棉蚜啶虫脒抗性种群交互抗性和增效剂增效作用的研究

【目的】明确棉蚜Aphis gossypii Glover啶虫脒抗性品系与其它杀虫剂的交互抗性现状以及增效剂的增效作用,为延缓和治理棉蚜对啶虫脒的抗性提供依据。【方法】采用单头反选育和群体汰选的方式,获得了棉蚜啶虫脒敏感和抗性品系;采用叶片药膜法测定了13种杀虫剂对啶虫脒的交互抗性以及增效剂对啶虫脒的增效作用。【结果】经过室内棉蚜敏感和抗性品系的筛选,获得了相对抗性倍数为82.33倍的棉蚜啶虫脒抗性品系。棉蚜啶虫脒抗性品系的交互抗性谱的研究表明,交互抗性倍数小于5的药剂为:吡蚜酮,甲基阿维菌素;交互抗性倍数在5~10倍的药剂为:噻虫嗪,联苯菊酯,毒死蜱,马拉硫磷,丙溴磷,辛硫磷;交互抗性倍数在10~15倍的药剂为:硫丹,阿维菌素,高效氯氰菊酯,三唑磷,氧化乐果;交互抗性倍数大于1 5倍的药剂为:吡虫啉。增效剂实验表明,TPP和PBO在啶虫脒敏感品系中增效作用不明显,但在抗性品系中增效作用显著。在啶虫脒抗性品系中的增效比为1.77、1.61,在啶虫脒敏感品系中的增效比为1.02、1.03。DEM在啶虫脒抗性、敏感品系中的增效作用均不明显,增效比为1.04、1.02。TPP和PBO对啶虫脒有很好的增效作用。以室内棉蚜敏感品系(LC_(50)为0.180 mg/L)为基础,对新疆各主要棉区的棉蚜种群进行了啶虫脒药剂的抗性调查,结果表明新疆各主要棉区棉蚜对啶虫脒的相对抗性倍数为6.1~22.0倍。【结论】由此说明新疆主要棉区棉蚜对啶虫脒具有一定的抗性风险,生产中可以利用无交互抗性的吡蚜酮和甲基阿维菌素来治理抗性棉蚜种群。     

柑橘全爪螨两个田间种群抗性监测及羧酸酯酶生化特性研究

采用叶碟浸渍法测定了重庆北碚和万州地区柑橘全爪螨Panonychus citri(McGregor)田间种群对阿维菌素、毒死蜱、甲氰菊酯和哒螨灵的抗性水平。结果表明,同室内敏感品系相比,北碚种群对毒死蜱、甲氰菊酯和哒螨灵的相对抗性水平分别达到3倍、3倍和22倍;万州种群对阿维菌素、毒死蜱、甲氰菊酯和哒螨灵的相对抗性水平分别达到2倍、35倍、10倍和2倍。柑橘全爪螨2个地理种群的羧酸酯酶CarE的生化特性研究发现,CarE酶活的增高和毒死蜱的抗性存在一定的相关性。毒死蜱对不同地理种群柑橘全爪螨CarE的抑制效果不同,对抗性倍数较高的万州种群抑制效果最差。     

棉蚜对吡虫啉的抗性选育和现实遗传力分析

【目的】为了评估棉蚜Aphis gossypii Glover对吡虫啉的抗性风险,在室内进行了棉蚜对吡虫啉(imidacloprid)的抗性选育和抗性现实遗传力分析。【方法】采用单头反选育法和群体汰选法,分别得到了棉蚜对吡虫啉敏感品系(LC₅₀为0.176 mg/L)和抗性品系(LC₅₀为14.657 mg/L)。采用阈性状分析方法,获得棉蚜对吡虫啉的抗性现实遗传力（h²）。【结果】相对于田间原始种群(LC₅₀为0.346 mg/L),吡虫啉敏感棉蚜品系对吡虫啉的LC50减少了2倍;获得的吡虫啉抗性棉蚜品系,经过40代的选育,得到抗性倍数为室内敏感品系的83.27倍的抗性品系。棉蚜对吡虫啉的抗性现实遗传力(h2)为0.1478。进一步预测其抗性发展速度,基于80%~90%的选择压力,预计抗性增长100倍时,吡虫啉可使用30.2~38.1代。【结论】这些研究说明棉蚜对吡虫啉存在抗性风险。     

巴氏新小绥螨甲氰菊酯抗性品系生物学特性及其对常用药剂的交互抗性

【目的】明确橘园常用药剂对巴氏新小绥螨Neoseiulus barkeri成螨的致死效应,弄清巴氏新小绥螨甲氰菊酯抗性品系对柑橘园常用药剂的交互抗性水平及生态适合度变化,为巴氏新小绥螨抗性品系的田间应用提供科学理论依据。【方法】在对巴氏新小绥螨进行致死效应和交互抗性测定的基础上,运用生态学方法对其生物学特性进行评价。【结果】不同药剂对巴氏新小绥螨成螨致死效应存在显著差异。高效氯氟氰菊酯和毒死蜱的致死率最高,校正死亡率分别为97.62%和92.57%;巴氏新小绥螨甲氰菊酯抗性品系螺螨酯、噻虫嗪、乙螨唑、毒死蜱和高效氯氟氰菊酯均存在显著交互抗性,其抗性倍数分别为7.56、10.32、11.45、19.10和45.89倍。生物学特性研究结果表明,与敏感品系相比,甲氰菊酯抗性的获得使其发育历期显著延长,但对捕食量和孵化率影响不显著。哒螨灵、丁氟螨酯和高效氯氟氰菊酯对巴氏新小绥螨抗性品系与敏感品系卵的孵化率具有显著影响,其他常用药剂对巴氏新小绥螨抗性品系与敏感品系卵的孵化率不存在显著影响。【结论】甲氰菊酯抗性获得使巴氏新小绥螨对柑橘园常用药剂表现不同水平的交互抗性;甲氰菊酯抗性获得对巴氏新小绥螨生长、繁殖及捕食均无显著影响,可在田间推广应用。     

山楂叶螨对螺螨酯的抗药性及对七种杀螨剂的交互抗性

【目的】筛选山楂叶螨Amphitetranychus viennensis Zacher对螺螨酯的抗药性,并明确其对7种杀螨剂的交互抗性。【方法】采用室内生物测定的方法,研究山楂叶螨对螺螨酯的抗性发展趋势及其交互抗性。【结果】用螺螨酯筛选山楂叶螨21代,抗性上升11.65倍;抗性品系对乙螨唑存在明显的交互抗性,抗性倍数为6.30;对噻螨酮存在负交互抗性,抗性倍数为0.69;对阿维菌素、炔螨特和三唑锡不存在交互抗性,抗性倍数分别为1.15、1.25、1.78;对哒螨灵和联苯肼酯有产生交互抗性的可能,抗性倍数分别为3.46和2.79。【结论】螺螨酯防治山楂叶螨存在抗性风险,抗螺螨酯的山楂叶螨品系会产生交互抗性,上述结果可为果园科学使用螺螨酯和合理轮换用药提供理论依据。     

西花蓟马对多杀菌素的抗性生化机制研究

在室内持续用多杀菌素对西花蓟马Frankliniella occidentalis(Pergande)进行抗性汰选,获得抗性倍数达到11 999倍的极高抗品系。该抗性品系对乙基多杀菌素和噻虫嗪具有显著的交互抗性,抗性倍数分别为53 718和84倍,对阿维菌素和毒死蜱的敏感性也有显著下降,交互抗性倍数分别为3.33和2.28倍,对虫螨腈无明显交互抗性。生化测定结果表明,抗性品系的羧酸酯酶、谷胱甘肽S-转移酶和多功能氧化酶的活力与敏感品系均无显著差异,推测抗性可能与靶标位点的敏感性降低有关。     

尼氏钝绥螨抗亚胺硫磷品系的筛选及遗传分析

尼氏钝绥螨Amblyseius nicholsi Ehara et Lee是桔全爪螨Panonychus citri(McGregor)的有效天敌之一.为了筛选抗有机磷农药品系, 经实验室内用亚胺硫磷33次处理后, 抗性提高18.9倍, LC₅₀从最初的52.5ppm提高到995ppm, 为大田常用浓度的两倍.S(敏感型)与R(抗性型)的LD-P线近于平行, 表明两者已成为纯系.正交与反交之F₁代雌性个体的LD—P线介于S与R之间略偏向R方, F₁显性度(D)大于0而小于1, 说明抗性为半显性.F₁(杂合子)与敏感亲本的回交结果, 其LD—P线在50%.死亡率处出现一平坡, SR(杂合子)与SS(敏感个体)的分配比例接近于1:1的理论值.以上结果说明尼氏钝绥螨对亚胺硫磷的抗性为半显性的单基因所控制.正、反交F₁代雄性个体的抗性检测结果表明, F₁代的雄性个体具有其遗传性来自母系的特征.尼氏钝绥螨抗亚胺硫磷品系对辛硫磷、水胺硫磷、乐果、敌敌畏、敌百虫等有机磷农药具有一定的交互抗性, 抗性分别提高28.5、8.5、5.4、3.8和2.9倍.     

二斑叶螨不同抗性品系最佳内参基因的筛选及CYP392E亚家族基因的表达分析

【目的】 筛选二斑叶螨Tetranychus urticae敏感品系（SS）、 抗阿维菌素品系(Av-R)和抗螺虫乙酯品系（Sp-R）中合适的内参基因, 研究二斑叶螨不同抗性品系CYP392E亚家族基因表达水平的变化。【方法】采用实时荧光定量PCR （quantitative real time PCR, qRT-PCR）技术, 对二斑叶螨α-tubulin, β-actin, ELFn, GAPDH, 5.8S rRNA基因和SDHA共6个看家基因的表达稳定性进行分析以期筛选出合适的内参基因, 并在此基础上进一步分析二斑叶螨不同品系P450酶系CYP392E亚家族基因的表达量差异。【结果】在二斑叶螨SS, Av-R和Sp-R品系中稳定性最高的内参基因为ELFn。以ELFn为内参基因, CYP392E7基因相对表达量在二斑叶螨Av-R品系中显著高于SS品系(P<0.05), 为后者的2.18倍, 而在Sp-R品系和SS品系中差异不显著; 其余基因的相对表达量在2个抗性品系中均没有增加, Av-R品系的CYP392E4, CYP392E9和CYP392E10基因以及Sp-R品系的CYP392E1和CYP392E9基因相对表达量甚至显著下调, 分别为SS品系的48%, 74%, 65%, 63%和73%。【结论】在二斑叶螨SS, Av-R和Sp-R品系中ELFn为理想的内参基因, Av-R品系CYP392E4, CYP392E7, CYP392E9和CYP392E10基因相对表达量的显著变化可能与二斑叶螨对阿维菌素的抗性形成有关, Sp-R品系CYP392E1和CYP392E9基因也可能与二斑叶螨对螺虫乙酯的抗性形成有一定联系。     

二斑叶螨多重抗性品系最优内参基因的筛选及CYP392A亚家族基因的表达分析

【目的】筛选出二斑叶螨Tetranychus urticae Koch抗甲氰菊酯、阿维菌素及螺螨酯混剂的实时定量PCR最优内参基因。【方法】选取5.8S rRNA, α-tubulin, TBP, β-actin, ELFn, RPL13a, GAPDH和SDHA 8个候选内参基因,以GeNorm, BestKeeper和Normfinder 3个软件分析这8个基因在二斑叶螨多重抗性品系中的表达稳定性, 并以筛选的内参基因分析二斑叶螨P450酶系CYP392A亚家族基因的表达水平。【结果】经GeNorm, BestKeeper和Normfinder 3个软件综合评价确定ELFn基因为二斑叶螨敏感品系(susceptible strain, SS)和多重抗性品系(multi-pesticide resistant strain, Mp-R)各发育阶段的最优内参基因。以ELFn为内参基因对二斑叶螨CYP392A亚家族16个基因表达量进行分析,结果表明：经多重抗性选育40代后,Mp-R品系卵期CYP392A1表达量显著上调;CYP392A16基因在各发育阶段表达量极显著高于SS品系相应发育阶段;其他基因表达量在敏感品系和抗性品系之间差异不显著。【结论】筛选出了SS和Mp R品系中各发育阶段最佳内参基因为EFLn;Mp-R品系CYP392A亚家族16个基因的表达量在幼螨和若螨阶段低于卵与成螨阶段,其中CYP392A16基因在二斑叶螨多重抗性的形成中起主要作用。该结果为二斑叶螨多重抗性研究奠定了一定基础。     

棉铃虫对氰戊菊酯抗性和敏感品系的选育

用氰戊菊酯对来自阳谷的棉铃虫(YG)Heliothis armigera(Hubncr) 进行抗性晶系的筛选。在15代期间经过9代的室内选育,获得抗性品系(Fcn-R),抗性倍数高达2“3倍,筛选后F₁₅代LD₅₀值(24.1412μg/头)比筛选前F1代lD₅₀值(0.2020μg/头)提高了119.5倍。对来自偃师的棉铃虫(YS)进行了连续两代单对筛选,得到敏感品系(Fen-S),敏感晶系的LD50值为0.0116μg/头,接近1983年东台敏感晶系的LD₅₀值(0.0098μg/头)Fcn-R抗性晶系筛选前后分别测定了七种杀虫剂的剂量-死亡回归线,发现Fen-R抗性品系对溴氰菊酯[LD₅₀(Fen-R)/LD₅₀(YG)=5.2X] 和氯氰菊酯(2.5X)具有一定程度的交互抗性;而对功夫菊酯(0.66X),氯菊酯(0.89x)、灭多威(0.74X)及久效磷(1.5x)没有交互抗性。氰戊菊酯加Pb的增效试验结果表明棉铃虫对氰戊菊酯的抗性主要是由于多功能氧化酶的代谢作用。毒理学资料还暗示抗性为多因子(基因)的。     

Molecular mechanisms conferring asymmetrical cross-resistance between tebufenozide and abamectin in Plutella xylostella

Based on the confirmation of asymmetrical cross-resistance between abamectin and tebufenozide in Plutella xylostella, the present work proved that the cytochrome P450 monooxygenase plays a decisive role in cross-resistance, and the expression of various cytochrome P450 (CYP450) genes in different strains was surveyed to elucidate the molecular basis of the underlying mechanisms. Enzyme analysis showed the activity of cytochrome P450 monooxygenase was notable enhanced in the strains resistant to both tebufenozide (3.07-fold) and abamectin (3.37-fold), suggesting that the enhancement of cytochrome P450 monooxygenase is the main detoxification mechanism responsible for the cross-resistance. CYP4M7 (64.58-fold) and CYP6K1 (41.97-fold) had extremely high expression levels in the Teb-R strain, selected using tebufenozide, which was highly resistant to tebufenozide (RR 185.5) and moderately cross-resistant to abamectin (RR 41.0). When this strain was subjected to further selection using abamectin, the resultant Aba-R strain showed a higher expression of CYP6K1 (60.32-fold). However, the expression of CYP4M7 was reduced (10.62-fold). Correspondingly, the Aba-R strain became more resistant to abamectin (RR 593.8) and less resistant to tebufenozide (RR 28.0). Therefore, we concluded that the over expression of CYP4M7 was the main cause for tebufenozide resistance, and that CYP6K1 mainly conferred abamectin resistance. The asymmetrical cross-resistance occurred because tebufenozide selection not only enhanced the expression of CYP4M7, but also that of CYP6K1. This is the first report on the molecular mechanism of asymmetrical cross-resistance between insecticides.     

Cross-resistance of bisultap resistant strain of Nilaparvata lugens and its biochemical mechanism

The resistant (R) strain of the planthopper Nilaparvata lugens (St?l) selected for bisultap resistance displayed 7.7-fold resistance to bisultap and also had cross-resistance to nereistoxin (monosultap, thiocyclam, and cartap), chlorpyrifos, dimethoate, and malathion but no cross-resistance to buprofezin, imidacloprid, and fipronil. To find out the biochemical mechanism of resistance to bisultap, biochemical assay was done. The results showed that cytochrome P450 monooxygenases (P450) activity in R strain was 2.71-fold that in susceptible strain (S strain), in which the changed activity for general esterase (EST) was 1.91 and for glutathione S-transferases only 1.32. Piperonyl butoxide (PBO) could significantly inhibit P450 activity (percentage of inhibition [PI]: 37.31%) in the R strain, with ESTs PI = 16.04% by triphenyl phosphate (TPP). The results also demonstrated that diethyl maleate had no synergism with bisultap. However, PBO displayed significant synergism in three different strains, and the synergism increased with resistance (S strain 1.42, Lab strain, 2.24 and R strain, 3.23). TPP also showed synergism for three strains, especially in R strain (synergistic ratio = 2.47). An in vitro biochemical study and in vivo synergistic study indicated that P450 might be play important role in the biochemical mechanism of bisultap resistance and that esterase might be the important factor of bisultap resistance. Acetylcholinesterase (AChE) insensitivity play important role in bisultap resistance. We suggest that buprofezin, imidacloprid, and fipronil could be used in resistance management programs for N. lugens via alternation and rotation with bisultap.     

Multiple Cytochrome P450 genes: their constitutive overexpression and permethrin induction in insecticide resistant mosquitoes, Culex quinquefasciatus

Four cytochrome P450 cDNAs, CYP6AA7, CYP9J40, CYP9J34, and CYP9M10, were isolated from mosquitoes, Culex quinquefasciatus. The P450 gene expression and induction by permethrin were compared for three different mosquito populations bearing different resistance phenotypes, ranging from susceptible (S-Lab), through intermediate (HAmCq(G0), the field parental population) to highly resistant (HAmCq(G8), the 8(th) generation of permethrin selected offspring of HAmCq(G0)). A strong correlation was found for P450 gene expression with the levels of resistance and following permethrin selection at the larval stage of mosquitoes, with the highest expression levels identified in HAmCq(G8), suggesting the importance of CYP6AA7, CYP9J40, CYP9J34, and CYP9M10 in the permethrin resistance of larva mosquitoes. Only CYP6AA7 showed a significant overexpression in HAmCq(G8) adult mosquitoes. Other P450 genes had similar expression levels among the mosquito populations tested, suggesting different P450 genes may be involved in the response to insecticide pressure in different developmental stages. The expression of CYP6AA7, CYP9J34, and CYP9M10 was further induced by permethrin in resistant mosquitoes. Taken together, these results indicate that multiple P450 genes are up-regulated in insecticide resistant mosquitoes through both constitutive overexpression and induction mechanisms, thus increasing the overall expression levels of P450 genes.     

Microarray analysis of cytochrome P450 mediated insecticide resistance in Drosophila

Insecticide resistance in laboratory selected Drosophila strains has been associated with upregulation of a range of different cytochrome P450s, however in recent field isolates of D. melanogaster resistance to DDT and other compounds is conferred by one P450 gene, Cyp6g1. Using microarray analysis of all Drosophila P450 genes, here we show that different P450 genes such as Cyp12d1 and Cyp6a8 can also be selected using DDT in the laboratory. We also show, however, that a homolog of Cyp6g1 is over-expressed in a field resistant strain of D. simulans. In order to determine why Cyp6g1 is so widely selected in the field we examine the pattern of cross-resistance of both resistant strains and transgenic flies over-expressing Cyp6g1 alone. We show that all three DDT selected P450s can confer resistance to the neonicotinoid imidacloprid but that Cyp6a8 confers no cross-resistance to malathion. Transgenic flies over-expressing Cyp6g1 also show cross-resistance to other neonicotinoids such as acetamiprid and nitenpyram. We suggest that the broad level of cross-resistance shown by Cyp6g1 may have facilitated its selection as a resistance gene in natural Drosophila populations.     

Cytochrome P450 monooxygenases and insecticide resistance in insects

Cytochrome P450 monooxygenases are involved in many cases of resistance of insects to insecticides. Resistance has long been associated with an increase in monooxygenase activities and with an increase in cytochrome P450 content. However, this increase does not always account for all of the resistance. In Drosophila melanogaster, we have shown that the overproduction of cytochrome P450 can be lost by the fly without a corresponding complete loss of resistance. These results prompted the sequencing of a cytochrome P450 candidate for resistance in resistant and susceptible flies. Several mutations leading to amino-acid substitutions have been detected in the P450 gene CYP6A2 of a resistant strain. The location of these mutations in a model of the 3D structure of the CYP6A2 protein suggested that some of them may be important for enzyme activity of this molecule. This has been verified by heterologous expression of wild-type and mutated cDNA in Escherichia coli. When other resistance mechanisms are considered, relatively few genetic mutations are involved in insecticide resistance, and this has led to an optimistic view of the management of resistance. Our observations compel us to survey in more detail the genetic diversity of cytochrome P450 genes and alleles involved in resistance.     

Metabolic imidacloprid resistance in the brown planthopper,Nilaparvata lugens,relies on multiple P450 enzymes

Target insensitivity contributing to imidacloprid resistance in Nilaparvata lugens has been reported to occur either through point mutations or quantitative change in nicotinic acetylcholine receptors (nAChRs). However, the metabolic resistance, especially the enhanced detoxification by P450 enzymes, is the major mechanism in fields. From one field-originated N. lugens population, an imidacloprid resistant strain G25 and a susceptible counterpart S25 were obtained to analyze putative roles of P450s in imidacloprid resistance. Compared to S25, over-expression of twelve P450 genes was observed in G25, with ratios above 5.0-fold for CYP6AY1, CYP6ER1, CYP6CS1, CYP6CW1, CYP4CE1 and CYP425B1. RNAi against these genes in vivo and recombinant tests on the corresponding proteins in vitro revealed that four P450s, CYP6AY1, CYP6ER1, CYP4CE1 and CYP6CW1, played important roles in imidacloprid resistance. The importance of the four P450s was not equal at different stages of resistance development based on their over-expression levels, among which CYP6ER1 was important at all stages, and that the others might only contribute at certain stages. The results indicated that, to completely reflect roles of P450s in insecticide resistances, their over-expression in resistant individuals, expression changes at the stages of resistance development, and catalytic activities against insecticides should be considered. In this study, multiple P450s, CYP6AY1, CYP6ER1, CYP4CE1 and CYP6CW1, have proven to be important in imidacloprid resistance.     

Permethrin Induction of Multiple Cytochrome P450 Genes in Insecticide Resistant Mosquitoes,Culex quinquefasciatus

The expression of some insect P450 genes can be induced by both exogenous and endogenous compounds and there is evidence to suggest that multiple constitutively overexpressed P450 genes are co-responsible for the development of resistance to permethrin in resistant mosquitoes. This study characterized the permethrin induction profiles of P450 genes known to be constitutively overexpressed in resistant mosquitoes, Culex quinquefasciatus. The gene expression in 7 of the 19 P450 genes CYP325K3v1, CYP4D42v2, CYP9J45, (CYP) CPIJ000926, CYP325G4, CYP4C38, CYP4H40 in the HAmCqG8 strain, increased more than 2-fold after exposure to permethrin at an LC50 concentration (10 ppm) compared to their acetone treated counterpart; no significant differences in the expression of these P450 genes in susceptible S-Lab mosquitoes were observed after permethrin treatment. Eleven of the fourteen P450 genes overexpressed in the MAmCqG6 strain, CYP9M10, CYP6Z12, CYP9J33, CYP9J43, CYP9J34, CYP306A1, CYP6Z15, CYP9J45, CYPPAL1, CYP4C52v1, CYP9J39, were also induced more than doubled after exposure to an LC50 (0.7 ppm) dose of permethrin. No significant induction in P450 gene expression was observed in the susceptible S-Lab mosquitoes after permethrin treatment except for CYP6Z15 and CYP9J39, suggesting that permethrin induction of these two P450 genes are common to both susceptible and resistant mosquitoes while the induction of the others are specific to insecticide resistant mosquitoes. These results demonstrate that multiple P450 genes are co-up-regulated in insecticide resistant mosquitoes through both constitutive overexpression and induction mechanisms, providing additional support for their involvement in the detoxification of insecticides and the development of insecticide resistance.