酸三苯酯(TPP)和马来酸二乙酯(DEM)具有显著增效(SR50,DEF=6.38,SR50,TPP=5.52,SR50,DEM=1.60,P<0.05)。生化测定表明:抗吡虫啉品系西花蓟马的羧酸酯酶(5.06倍)和谷胱甘肽S-转移酶酶活性(1.63倍)均显著(P<0.05)高于敏感品系,表明羧酸酯酶和谷胱甘肽S-转移酶酶活性的提高是西花蓟马对吡虫啉产生抗药性的主要原因。     

北京地区西花蓟马田间种群的抗药性监测

采用叶管药膜法在室内测定了2009—2010年北京海淀地区和昌平地区西花蓟马Frankliniella occidentalis(Pergande)田间种群对12种杀虫剂敏感性的年度变化。结果表明,北京昌平和海淀地区的西花蓟马对多数的药剂仍处于敏感状态,但对氯氟氰菊酯已产生近40倍的抗性,昌平种群对多杀菌素具有产生低水平抗性的趋势(抗性倍数为4倍)。推荐药剂包括多杀菌素、阿维菌素、甲氨基阿维菌素苯甲酸盐(甲维盐)、毒死蜱和溴虫腈,应注意与其它药剂的轮换使用,灭多威对西花蓟马的毒力水平最低,不推荐使用。     

外来入侵害虫西花蓟马防控技术研究与示范

针对入侵害虫西花蓟马Frankliniella occidentalis(Pergande)在我国部分地区暴发成灾的形势,公益性行业科研专项"外来入侵害虫西花蓟马防控技术研究与示范"项目组在除西藏、台湾、香港和澳门以外的30个省、区和直辖市开展了西花蓟马的调查、监测、预警和综合防控技术研究与示范。结果表明西花蓟马在北京、云南、浙江、山东等14个省市发生危害,尤以云南和北京两地最为严重,在全国呈快速蔓延趋势。明确了西花蓟马在我国的成灾机制;建立了西花蓟马高效诱捕技术;筛选出4种对西花蓟马具有显著控害潜力的本土天敌昆虫及病原微生物;筛选出5种对西花蓟马高效、对环境友好的防治药剂;明确西花蓟马重要发生区域北京和云南种群对主要化学药剂的抗性和机制;分别组建了基于农业措施防治、色板与引诱剂应用的引诱技术、生物防治和高效环保化学农药综合应用的10套西花蓟马防控技术体系,在我国北京、云南、山东和浙江等西花蓟马主要发生区域累计推广面积2.65万公顷,有效控制了西花蓟马的为害和扩散蔓延。     

西花蓟马田间种群对常用杀虫剂的抗性现状及防治对策

【目的】西花蓟马Frankliniella occidentalis在中国是一种严重危害温室蔬菜的入侵害虫。本研究旨在了解该害虫在中国的抗药性现状,为防治该害虫提供理论支持。【方法】采用Munger cell法测定了北京,山东寿光和青岛以及云南晋宁和呈贡等5个地区西花蓟马田间种群对多杀菌素、毒死蜱、阿维菌素、甲维盐、氟氯氰菊酯、溴虫腈、灭多威、吡虫啉和啶虫脒9种杀虫剂的抗药性水平,同时利用这些田间种群测定了多功能氧化酶抑制剂胡椒基丁醚（PBO）、谷胱甘肽S 转移酶抑制剂顺丁烯二酸二乙酯（DEM）和羧酸酯酶抑制剂三丁基三硫磷酸酯（DEF）对多杀菌素、吡虫啉和甲维盐的增效作用。【结果】生物测定结果表明,北京、晋宁及呈贡种群分别对多杀菌素产生了34.45, 47.45和64.45倍的高水平抗性;晋宁种群对灭多威和甲维盐分别产生了16.58和11.03倍的中等水平抗性;呈贡种群对甲维盐、啶虫脒、吡虫啉、阿维菌素、溴虫腈分别产生了24.17, 21.69, 20.05, 16.45和10.31的中等水平抗性;青岛种群对啶虫脒和吡虫啉产生了17.70和12.49倍的中等水平抗性;寿光种群没有对任何杀虫剂产生高等或中等水平抗性。增效剂生物测定结果表明,对于吡虫啉和甲维盐,多功能氧化酶抑制剂PBO在所有田间种群上均有显著的增效作用。谷胱甘肽S-转移酶抑制剂DEM在呈贡、寿光和青岛种群中对吡虫啉存在显著增效作用;在北京、呈贡和寿光种群中,DEM对甲维盐存在显著增效作用。羧酸酯酶抑制剂DEF在呈贡、晋宁和青岛种群中对吡虫啉存在显著增效作用;在北京、呈贡和晋宁种群中,DEF对吡虫啉存在显著增效作用。但所有增效剂在各田间种群中对多杀菌素均无显著增效作用。【结论】结果提示：在使用多杀菌素防治西花蓟马时,应与其他杀虫剂轮换使用;此外,可通过添加酶抑制剂来增强甲维盐和吡虫啉对西花蓟马的防效。     

5种杀虫剂对西花蓟马和花蓟马的毒力及其生理酶活性的影响

【目的】探究不同杀虫剂对重要入侵害虫西花蓟马及其本地近缘种花蓟马的毒力及对保护酶和解毒酶活性的影响,为进一步研究2种害虫的抗性管理提供依据。【方法】采用浸渍法测定5种田间常用杀虫剂对西花蓟马和花蓟马的毒力,并测定杀虫剂亚致死浓度(LC25)下2种蓟马体内保护酶和解毒酶活性的差异。【结果】不同杀虫剂对2种蓟马的毒力依次为:乙基多杀菌素甲维盐阿维菌素吡虫啉噻虫嗪,乙基多杀菌素对西花蓟马和花蓟马的LC_(50)分别为0.28和0.03 mg·L~(-1)。不同药剂的亚致死剂量(LC_(25))对西花蓟马和花蓟马体内保护酶和解毒酶活性普遍具有诱导作用。其中,阿维菌素对西花蓟马超氧化物歧化酶(SOD)活性诱导作用最强,为326.40 U·mg~(-1),是对照的9.37倍,而乙基多杀菌素对花蓟马SOD活性诱导作用最强,为245.35 U·mg~(-1),是对照的9.32倍;吡虫啉对西花蓟马和花蓟马过氧化物酶(POD)诱导作用最强,分别为298.67和246.79 U·mg~(-1),是对照的37.10和20.57倍;阿维菌素对西花蓟马和花蓟马过氧化氢酶(CAT)和羧酸酯酶(CarE)诱导作用最强,分别为298.67、246.79 U·mg~(-1)(CAT活性)和12.53、11.99 U·mg~(-1)(CarE活性);乙基多杀菌素对西花蓟马和花蓟马谷胱甘肽转移酶(GST)和乙酰胆碱酯酶(AChE)诱导作用最强,分别为77527.59、66927.39 U·mg~(-1)(GST活性)和2.34、2.22 U·mg~(-1)(AChE活性)。【结论】5种杀虫剂中,乙基多杀菌素对2种蓟马的毒力最强;西花蓟马对杀虫剂的解毒代谢能力强于花蓟马。     

Biotic resistance limits the invasiveness of the western flower thrips,Frankliniella occidentalis (Thysanoptera: Thripidae), in Florida

The spread of the western flower thrips, Frankliniella occidentalis (Pergande), has resulted in the world‐wide destabilization of established integrated pest management programs for many crops. It is hypothesized that frequent exposure to insecticides in intensive agriculture selected for resistant populations, which allowed invasive populations in the eastern USA to overcome biotic resistance from the native community of species. Research conducted in Florida to understand the role of biotic factors in limiting the abundance of the western flower thrips is reviewed. Orius spp. (Hemiptera: Anthocoridae) are effective predators that suppress populations of thrips on crop and non‐crop hosts in southern and northern Florida. Orius are more effective predators of the western flower thrips than the native flower thrips, F. tritici (Fitch) and F. bispinosa (Morgan). The native species are competitors of the western flower thrips. Excessive fertilization and the use of broad‐spectrum insecticides in crop fields further enhances populations of the western flower thrips. Interactions with native species clearly limit the abundance of western flower thrips in Florida, but populations are abundant in fertilized crop fields where application of insecticides excludes predators and competitor species.     

不同辣椒品种抗（耐）西花蓟马的初步筛选及苗期防御酶的变化

【背景】西花蓟马自2003年传入我国以来,呈扩张趋势。辣椒上西花蓟马以化学防治为主,国内尚无抗性资源保护、抗（耐）虫性资源筛选等相关研究。【方法】以20个辣椒品种和西花蓟马为材料,采用幼苗接虫法,根据危害症状分级,计算为害指数并作为抗（耐）评价指标,然后测定不同抗（耐）材料苗期受西花蓟马危害后防御酶活性的变化,探讨其与抗性的关系。【结果】在20个供试辣椒品种中,湘研13号和博辣4号对西花蓟马的抗性较强,其他品种抗性较差,兴蔬绿剑抗性最差;不同辣椒品种抗（耐）虫性与过氧化物酶变化呈正相关,但与过氧化氢酶相关性不显著。【结论与意义】本研究建立了辣椒抗（耐）西花蓟马的筛选评价体系,为挖掘抗西花蓟马的种质资源和西花蓟马的有效防控提供了依据。     

天敌昆虫抗药性研究进展

天敌昆虫抗药性研究在协调害虫化学防治和生物防治中有着重要的理论和现实意义,其研究的最终目的在于更好地推进抗性天敌在害虫综合治理(IPM)中的应用。抗药性天敌昆虫具有潜在的巨大价值。鉴于此,本文系统地综述了天敌昆虫抗药性最新研究进展,包括杀虫剂对天敌昆虫的影响、天敌昆虫抗药性现状、抗药性机理和限制天敌昆虫抗药性发展因素等。文章最后还对抗药性天敌昆虫的应用前景进行了展望。     

Impact of production system on development of insecticide resistance in Frankliniella occidentalis (Thysanoptera: Thripidae)

The western flower thrips, Frankliniella occidentalis (Pergande) (Thysanoptera: Thripidae), has become one of the most difficult insects to control in the intensive agriculture of southeastern Spain. However, resistance problems are quite different in two neighboring areas, Murcia and Almeria, with distinct production systems. Thirty-six field populations of western flower thrips from sweet pepper crops were collected in two different dates in Murcia and Almeria in 2005 and 2006. Western flower thrips populations collected were exposed to a diagnostic concentration of spinosad, methiocarb, acrinathrin, and formetanate. The results allowed the recognition of higher levels of resistance in Almeria compared with Murcia throughout the growing season. The mortality at the diagnostic concentration for spinosad (120 ppm) in western flower thrips populations ranged from 34 to 81% in Almeria, and from 73 to 100% in Murcia. The mortalities at the diagnostic concentration to acrinathrin (800 ppm) and formetanate (8000 ppm) were 17-31% in Almeria and 77-100% in Murcia, and 14-41% in Almeria and 48-99% in Murcia, respectively, indicating large geographic variations. Toxicity of methiocarb was higher for western flower thrips populations from both areas. However, mortality at the diagnostic concentration of methiocarb (2000 ppm) varied from 56 to 90% in Almeria, and it was from 94 to 100% in Murcia. The impact of production systems and agricultural practices of each area on the development and stability of insecticide resistance is discussed.     

基于生物防治的西花蓟马治理及思考

西花蓟马Frankliniella occidentalis（Pergande）是世界性的大害虫,对温室中蔬菜花卉造成巨大的危害。20世纪70年代后在世界范围内广泛而迅速地传播蔓延,近年入侵中国。西花蓟马对农药产生了广泛的抗性,使得生物防治一直作为其综合治理中的主导措施。本文综述了世界上西花蓟马生物防治的现状,以期为中国西花蓟马的治理提供一定的借鉴作用。     

Life-stage variation in insecticide resistance of the western flower thrips (Thysanoptera: Thripidae)

The life-stage variations in insecticide resistance of western flower thrips, Frankliniella occidentalis (Pergande) (Thysanoptera: Thripidae), to selective insecticides (acrinathrin, formetanate, and methiocarb) were studied using resistant laboratory strains. In each strain, the second-instar larva was less susceptible to the insecticides tested than the adults. The lower the resistance level of the adults, the higher the difference between larva and adult susceptibility: 32-fold to methiocarb, 15.4-fold to formetanate, and 180-fold to acrinathrin in the reference strain. In laboratory-selected resistant strains, these differences were much lower: 5.8-fold to methiocarb, 4.8-fold to formetanate, and 2.0-fold to acrinathrin. In selected strains, higher resistance levels for each insecticide were found, both for larvae and adults, compared with the reference strain. These results show that after insecticide resistance selection in adults, the resistance is carried over to the larvae, but at lower levels.     

Evaluation of efficacy of Neoseiulus cucumeris for control of western flower thrips in spring bedding crops

Western flower thrips, Frankliniella occidentalis (Pergande), is the principal insect pest of spring flower crops grown in the northeastern United States for use as bedding plants. Neoseiulus (=Amblyseius) cucumeris (Oudemans) is a predacious mite reared commercially that is recommended for control of western flower thrips in various vegetable and flower crops at a rate of ca 53 mites/m²/week. Efficacy on spring flower crops, however, is not well demonstrated, reports being either from other crops or extension demonstration trials. In two trials (each replicated), we compared suppression of western flower thrips in spring bedding plants provided by (1) N. cucumeris at the recommended rate, (2) spinosad (at the labeled rate), the most widely used thrips-control pesticide, and (3) both combined. Trial No. 1 was run in mixed bedding plants in commercial greenhouses and Trial No. 2 in impatiens monocultures in University greenhouses. We found that in commercial greenhouses, variation in species composition of crops and movement of plants during crop production made it difficult to detect any significant effects. In an impatiens monoculture (Trial No. 2), we found better evidence of partial suppression of thrips larvae and adults by treatments. Spinosad alone provided the best control, with mites alone usually providing control intermediate to that of spinosad alone and the untreated control. Control from spinosad plus mites was not significantly different from that of spinosad alone (all treatments evaluated as counts of thrips per plant, in flowers). In another University-based trial (Trial No. 3), we compared the commercially recommended rate of N. cucumeris (53 mites/m²/week) to a 3- to 4-fold higher rate (190 mites/m²/week) in impatiens monocultures. This trial was replicated twice in the fall of 2004 and once in spring of 2005 in Amherst, Massachusetts. We found that the higher release rate, while not resulting in statistically significantly more mites per plant (in flowers) than the standard rate, did suppress thrips larvae per plant (in flowers) by 50–75%, a higher level than that achieved by the recommended standard rate. No reductions, however, were found in counts of adult thrips, either as numbers per plant (in flowers) or as numbers caught per yellow sticky card, except for one replication in which thrips counts were lowered compared to controls by mites (at both release rates). We conclude that N. cucumeris, especially at the higher rate, provides partial control of western flower thrips in impatiens bedding plants, but that control from spinosad is better. Biological control of western flower thrips with this predator is not a complete thrips IPM program, but may be used together with spinosad or other materials to prevent development of pesticide resistance. This approach is most likely to be of value in crops grown as continuous relay plantings or a series of different, but thrips-susceptible, crop species.     

Engineered multidomain cysteine protease inhibitors yield resistance against western flower thrips (Frankliniella occidentalis) in greenhouse trials

Western flower thrips, Frankliniella occidentalis (Pergande) (Thysanoptera: Thripidae), cause very large economic damage on a variety of field and greenhouse crops. In this study, plant resistance against thrips was introduced into transgenic potato plants through the expression of novel, custom-made, multidomain protease inhibitors. Representative classes of inhibitors of cysteine and aspartic proteases [kininogen domain 3 (K), stefin A (A), cystatin C (C), potato cystatin (P) and equistatin (EIM)] were fused into reading frames consisting of four (K-A-C-P) to five (EIM-K-A-C-P) proteins, and were shown to fold into functional inhibitors in the yeast Pichia pastoris. The multidomain proteins were expressed in potato and found to be more resistant to degradation by plant proteases than the individual domains. In a time span of 14-16 days, transgenic potato plants expressing EIMKACP and KACP at a similar concentration reduced the number of larvae and adults to less than 20% of the control. Leaf damage on protected plants was minimal. Engineered multidomain cysteine protease inhibitors thus provide a novel way of controlling western flower thrips in greenhouse and field crops, and open up possibilities for novel insect resistance applications in transgenic crops.     

The spread of the western flower thrips Frankliniella occidentalis (Pergande)

Abstract 1 Since the late 1970s, the western flower thrips has spread from its original distribution in western North America to become a major worldwide crop pest. 2 A wide range of data sources have been used to map the original distribution in the U.S.A. and Canada, and the progress of the spread in the U.S.A., Canada, Europe, northern Africa and Australia. 3 The possible reasons for the start of the spread are discussed. The most likely reason is that intensive insecticide use in horticulture in the 1970s and 1980s selected an insecticide resistant strain or strains. These then established in glasshouses across North America and spread from there to Europe, Asia, Africa and Australia. 4 The international spread of the western flower thrips occurred predominantly by the movement of horticultural material, such as cuttings, seedlings and potted plants. Within Europe, an outward spread from the original outbreak in the Netherlands is discernible. The speed of spread was 229 ± 20 km/year. 5 The spread has not been restricted to glasshouses. The western flower thrips has established outdoors in areas with milder winters; for example, across the southern U.S.A., southern Europe and Australia. It also overwinters in some regions with colder winters. 6 Polyphagous phytophagous thrips have many factors predisposing them to become worldwide crop pests, particularly in glasshouses. Some other species that might spread in a similar way to the western flower thrips are listed.