拟除虫菊酯抗性家蝇的交互抗药性研究

拟除虫菊酯的广泛使用使家蝇普遍产生了抗药性,为有效的控制家蝇的危害,需要了解家蝇对轮换或新杀虫剂的交互抗性状况。作者用点滴法测定了两个实验室汰选的拟除虫菊酯抗性家蝇品系对几种杀虫剂的交互抗性,结果表明:二氯苯醚菊酯和溴氰菊酯之间存在较高程度的交互抗药性;拟除虫菊酯抗性较高的家蝇对作用机制不同的新农药(多杀菌素、氟虫腈)表现较低程度的交互抗性。     

增效剂对桔小实蝇抗药性的影响

采用药膜法分别测定了增效醚（PBO）和磷酸三苯酯（TPP）两种增效剂对桔小实蝇抗敌百虫、高效氯氰菊酯和阿维菌素三个种群的抗药性产生的影响。结果表明,对这三种药剂分别产生的桔小实蝇抗性种群,PBO和TPP均能对其抗药性有一定的影响,但影响程度不同,对抗敌百虫、抗高效氯氰菊酯的两个桔小实蝇种群,TPP对敌百虫和高效氯氰菊酯的增效作用均高于PBO,且增效作用显著,增效比分别达3．98和2．43,PBO的增效比为1．71和1．66;对抗阿维菌素的桔小实蝇种群则略相反,PBO对阿维菌素的增效作用高于TPP,但增效作用均低于敌百虫与高效氯氰菊酯。     

杀虫双和杀螟丹选育对小菜蛾抗药性的形成及其抗性机制

用杀虫双和杀螟丹在实验室以点滴法处理小菜蛾Plutella xylostella L.四龄幼虫,以连续继代药剂淘汰选育其抗药性。至35代,药剂汰选的小菜蛾对杀虫双和杀螟丹的抗药性较选育前正常品系分别提高了51倍和25倍。其抗药性的形成发展均呈S形,可认为已成为抗性品系。以有机磷、氨基甲酸酯、拟除虫菊酯及有机氮等11种杀虫剂测试抗杀虫双小菜蛾品系和抗杀螟丹小菜蛾品系对常用药剂的敏感度结果表明：对杀虫双、杀螟丹和杀虫环之间有较严重的正交互抗性;对敌敌艮、马拉硫磷和杀螟松有轻微交互抗性产生;对溴氰菊酯、氯氰菊酯、氯菊酯和灭多威、久效威等药剂更加敏感,呈负交互抗性。用聚丙烯酰胺凝胶电泳(PAGE)法测定表明,抗药性产生与特异性酯酶的形成有一定关系。用比色法和酸度法测定,抗性品系的乙酰胆碱酯酶(AchE)活性降低,羧酸酯酶(CarE)活性无差异。加增效剂Pb和SV₁：于四龄幼虫表皮,对抗杀虫双小菜蛾晶系分别有6.28及1.45倍的增效作用;对抗杀螟丹小菜蛾品系分别有4.85及1.39倍的增效作用,可见多功能氧化酶(MFO)为小菜蛾抗杀虫双和抗杀螟丹的重要因子。     

北京和河北地区小菜蛾的抗药性动态

【目的】了解北京和河北地区小菜蛾Plutella xylostella(L.)对主要防治药剂的抗药性现状,为小菜蛾的有效防治提供参考。【方法】2011—2015年,采用浸叶法监测了小菜蛾对9种药剂的抗药性。【结果】小菜蛾对氯虫苯甲酰胺、多杀菌素和丁醚脲均为敏感水平,对Bt制剂、虫螨腈和茚虫威个别年份出现中等抗性水平,但总体上为敏感状态,对阿维菌素和氟啶脲保持中等抗性水平,对高效氯氰菊酯为中等至高水平抗性。【结论】在北京和河北地区高效氯氰菊酯不适用于小菜蛾的防治,少用或暂停使用阿维菌素,其它药剂可交替或轮换使用。     

斜纹夜蛾抗性种群中酶抑制剂对杀虫剂的增效作用（英文）

采用浸液生测法研究了斜纹夜蛾Spodoptera litura巴基斯坦抗性种群中酶抑制剂［胡椒基丁醚（PBO）和脱叶膦（DEF)］对丙溴磷、灭多威、硫双灭多威、氯氰菊酯、氯氟氰菊酯、联苯菊酯、茚虫威和多杀菌素等杀虫剂的增效作用。结果表明：PPO和DEF对氨基甲酸酯杀虫剂灭多威和硫双灭多威均具有增效作用,但对有机磷杀虫剂丙溴磷不具有增效作用。两种抑制剂对氯氰菊酯均产生增效作用,但对联苯菊酯没有增效作用。PPO 和DEF增加了氯氟氰菊酯对Multan种群的毒性,但没有增加其对Mailsi种群的毒性。DEF对多杀菌素具有增效作用,但PBO对其没有增效作用。PBO和DEF对氨基甲酸酯杀虫剂、拟除虫菊酯杀虫剂、茚虫威和多杀菌素具有明显的增效作用,这说明细胞色素P450单加氧酶和酯酶的解毒作用至少部分参与了斜纹夜蛾对这些杀虫剂的抗性过程。不过,两种增效剂对杀虫剂增效作用范围有限,暗示对于斜纹夜蛾巴基斯坦种群而言,其他的机制（如靶位点不敏感、表皮穿透作用降低）可能是更重要的抗性机制。     

烟粉虱对拟除虫菊酯杀虫剂的抗性机理

通过增效剂生物测定、生化分析以及钠离子通道基因ⅡS4-6 cDNA片段的RT-PCR扩增,探讨了烟粉虱Bemisia tabaci（Gennadius）对拟除虫菊酯杀虫剂的抗性机理。结果表明：对于采自田间的6个烟粉虱抗性品系,磷酸三苯酯（TPP）和胡椒基丁醚（PBO）对氯氰菊酯、溴氰菊酯、氯氟氰菊酯和甲氰菊酯均有显著的增效作用,而DEM对4种拟除虫菊酯杀虫剂均无明显的增效作用。烟粉虱抗性品系的α-NA羧酸酯酶和β-NA羧酸酯酶活性分别是敏感品系的2.16～2.65倍和1.22～1.41倍,抗性品系的谷胱甘肽S转移酶活性与敏感品系没有差异,表明羧酸酯酶和多功能氧化酶在烟粉虱对拟除虫菊酯类杀虫剂的抗性中具有重要的作用,而谷胱甘肽S转移酶与抗性无关。通过RT-PCR克隆了6个烟粉虱田间抗性品系的钠离子通道结构域ⅡS4-6 cDNA片段的序列（420 bp）,发现与敏感品系相比,有2个位点发生突变,分别为L925I突变和I917V突变,L925I突变在所有6个烟粉虱田间抗性种群中均有发生,该位点突变已被证实与拟除虫菊酯类杀虫剂密切相关,表明神经不敏感性可能是烟粉虱对拟除虫菊酯产生抗性的另一个重要因子。     

羧酸酯酶介导的小菜蛾对氟虫腈的抗性

【目的】羧酸酯酶（carboxylesterases, CarEs）是昆虫重要的解毒代谢酶之一,可以介导靶标昆虫对多种杀虫剂的代谢抗性。本研究检测了羧酸酯酶对小菜蛾Plutella xylostella 抗药性的介导功能,旨在阐明羧酸酯酶在小菜蛾代谢解毒中的生理生化和分子机理。【方法】采用点滴法测定氟虫腈对小菜蛾敏感种群和抗氟虫腈种群的毒力,以及羧酸酯酶抑制剂磷酸三苯酯（triphenyl phosphate, TPP）对氟虫腈的增效作用;以LC₃₀和LC₅₀浓度的氟虫腈处理抗性小菜蛾,测定药剂处理后CarEs酶活性的变化;利用qRT-PCR技术分析Pxae22和Pxae31两个基因在小菜蛾不同发育阶段、组织和种群的表达模式;利用dsRNA干扰Pxae22和Pxae31后观察基因的表达变化和小菜蛾3龄幼虫对药剂敏感性的变化。【结果】TPP可以削弱小菜蛾3龄幼虫对氟虫腈的抗性,增效倍数约为6倍;使用较低剂量（LC₃₀和LC₅₀）氟虫腈处理小菜蛾3龄幼虫后,处理组CarEs比活力明显高于对照,提示氟虫腈对小菜蛾CarEs活性具有诱导作用。对羧酸酯酶基因Pxae22和Pxae31在小菜蛾不同发育阶段、4龄幼虫不同组织和不同种群3龄幼虫中的表达模式分析发现,这两个基因在小菜蛾4龄幼虫中的表达量最高;在4龄幼虫中以中肠组织中的表达量较高,头、表皮、脂肪体中的表达量很低; 抗性种群中的表达量显著高于敏感种群。通过干扰 Pxae22和 Pxae31后的qRT-PCR验证,两个基因的表达量均显著降低,进一步的氟虫腈毒力测定发现,干扰P xae22和 Pxae31后的小菜蛾3龄幼虫对氟虫腈的敏感性分别增加了1.63倍和1.73倍。【结论】羧酸酯酶在小菜蛾对氟虫腈解毒代谢中具有重要作用;Pxae22和Pxae31是小菜蛾的两个抗性相关基因,其表达水平的变化直接影响小菜蛾对氟虫腈的敏感性。     

小菜蛾对定虫隆抗性种群的选育及交互抗性研究

用昆虫生长调节剂(insect growth regulator,简称IGR)定虫隆(chlorfluazuron)对源自深圳田间的小菜蛾(SZ-S)Plutella xylostella(L.)在室内进行抗性种群选育,经过8代饲养和6次药剂汰选,获得抗性种群(CH-R),与相对敏感种群Sz—S比较,抗性指数(R1)为23.78倍。CH-R种群在去除选择压力条件下饲养5代,抗性逐渐下降。抗性汰选前后分别测定了10种药剂的剂量—死亡毒力回归线,发现CH—R抗性种群对三氟氯氰菊酯、氯氰菊酯、辛硫磷、喹硫磷、灭多威、磺胺脲类衍生物—杀螨隆、微生物杀虫剂Bt和齐墩螨素无明显交互抗性,抗性倍数为0.4-1.7;对两种沙蚕毒素类杀虫剂杀螟丹和杀虫丹的敏感性却有所上升,有负交互抗性趋势。活体增效剂试验表明,增效醚(PBO)和三苯基磷酸酯(TPP)对定虫隆均有一定的增效活性,PBO的增效比最高为29倍,能够完全抑制对定虫隆的抗性,说明多功能氧化酶可能是主导抗性机制之一。     

高原春油菜田小菜蛾种群动态和抗药性的监测

【目的】为了准确掌握典型春油菜种植区小菜蛾Plutella xylostella(L.)种群变化动态和抗药性现状。【方法】诱捕法调查了青海高原小菜蛾成虫发生动态、室内用浸渍法测定了小菜蛾田间种群的抗性倍数,并进行了田间药效试验。【结果】青海省小菜蛾一般一年发生3代,但2 500 m以上的地区第3代成虫数量较第1代、第2代明显下降。在我省高原春油菜区,每日20:00至次日晨4:00是小菜蛾成虫发生主要的时间段。小菜蛾在青海省不能越冬。湟中点小菜蛾对溴虫腈产生低水平抗性;对多杀菌素、丁醚脲产生中等抗性水平;对Bt、高效氯氰菊酯、茚虫威产生高水平的抗性;对阿维菌素、啶虫隆、氯虫苯甲酰胺产生极高水平抗性。互助点小菜蛾对溴虫腈、丁醚脲产生低水平抗性;对多杀菌素、啶虫隆产生中等抗性水平;对Bt、氯虫苯甲酰胺、茚虫威产生高水平抗性;对阿维菌素产生极高水平抗性。小菜蛾的抗性监测结果与田间药效结果基本一致,溴虫腈的抗性倍数最低,田间防治效果好于其他参试药剂。【结论】青海省小菜蛾年发生代数较少,且不能越冬。春油菜田小菜蛾已对大部分农药产生了抗药性。     

棉铃虫对拟除虫菊酯杀虫剂敏感性的修复及其乙酰胆碱酯酶的变化

利用生物测定和生物化学方法研究了抗药性棉铃虫Helicoverpa armigera(Hubner)对拟除虫菊酯敏感性修复及其体内乙酰胆碱酯酶的变化,结果表明：当去除药剂选择压后,棉铃虫对拟除虫菊酯的抗性为不稳定。随着停止用药的时间加长,敏感性增加。从田间收集的棉铃虫在室内饲养后第1代对拟除虫菊酯的抗性下降速度较迅速。特异性酶抑制剂对敏感和抗性棉铃虫种群的乙酰胆碱酯酶亲和力试验结果证实,乙酰胆碱酯酶在抗性棉铃虫对杀虫剂反应发生变化的过程中发生改变,这种酶的改变可能对棉铃虫抗药性的不稳定性有重要影响。     

小菜蛾对杀螟丹抗性遗传的研究

利用室内选育的抗杀螟丹小菜蛾Plutella xylostella (L.)品系和敏感品系研究了该品系的抗性遗传形式,结果表明,小菜蛾对杀螟丹的抗性形式为常染色体多基因遗传,并呈不完全显性。该品系对６种常用杀虫剂的抗性谱测定结果表明,对杀虫双有较严重的正交互抗性;对敌敌畏、杀扑磷有低度交互抗性;对溴氰菊酯、灭多威和叶蝉散等药剂无交互抗性。还发现该品系对杀螟丹的抗性与乙酰胆碱酯酶和羧酸酯酶活性无关。     

小菜蛾溴氰菊酯敏感和抗性品系蛋白质表达谱的比较分析

杀虫剂抗性是害虫防治中的一个主要挑战。为有效治理抗性, 我们必须了解杀虫剂诱导的害虫生理生化变化。目前害虫抗药性的一些机理已经清楚, 但更多的相关机制还有待探究。本研究通过蛋白质组学方法检测了小菜蛾Plutella xylostella溴氰菊酯敏感和抗性品系间蛋白质组的表达差异。结果显示： SDS-PAGE胶上有大约300个蛋白差异点, 其中23个蛋白点具2.5倍以上的表达差异, 通过MALDI-TOF-MS, 我们成功鉴定出8个蛋白, 其中包括化感蛋白CSP2、 铜锌超氧化物歧化酶和peroxiredoxin样蛋白。通过实时定量PCR（real-time quantitative PCR, qPCR）分析了其中5个蛋白的mRNA 表达水平, 结果表明mRNA 表达水平不能真实反映蛋白的表达水平。免疫印迹验证了双向电泳中SOD1的表达差异。本研究有力地证明溴氰菊酯诱导小菜蛾成虫蛋白质组表达变化, 这为进一步筛选抗性靶标提供很大的帮助。     

溴氰菊酯胁迫下小菜蛾幼虫体内差异表达蛋白的分析

小菜蛾Plutella xylostella L.是世界性十字花科蔬菜的主要害虫, 已对多种杀虫剂产生抗性, 其中以对拟除虫菊酯类杀虫剂的抗性发展最快。溴氰菊酯是拟除虫菊酯杀虫剂中杀虫毒力最强的品种。我们前期的研究发现, 小菜蛾溴氰菊酯敏感品系（DS）和抗性品系（DR）成虫期的蛋白质双向电泳(2-DE)图谱存在显著差异。本研究通过双向电泳技术从小菜蛾4龄幼虫中分离出89个有明显差异的蛋白点, 从中选出30个进行串联质谱(MALDI-TOF-MS)实验, 并利用蛋白质数据库检索这些在抗性品系中表达而在敏感品系中不表达或者不同品系中差异表达的蛋白质的归属、 性质和功能, 最终成功鉴定出10个蛋白。对其中的3个基因进行了荧光定量PCR验证, 发现这些蛋白质在mRNA水平的表达与在蛋白水平的表达是一致的。这些在溴氰菊酯胁迫下差异表达的蛋白为研究溴氰菊酯的作用靶标和作用机理, 以及筛选与其抗性相关的蛋白质提供了依据。     

Insecticide toxicity, synergism and resistance in the German cockroach (Dictyoptera: Blattellidae)

The toxicity of synergism of and resistance to insecticides in four strains of German cockroach, Blattella germanica (L.), were investigated. Toxicity of nine insecticides by topical application to the susceptible strain varied greater than 2,000-fold, with deltamethrin (LD50 = 0.004 micrograms per cockroach) and malathion (LD50 = 8.4 micrograms per cockroach) being the most and least toxic, respectively. Resistance to pyrethrins (9.5-fold) in the Kenly strain was unaffected by the synergists piperonyl butoxide (PBO) or S,S,S-tributylphosphorotrithioate (DEF), suggesting that the metabolism is not involved in this case. Malathion resistance in the Rutgers strain was suppressible with PBO, implicating oxidative metabolism as a resistance mechanism. The Ectiban-R strain was resistant to all the pyrethroids tested, and cypermethrin resistance was not suppressible with PBO or DEF. These findings support results of previous studies that indicated this train has a kdr-like mechanism. Bendiocarb resistance in both the Kenly and Rutgers strains was partially suppressed by either PBO or DEF, suggesting that oxidative and hydrolytic metabolism are involved in the resistance. Trends between the effects of the synergists on the susceptible versus resistant strains are discussed.     

Insecticide resistance and cross-resistance in the house fly (Diptera: Muscidae)

A house fly strain, ALHF, was collected from a poultry farm in Alabama after a control failure with permethrin, and further selected in the laboratory with permethrin for five generations. The level of resistance to permethrin in ALHF was increased rapidly from an initial 260-fold to 1,800-fold after selection. Incomplete suppression of permethrin resistance by piperonyl butoxide (PBO) and S,S,S,-tributylphosphorotrithioate (DEF) reveals that P450 monooxygenase- and hydrolase-mediated detoxication, and one or more additional mechanisms are involved in resistance to permethrin. The ALHF strain showed a great ability to develop resistance or cross-resistance to different insecticides within and outside the pyrethroid group including some relatively new insecticides. Resistance to beta-cypermethrin, cypermethrin, deltamethrin, and propoxur (2,400-4,200-, 10,000-, and > 290-fold, respectively, compared with a susceptible strain, aabys) in ALHF house flies was partially or mostly suppressed by PBO and DEF, indicating that P450 monooxygenases and hydrolases are involved in resistance to these insecticides. Partial reduction in resistance with PBO and DEF implies that multiresistance mechanisms are responsible for resistance. Fifteen- and more than fourfold resistance and cross-resistance to chlorpyrifos and imidacloprid, respectively, were not effected by PBO or DEF, indicating that P450 monooxygenases and hydrolases are not involved in resistance to these two insecticides. Forty-nine-fold cross-resistance to fipronil was mostly suppressed by PBO and DEF, revealing that monooxygenases are a major mechanism of cross-resistance to fipronil. Multiresistance mechanisms in the ALHF house fly strain, however, do not confer cross-resistance to spinosad, a novel insecticide derived from the bacterium Saccharopolyspora spinosa. Thus, we propose that spinosad be used as a potential insecticide against house fly pests, especially resistant flies.     

Metabolic mechanisms only partially explain resistance to pyrethroids in Australian broiler house populations of lesser mealworm (Coleoptera: Tenebrionidae)

The susceptibility of six Australian broiler house populations and an insecticide susceptible population of lesser mealworm, Alphitobius diaperinus (Panzer) (Coleoptera: Tenebrionidae), to cyfluthrin, beta-cyfluthrin, gamma-cyhalothrin, and deltamethrin was investigated. One broiler house population had equivalent susceptibility to the susceptible to beta-cyfluthrin and beta-cyhalothrin, with higher susceptibility to cyfluthrin and deltamethrin. The remaining five populations demonstrated strong resistance to cyfluthrin (19-37-fold), the insecticide used most widely for management of A. diaperinus in Australia. Each cyfluthrin-resistant population demonstrated reduced susceptibility to beta-cyfluthrin (resistance ratios were 8-17-fold), deltamethrin (2.5-8-fold), and gamma-cyhalothrin (6-12-fold) compared with the laboratory population, but cross-resistance patterns varied considerably between populations. Adding piperonyl butoxide (PBO) had no effect on the susceptibility of the susceptible population to any of the insecticides, but it increased the susceptibility of each of the five cyfluthrin-resistant populations: to cyfluthrin (synergism ratio range, 1.9-5.0-fold), beta-cyfluthrin (1.6-4.1-fold), and y-cyhalothrin (1.7-2.0-fold). PBO had a more variable effect on susceptibility to deltamethrin, with three of the cyfluthrin-resistant populations being more susceptible to deltamethrin in the presence of PBO, but susceptibility of the remaining two populations was unaffected by adding PBO (synergism ratio range, 0.9-2.5-fold). Overall, the addition of PBO to the four pyrethroids had variable effects on their susceptibility. This variability indicated the presence of other resistance mechanisms in beetle populations apart from metabolic resistance. In addition, the relative importance of metabolic resistance in each beetle population varied widely between pyrethroids. Thus, it cannot be assumed that PBO will reliably synergize pyrethroids against cyfluthrin-resistant lesser mealworm populations when using it to mitigate insecticide resistance.     

小菜蛾对溴氰菊酯抗性相关的DNA片段的克隆与分析

采用代表性差异分析（representational difference analysis, RDA ）方法,以小菜蛾Plutella xylostella (L.)的敏感品系作为对照组,溴氰菊酯抗性近等基因系（near isogenic line）作为测试组,通过三轮消减杂交得到大小为 150～300 bp的差异扩增带,经亚克隆测序并与GenBank等数据库同源比较,发现差异片段与已知抗性相关基因无同源性;以随机选取的差异片段作探针进行Southern blot分析,在测试组扩增子和三轮差异产物中都获得了阳性结果,而在对照组扩增子中的结果是阴性的。这些结果表明测序片段可能是与抗性相关的新基因序列或调控序列。     

Insecticide Mixtures Could Enhance the Toxicity of Insecticides in a Resistant Dairy Population of Musca domestica L

House flies, Musca domestica L., are important pests of dairy operations worldwide, with the ability to adapt wide range of environmental conditions. There are a number of insecticides used for their management, but development of resistance is a serious problem. Insecticide mixtures could enhance the toxicity of insecticides in resistant insect pests, thus resulting as a potential resistance management tool. The toxicity of bifenthrin, cypermethrin, deltamethrin, chlorpyrifos, profenofos, emamectin benzoate and fipronil were assessed separately, and in mixtures against house flies. A field-collected population was significantly resistant to all the insecticides under investigation when compared with a laboratory susceptible strain. Most of the insecticide mixtures like one pyrethroid with other compounds evaluated under two conditions (1∶1-“A” and LC₅₀: LC₅₀-“B”) significantly increased the toxicity of pyrethroids in the field population. Under both conditions, the combination indices of pyrethroids with other compounds, in most of the cases, were significantly below 1, suggesting synergism. The enzyme inhibitors, PBO and DEF, when used in combination with insecticides against the resistant population, toxicities of bifenthrin, cypermethrin, deltamethrin and emamectin were significantly increased, suggesting esterase and monooxygenase based resistance mechanism. The toxicities of bifenthrin, cypermethrin and deltamethrin in the resistant population of house flies could be enhanced by the combination with chlorpyrifos, profenofos, emamectin and fipronil. The findings of the present study might have practical significance for resistance management in house flies.