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.     

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.     

Development and stability of insecticide resistance in the leafminer Liriomyza trifolii (Diptera: Agromyzidae) to cyromazine, abamectin, and spinosad

Three populations of the leafminer, Liriomyza trifolii (Burgess), were collected from commercial ornamental production greenhouses in the United States and tested for susceptibility to three commercial insecticides. A leaf dip bioassay of leaves containing young (1-2-d-old) larvae was used. Based on larval mortality and compared with a susceptible laboratory reference colony, the three strains varied in spectrum and level of resistance to the insecticides. CA-1, collected from Gerbera daisy, was moderately resistant to cyromazine (18.1-fold) and abamectin (22.0-fold), but highly resistant to spinosad (> 188-fold). CA-2, collected from chrysanthemums, was not resistant to abamectin, had a low level of resistance to cyromazine (8.2-fold), but was extremely resistant to spinosad (1,192-fold). GA-1, collected from chrysanthemums, had very low levels of resistance to cyromazine (5.4-fold) and spinosad (1.9-fold) but was moderately resistant to abamectin (30.6-fold). When reared in the absence of insecticide selection pressure, all three strains reverted to approximately the level of the reference strain. The CA-1 strain reverted in nine generations to cyromazine; however, the lowest levels of abamectin and spinosad resistance reverted to was 3.1-fold at F8 and 3.2 at the F10, respectively. The CA-2 strain reverted in five generations to both cyromazine and spinosad. GA-1 reverted in five generations to abamectin. Based on the results, resistance to these three insecticides was unstable. Additionally, there was no cross-resistance among these three insecticides.     

Monitoring insecticide resistance in Australian Frankliniella occidentalis Pergande (Thysanoptera: Thripidae) detects fipronil and spinosad resistance

Abstract  Insecticide resistance monitoring using a Potter precision spray tower with discriminating concentration and log dose probability techniques underpins the Australian insecticide management strategy for Frankliniella occidentalis Pergande. Abamectin, acephate, chlorpyrifos, dichlorvos, dimethoate, endosulfan, fipronil, malathion, methamidophos methidathion, methiocarb, methomyl, pyrazophos and spinosad are recommended for use against F. occidentalis but abamectin, methiocarb and pyrazophos are the only chemicals where insecticide resistance has not been detected. Although not registered, chlorfenapyr was effective against F. occidentalis and should be pursued for that purpose. In contrast, chlorpyrifos, dichlorvos and malathion resistance were detected at low to moderate levels throughout the study period putting their sustainable use for F. occidentalis control in doubt . Although it appears that acephate, dimethoate, endosulfan, fipronil, methamidophos, methidathion and spinosad remain effective, some populations contained a small percentage of thrips that survived exposure to a concentration that killed 100% of the susceptible strain. Subsequent laboratory selection of one such population separately with fipronil and spinosad caused an increase in resistance to these insecticides. These products must now be considered at risk. This is the first report of fipronil or spinosad resistance in populations of F. occidentalis.     

Thiamethoxam Resistance in the House Fly,Musca domestica L.: Current Status,Resistance Selection,Cross-Resistance Potential and Possible Biochemical Mechanisms

The house fly, Musca domestica L., is an important ectoparasite with the ability to develop resistance to insecticides used for their control. Thiamethoxam, a neonicotinoid, is a relatively new insecticide and effectively used against house flies with a few reports of resistance around the globe. To understand the status of resistance to thiamethoxam, eight adult house fly strains were evaluated under laboratory conditions. In addition, to assess the risks of resistance development, cross-resistance potential and possible biochemical mechanisms, a field strain of house flies was selected with thiamethoxam in the laboratory. The results revealed that the field strains showed varying level of resistance to thiamethoxam with resistance ratios (RR) at LC₅₀ ranged from 7.66-20.13 folds. Continuous selection of the field strain (Thia-SEL) for five generations increased the RR from initial 7.66 fold to 33.59 fold. However, resistance declined significantly when the Thia-SEL strain reared for the next five generations without exposure to thiamethoxam. Compared to the laboratory susceptible reference strain (Lab-susceptible), the Thia-SEL strain showed cross-resistance to imidacloprid. Synergism tests revealed that S,S,S-tributylphosphorotrithioate (DEF) and piperonyl butoxide (PBO) produced synergism of thiamethoxam effects in the Thia-SEL strain (2.94 and 5.00 fold, respectively). In addition, biochemical analyses revealed that the activities of carboxylesterase (CarE) and mixed function oxidase (MFO) in the Thia-SEL strain were significantly higher than the Lab-susceptible strain. It seems that metabolic detoxification by CarE and MFO was a major mechanism for thiamethoxam resistance in the Thia-SEL strain of house flies. The results could be helpful in the future to develop an improved control strategy against house flies.     

Selection for resistance to acetamiprid and various other insecticides in the diamondback moth, Plutella xylostella (L.) (Lep., Plutellidae)

Abstract:  A diamondback moth (DBM) colony (KOBII) originally collected from cabbage fields of Iwaoka-cho in Kobe City, Japan, where acetamiprid is the primary insecticide for DBM control was selected for studies on resistance to acetamiprid, phenthoate, esfenvalerate and cartap, using the leaf-dipping method. Resistance to acetamiprid was slow to develop in KOBII compared with the other insecticides. Three selection experiments each with phenthoate and esfenvalerate yielded a resistance ratio (RR) of 140 and 222, respectively, in the selected strains compared with a part of KOBII that was not exposed to any insecticide (KOBII-NS). Three selection experiments with cartap also gave an RR of 15. However, six selection experiments with acetamiprid yielded an RR of just 9.5 in the selected strain. When cross-resistance to acetamiprid was evaluated, the cartap-resistant strain showed a moderate level of cross-resistance to acetamiprid. In the case of the phenthoate-resistant strain, a very low cross-resistance to acetamiprid was observed. There was however no discernible cross-resistance to acetamiprid in the esfenvalerate-resistant strain.     

Use of sperm precedence to infer the overwintering cost of insecticide resistance in the Colorado potato beetle

1 Resistance to insecticides is a model system for studying adaptation. Although selection for resistance is always strong in areas and seasons where populations are exposed to insecticides, costs of resistance, which may only be expressed in the absence of insecticide use, will shape how quickly resistance will evolve.
2 We used sperm precedence to measure the shifts in resistance to imidacloprid in a natural population during winter diapause in the Colorado potato beetle, Leptinotarsa decemlineata (Say) (Coleoptera: Chrysomelidae). Because adult beetles overwinter with viable autumn sperm, but sperm from spring matings take precedence over stored sperm, we used the difference in resistance of springmated and autumn-mated overwintered females to estimate the shift in resistance during the winter. Offspring of autumn-mated females were 2.7- or 2.5-fold more resistant compared with offspring from spring-mated females in two replicate trials.
3 We also measured the resistance of late summer and spring emergent adults in fields treated and untreated with imidacloprid in the first year. Adults from the treated field were 13.7-fold more resistant and adults from the untreated field were 2.6-fold more resistant compared with the next spring's emergers.
4 These large costs of resistance observed in the field and inferred from resistance declines during diapause help to explain the observation that imidacloprid resistance has increased only slowly over the decade of widespread use against this species, and how insecticide resistance in general can cycle annually.     

Pleiotropy of insecticide resistance in the codling moth, Cydia pomonella

The codling moth, Cydia pomonella (L.) (Lepidoptera: Tortricidae), has developed resistance to various insecticides. Relative fitness of one susceptible strain (Sv) and two strains selected for resistance to diflubenzuron (Rt) and deltamethrin (Rv), respectively, was measured in the absence of insecticide selection pressure. Mating rate, fecundity, fertility, developmental time, fifth instar weight, and adult longevity were compared. Both resistant strains were less fecund and fertile, developed more slowly, weighed less, and had shorter life-spans than the susceptible strain. These results indicate that biological constraints are associated with insecticide resistance in the codling moth. We also found that fitness estimates of the Rv strain did not differ statistically from those of the Rt strain. Enhanced mixed-function oxidase and glutathione-S-transferase activities have been shown to be involved in insecticide resistance in both Rt and Rv strains. This suggests that the fitness cost described in both resistant strains was mainly associated to metabolic resistance. The impact of such deleterious pleiotropy of insecticide resistance in C. pomonella in terms of resistance management in the field is discussed.     

二点叶螨对甲氰菊酯、氧乐果和四螨嗪抗药性的选育、衰退和恢复

以兰州吐鲁沟公园的二点叶螨Tetranychusurticae为敏感品系 ,分别用氧乐果、甲氰菊酯、四螨嗪喷雾处理 15次 ,其抗性水平分别为 38 5、 479 8和 6 7 3倍。将抗性品系分别与敏感品系进行杂交和回交的结果表明 :抗氧乐果品系的显性系数DRS (R♀×S♂ )为 0 470 0、DSR (S♀×R♂ )为 0 4749;抗甲氰菊酯品系的DRS (R♀×S♂ )为 0 5 15 5 ,DSR 为0 5 2 37;抗四螨嗪品系的DRS为 0 3134 ,DSR 为 0 2 46 6。表明二点叶螨对这 3种药剂的抗性均是由单个不完全显性基因所控制。在连续 10个月不接触药剂的情况下 ,3个抗性品系的抗药性都有下降 ,抗氧乐果品系的抗性下降最快 ,只有敏感品系的抗性倍数的 3 6倍 ;抗甲氰菊酯种群的抗性下降较慢 ,为敏感品系的 95 9倍。再经甲氰菊酯、氧乐果、四螨嗪分别连续15次喷雾处理后 ,3个抗性种群的抗性水平又再度回升 ,抗甲氰菊酯品系回升较快 ,抗性为敏感品系的 5 2 3 5倍 ,抗四螨嗪品系次之 ,抗氧乐果的品系抗性恢复最慢。     

Resistance irrelevant CYP417A2v2 was found degrading insecticide in Laodelphax striatellus

Cytochrome P450 monooxygenases (CYP s) usually overexpressed in resistant strain were found involved in oxidative detoxification of insecticides. In this study, an investigation was conducted to confirm if resistance irrelevant CYP s which were not overexpressed in resistant strain before, were capable of degrading insecticides. Three resistance irrelevant CYP s viz. CYP 417A2v2, CYP 425A1v2, and CYP 4DJ 1 from CYP 4 family of Laodelphax striatellus were randomly selected for experiments. CYP 417A2v2 and CYP 425A1v2 were found expressed successfully in Sf9 cell line while CYP 4DJ 1 was not expressed successfully and out of two expressed CYP s, only CYP 417A2v2 showed its efficient catalytic activity. For catalytic activity, three traditional model probe substrates and five insecticides were assayed. For the probe substrates screened, p‐nitroanisole and ethoxycoumarin were preferentially metabolized by CYP 417A2v2 (specific activity 3.76 ± 1.22 and 1.63 ± 0.37 nmol min^?1 mg protein^?1, respectively) and they may be potential diagnostic probes for this enzyme. Among insecticides, only imidacloprid was efficiently degraded by CYP 417A2v2. Incubation of imidacloprid with CYP 417A2v2 of L. striatellus and subsequent HPLC , LC ‐MS , and MS /MS analysis revealed the formation of imidacloprid metabolites, that is, 4′ or 5′hydroxy‐imidacloprid by hydroxylation. This result implies the exemption of CYP s character that it is not always, all the CYP s degrading insecticides being selected and overexpressed in resistant strains and the degrading CYP s without mutations to upregulate could be candidates during insecticide resistance evolution. This characterization of individual insect CYP s in insecticide degradation can provide insight for better understand of insecticide resistance development.     

Bidirectional selection for body mass and correlated response of pyrethroid resistance and fitness in Sitophilus zeamais

Responses to artificial selection on body mass in the maize weevil Sitophilus zeamais (Coleoptera: Curculionidae) were investigated to determine whether changes in body mass are associated with insecticide susceptibility, rate of population growth, and metabolic rate. Two strains of the maize weevil differing in susceptibility to pyrethroid insecticides were subjected to bidirectional selection on body mass. The susceptible strain responded to selection resulting in individuals with lower or higher body mass, but the resistant strain responded significantly only to selection for lower body mass. The resistant strain selected for low body mass increased its level of deltamethrin resistance in 44 × . In contrast, selection for low body mass in the susceptible parental strain led to increased deltamethrin susceptibility (50 × ) and selection for high body mass increased deltamethrin resistance (4 × ). Thus, the correlated response of insecticide resistance to selection for body mass differed between strains, a likely consequence of their distinct genetic background. Regardless, body mass was positively correlated with fitness (reproductive output) (r = 0.79; P < 0.001), while such correlation with respiration rate was significant only at P = 0.07 (r = 0.44). Therefore, the association between body mass and deltamethrin resistance is population‐dependent in the maize weevil, and the confluence of deltamethrin resistance and high body mass in a given strain will likely favour its energy metabolism and lead to the mitigation of fitness costs usually associated with insecticide resistance. The genetic background and selection history of insecticide resistant populations should not be neglected since they may favour the confluence of insecticide resistance with mitigation mechanisms of its associated fitness costs limiting the tactics available to their management.     

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。     

抗溴氰菊酯家蝇在不同用药方式下的敏感性变化及其机制

以具有极高抗水平的抗溴氰菊酯家蝇Musca domestica vicina Macquart DR0品系为试虫,模拟田间几种常见的用药方式(混用、轮用、使用增效剂),在室内进行平行汰选,并以不用药和继续用原药汰选的为比较,研究试虫在这几种用药方式下的敏感性变化及其变化机制。抗性家蝇用辛溴混剂、辛硫磷以及溴氰菊酯＋SV₁汰选后,在F₁₆(F₁₇)代以前,对溴氰菊酯及汰选药剂的抗性发展相对都比较缓慢;F₁₆(F₁₇)代以后,用溴氰菊酯＋SV₁汰选的家蝇对溴氰菊酯的敏感性迅速下降,抗性发展很快。家蝇对溴氰菊酯的敏感性变化与药剂中溴氰菊酯的选择压有关。生化分析结果表明,在不同用药方式汰选下,家蝇体内酯酶、多功能氧化酶、谷胱甘肽-S-转移酶、乙酰胆碱酯酶的酶活或特性发生了不同的变化。     

二点叶螨对甲氰菊酯、氧乐果和四螨嗪抗药性的选育、衰退和恢复

以兰州吐鲁沟公园的二点叶螨Tetranychus urticae 为敏感品系,分别用氧乐果、甲氰菊酯、四螨嗪喷雾处理15次,其抗性水平分别为38.5、479.8和67.3倍。将抗性品系分别与敏感品系进行杂交和回交的结果表明：抗氧乐果品系的显性系数DRS（R♀×S♂）为0.4700、D_SR（S♀×R♂）为0.4749;抗甲氰菊酯品系的DRS（R♀×S♂）为0.5155, DSR为0.5237;抗四螨嗪品系的DRS为0.3134, DSR为0.2466。表明二点叶螨对这3种药剂的抗性均是由单个不完全显性基因所控制。在连续10个月不接触药剂的情况下,3个抗性品系的抗药性都有下降,抗氧乐果品系的抗性下降最快,只有敏感品系的抗性倍数的3.6倍;抗甲氰菊酯种群的抗性下降较慢,为敏感品系的95.9倍。再经甲氰菊酯、氧乐果、四螨嗪分别连续15次喷雾处理后,3个抗性种群的抗性水平又再度回升,抗甲氰菊酯品系回升较快,抗性为敏感品系的523.5倍,抗四螨嗪品系次之,抗氧乐果的品系抗性恢复最慢。     

取食不同寄主植物对棉蚜后代抗药性的影响

测定了5种药剂对棉蚜Aphis gossypii抗氰戊菊酯、吡虫啉品系和敏感品系取食棉花、黄瓜和石榴的后代的毒力,并对它们的后代体内乙酰胆碱酯酶和羧酸酯酶的比活力做了初步探索。结果表明,氰戊菊酯抗性品系取食棉花比取食黄瓜的后代对氰戊菊酯的抗性大76.4倍,对灭多威、氧乐果、硫丹和吡虫啉的抗性也大0.5～4.6倍;取食石榴的后代对5种药剂的抗性介于取食棉花和黄瓜的之间。吡虫啉抗性品系的测定结果与氰戊菊酯抗性品系基本一致。敏感品系取食黄瓜比取食棉花的后代对5种药剂的敏感性更高。3个品系取食不同植物的后代相比,其体内乙酰胆碱酯酶的比活力,取食棉花的为取食黄瓜的2.4～2.8倍;羧酸酯酶的比活力,取食棉花的为取食黄瓜的1.8～2.4倍。证明棉蚜的抗性和敏感品系取食的寄主植物不同,可引起对药剂敏感性的变化。乙酰胆碱酯酶和羧酸酯酶活力的变化均是引起这种变化的重要因素。     

Cyromazine resistance in the house fly (Diptera: Muscidae): genetics and cross-resistance to diflubenzuron

Larvae of a house fly, Musca domestica L., strain collected in a chicken house near Pittsburg, Tex, after a control failure with the poultry feedthrough insecticide cyromazine showed 6.5-fold resistance to cyromazine and 10-fold resistance to diflubenzuron. Adults of the strain showed high levels of resistance to carbaryl, DDT, and diazinon; moderate resistance to cypermethrin and permethrin; and low resistance to dieldrin. In contrast, no resistance to cyromazine was observed in eight laboratory house fly strains with resistance to four groups of conventional insecticides. When the genetics of cyromazine resistance was investigated in crosses to susceptible strains with visible mutant markers, results indicated cyromazine resistance was incompletely dominant over susceptibility and the resistance gene was on chromosome V. The same or a closely linked gene conferred resistance to diflubenzuron. A strain containing only chromosome V from the original resistant strain was resistant to cyromazine and diflubenzuron, but not to other insecticides except for low level resistance to DDT and carbaryl. Resistance to the latter insecticides appeared to be due to a linked, but distinct, gene. Therefore, resistance to cyromazine and probably diflubenzuron appears to be genetically distinct from other types of insecticide resistance.     

Susceptibility and detoxifying enzyme activity in two spider mite species (Acari: Tetranychidae) after selection with three insecticides

Changes in the susceptibility and detoxifying enzyme activity were measured in laboratory strains of Banks grass mite, Oligonychus pratensis (Banks), and twospotted spider mite, Tetranychus urticae Koch, that were repeatedly exposed to three insecticides. Three strains of each mite species were exposed to one of two pyrethroids, bifenthrin, and lambda-cyhalothrin, or an organophosphate, dimethoate, for 10 selection cycles at the LC60 for each insecticide. A reference or nonselected strain of each mite species was not exposed to insecticides. After 10 cycles of exposure, susceptibility to the corresponding insecticides, bifenthrin, lambda-cyhalothrin, and dimethoate, decreased 4.5-, 5.9-, and 289.2-fold, respectively, relative to the reference strain in the respective O. pratensis strains, and 14.8-, 5.7-, and 104.7-fold, respectively, relative to the reference strain in the respective T. urticae strains. In the bifenthrin-exposed O. pratensis strain, there was a 88.9-fold cross-resistance to dimethoate. In the dimethoate-exposed T. urticae strain, there was a 15.9-fold cross-resistance to bifenthrin. These results suggest that there may be cross-resistance between dimethoate and bifenthrin. The reduced susceptibility to dimethoate remained stable for three months in the absence of selection pressure in both mites. The decrease in susceptibility in the O. pratensis strains exposed to bifenthrin, lambda-cyhalothrin, and dimethoate was associated with a 4.7-, 3.0-, and 3.6-fold increase in general esterase activity, respectively. The decrease in susceptibility in the T. urticae strains exposed to bifenthrin and lambda-cyhalothrin was associated with a 1.3- and 1.1-fold increase in general esterase activity, respectively. The mean general esterase activity was significantly higher in the pyrethroid-exposed O. pratensis and T. urticae strains than in the nonselected strain. There was no significant increase in esterase activity in the dimethoate-exposed T. urticae strain. The decrease in susceptibility to insecticides was also associated with reduced glutathione S-transferase 1-chloro-2, 4-dinitrobenzene conjugation activity, but this did not appear to be related to changes in insecticide susceptibility. These results suggest that in these mites, the general esterases may play a role in conferring resistance to pyrethroids. However, some other untested mechanism, such as target site insensitivity, must be involved in conferring dimethoate resistance.     

寄主抗药性对菜蛾绒茧蜂生物学特性的影响

以小菜蛾Plutella xylostella敏感品系SP作寄主饲育的菜蛾绒茧蜂Cotesia plutellae SC品系分别寄生于小菜蛾的SP品系(SC-SP组合)或抗性RP品系(SC-RP组合),还以小菜蛾RP品系作寄主饲育的菜蛾绒茧蜂RC品系分别寄生于小菜蛾的SP品系(RC-SP组合)或RP品系(RC-RP组合),均在幼虫中期施用氰戊菊酯,考察了药剂对该蜂生物学特性的影响。结果发现：在不施用杀虫剂时,SC-RP组合中蜂的结茧率为45.8%,显著低于其它组合, 所结茧长0.76 mm,育出雌蜂前翅和后足胫节长分别为3.28 mm和2.33 mm,也分别小于其它各组合的结果,表明寄主抗药性对该蜂有不利影响;施用杀虫剂后,RC-RP、SC-RP组合中,蜂的结茧率分别为95.5%和37.8%,显著高于SC-SP和RC-SP组合中蜂的结茧率（22.5%,25.8%）,表明寄主抗性能保护其体内的幼蜂少受杀虫剂的影响;RC-SP组合在受到和未受到杀虫剂作用时茧的羽化率分别为95.2%和93.6%,无显著差异,卵+幼虫及雌蛹的发育历期在处理和对照间也无显著差异,表明用抗性寄主饲育的菜蛾绒茧蜂在寄生敏感寄主时仍表现一定的耐药性,有利于该蜂抗药性的发展,即寄主 寄生蜂之间在抗药性方面存在协同进化。     

Reduction of sooty mold damage through biocontrol of the greenhouse whitefly <Emphasis Type="Italic">Trialeurodes vaporariorum</Emphasis> (Hemiptera: Aleyrodidae) using selective insecticides in tomato cultivation greenhouses

The proliferation of sooty mold on tomato fruit, Solanum lycopersicum L.—as caused by the secretion of honeydew on the fruit by greenhouse whitefly, Trialeurodes vaporariorum (Westwood) (Hemiptera: Aleyrodidae)—has recently become a serious problem in estivo-autumnal greenhouse tomato cultivation in Japan. It is becoming increasingly difficult to control T. vaporariorum using insecticides because whiteflies have developed resistance to a variety of insecticides. As the first step towards integrated pest management, we examined whether the use of selective insecticides could prompt a cascade process in which an increase in parasitoids is followed by a decrease in whitefly occurrence and then a reduction in sooty mold damage. We compared greenhouses in which nonselective insecticides effective against T. vaporariorum and its parasitoids were used (hereafter denoted “nonselective insecticide greenhouses”) with greenhouses in which selective insecticides for T. vaporariorum were used (hereafter denoted “selective insecticide greenhouses”) in terms of the density and level of parasitism of T. vaporariorum as well as the degree of damage from sooty mold. The number of parasitized whiteflies increased with the number of whiteflies in the selective insecticide greenhouses, whereas it remained at low levels regardless of the number of whiteflies in the nonselective insecticide greenhouses. Furthermore, the selective insecticide greenhouses showed significantly higher parasitism levels, fewer whiteflies, and reduced sooty mold damage compared to the nonselective insecticide greenhouses. These results suggest that the use of selective insecticides causes an increase in parasitism, which in turn suppresses the number of greenhouse whiteflies and, eventually, sooty mold.