蔬菜蚜虫抗药性现状及抗性治理策略

蚜虫是为害蔬菜作物的一类重要害虫,如不防治会给蔬菜生产造成重大经济损失。长期以来主要依靠使用农药防治蔬菜蚜虫,但由于化学农药的不合理使用,蔬菜蚜虫对有机磷、拟除虫菊酯、氨基甲酸酯、新烟碱等多种类型的杀虫药剂均产生了不同程度的抗性。本文对常见的蔬菜蚜虫的抗药性现状、抗药性机理以及治理策略进行了论述,以期为该类害虫的可持续控制提供参考。     

滇西南菜区小菜蛾发生规律及抗药性现状

为掌握滇西南菜区小菜蛾的发生规律和抗药性现状, 2013-2017年进行了田间系统调查幼虫、性信息素诱集成虫和室内毒力测定。结果表明:滇西南菜区小菜蛾田间种群每年早春存在种群激增现象, 3-5月份出现春季高峰期, 6月后种群数量保持较低水平。抗性测定表明, 该地区小菜蛾对丁醚脲、Bt、氯虫苯甲酰胺、虫螨腈、茚虫威均为低水平抗性, 对氟啶脲和多杀霉素为中等水平抗性; 对阿维菌素为中到高抗,对高效氯氰菊酯为高抗水平。建议该区域1-5月放置性信息素诱杀成虫, 3-4月用丁醚脲、Bt制剂、氯虫苯甲酰胺、虫螨腈、茚虫威等进行化学防治, 6-12月小菜蛾的发生虫量在经济阈值下, 可不防治。     

Inheritance of resistance to a Bacillus thuringiensis toxin in a field population of diamondback moth (Plutella xylostella)

Inheritance of resistance to the Bacillus thuringiensis Berl. CryIA(b) crystal protein was studied in Plutella xylostella L. (diamondback moth). A field population 50-fold more resistant to CryIA(b) than a control susceptible strain was used. Dose-mortality curves of the resistant population, the susceptible strain and the F₁ from the two reciprocal crosses were compared. Resistance transmission to the F₁ was dependent on the sex of the resistant progenitor. Sex ratio of the survivors to high doses of CryIA(b) in the F₁ of the two reciprocal crosses did not corroborate the preliminary hypothesis of resistance being due to a recessive sex-linked allele. Since, in a previous work, the loss of CryIA(b) binding capacity of resistant insects had been demonstrated, binding to midgut tissue sections from F₁ individuals was also analysed. The presence of binding in all of the F₁ preparations showed that, at least, a recessive autosomal allele was responsible for the loss of binding capacity in the resistant population.     

农业害虫抗药性及其治理

对农业害虫抗药性的定义、害虫抗药性现状、抗药性的发展因素、抗性产生的机理等方面进行了阐述,并介绍几种害虫抗药性治理方案。     

棉蚜抗药性现状及治理策略

棉蚜Aphis gossypii Glover是农业生产上最重要的害虫之一。化学杀虫剂一直以来都是棉蚜综合防治体系中的重要组成部分, 但化学杀虫剂的不合理使用导致棉蚜对多种杀虫剂均产生了高水平抗性。现有研究表明, 靶标位点突变、解毒酶基因的过表达以及某些肠道共生菌丰度的变化是导致棉蚜对杀虫剂产生抗性的主要机制。针对棉蚜抗性发展现状及其抗药性机制, 制定科学合理的抗性治理策略, 是充分发挥化学防治的优势、实现棉蚜可持续治理的关键。本文主要从棉蚜的抗药性现状、抗性机制和抗性治理策略3个方面对近10多年的主要进展进行了综述, 旨在为棉蚜抗药性长效治理和科学施策提供理论依据。     

草地贪夜蛾抗药性现状及化学防治策略

本文就草地贪夜蛾抗药性研究的历史、现状以及如何进行化学防治进行了比较系统的分析。针对国内外草地贪夜蛾发生的现状,从抗药性程度及交互抗性、种群遗传、抗药性机制以及化学防治的关键技术等方面进行了讨论。提出了化学防治要尽量做到药剂品种、时间和空间的配合;掌握好药剂防治的两个窗口期,一是害虫本身敏感的窗口期即从孵化到3龄初,二是孵化后到钻蛀前;分阶段选择适宜药剂类型用于化学防治。除了考虑杀虫剂作用机制类别外,作用方式也要考虑。卵高峰期施用具有触杀活性的药剂配合具有杀卵活性的药剂添加具有渗透功能的助剂,孵化高峰期施用触杀药剂配合胃毒药剂,后期大龄幼虫可以考虑胃毒药剂为主的化学防治策略。     

田间小菜蛾抗药性监测及毒理机制研究

田间监测结果表明，福州地区小菜蛾Plutella xylostella(L.)已对生产上常用的各类杀虫剂产生不同程度的抗性，从9月至次年5年期间，田间小菜蛾表现出较高水平的抗性，而在8月份则表现出明显低的抗性水平，短期高温和长期低温的环境条件可明显抑制小菜蛾幼虫的AChE和CarE活性，但短期低温的环境条件对小菜蛾幼虫的AChE和CarE活性影响不大，饲养温度的变化不会影响小菜蛾幼虫AChE和Ki值，但在较高的酶与杀虫剂的反应温度下，有机磷对小菜蛾、菜青虫和黄曲条跳甲AChE的抑制作用显著增高，此外，探讨了田间影响小菜蛾抗性水平的环境因素及毒理学机制。     

3种生物源杀虫剂对杜仲梦尼夜蛾的毒力及防效

针对专性为害杜仲的食叶害虫杜仲梦尼夜蛾(Orthosia songi Chen et Zhang)幼虫进行室内毒力测定,比较了3种生物源杀虫剂对其3龄和5龄幼虫的杀虫活性,并进行了林间药效测定和防治示范试验。结果显示:甲氨基阿维菌素苯甲酸盐(甲维盐)对3龄和5龄幼虫的LC50值分别为0.152 5和0.204 7μg/L,苦参碱的LC50值分别为65.306 0和124.735 8μg/L,印楝素的LC50值分别为165.871 7和257.749 0μg/L。林间药效测定结果显示5.7%甲维盐微乳剂300万倍液防治效果最好,7d后校正死亡率达91.34%。防治示范试验表明,5.7%甲维盐微乳剂75 000倍液防治效果达95.69%,显著高于0.3%苦参碱水剂750倍液的防治效果(80.28%),且药剂成本7.5元/hm2,仅为后者的1.9%。     

云南通海小菜蛾种群抗药性监测及田间药效评价

为掌握云南蔬菜主产区通海县小菜蛾种群对常用杀虫剂的敏感性及其田间防治效果, 采用浸叶法和田间小区试验对常用杀虫剂进行室内毒力测定和田间药效试验。结果表明：通海县小菜蛾种群对丁醚脲和Bt的敏感性最高, 仍处于敏感水平, 对茚虫威属低抗水平, 对虫螨腈和多杀菌素的抗性倍数分别为24.28和31.68倍, 属中抗水平, 对氯虫苯甲酰胺抗性倍数为44.62倍, 到高抗水平, 对阿维菌素的敏感性最差, 抗性倍数829.90倍, 达极高抗水平。抗性水平和田间药效呈一定相关性, 氯虫苯甲酰胺和阿维菌素药后7 d对小菜蛾的防治效果均低于50%, 茚虫威、多杀菌素和丁醚脲的田间防效较好。通海县小菜蛾可选择的防治药剂包括茚虫威、多杀菌素和丁醚脲, 注意不同药剂之间的轮换和交替使用。     

Escalating insecticide resistance in Australian grain pests: contributing factors,industry trends and management opportunities

Insecticide resistance is an ever‐increasing problem that threatens food production globally. Within Australia, the grain industry has a renewed focus on resistance due to diminishing chemical options available to farmers and the increasing prevalence and severity of resistance encountered in the field. Chemicals are too often used as the major tool for arthropod pest management, ignoring the potent evolutionary forces from chemical selection pressures that lead to resistance. A complex array of factors (biological, social, economic, political, climatic) have contributed to current trends in insecticide usage and resistance in the Australian grain industry. We review the status of insecticide resistance and provide a context for how resistance is currently managed. We discuss emerging technologies and research that could be applied to improve resistance management. This includes generating baseline sensitivity data for insecticides before they are launched, developing genetic diagnostics for the full complement of known resistances, expanding resistance monitoring programs, and utilizing new technologies. Additional benefits are likely to be achieved through a combination of industry awareness and engagement, risk modeling, adoption of integrated pest management tactics, greater collaboration between industry stakeholders, and policy changes around chemical use and record keeping. The Australian grain context provides lessons for other agricultural industries. © 2018 Society of Chemical Industry     

棉叶螨的抗药性现状与治理策略

棉叶螨也称为棉红蜘蛛,属蛛形纲叶螨科,其种类繁多,分布范围广,世代周期短,是为害棉花的一类重要害螨。目前,用于防治棉叶螨的化学药剂主要是神经毒剂及呼吸抑制剂2大类,且棉叶螨对多数药剂产生了不同程度的抗性,以二斑叶螨Tetranychus urticae为首的植食性害螨已成为世界上抗药性最严重的节肢动物之一。美国路易斯安那州棉田二斑叶螨种群对阿维菌素产生了1 415倍抗性,而国内棉花上棉叶螨主要对有机磷类药剂产生了较强抗性,最高为467倍。棉叶螨产生抗药性的机制主要涉及靶标突变及解毒代谢增强,其中靶标突变主要涉及乙酰胆碱酯酶、电压门控钠离子通道和谷氨酸门控氯离子通道等;细胞色素P450单加氧酶、羧酸酯酶和谷胱甘肽S-转移酶等一种或多种解毒酶共同参与害螨对化学药剂的解毒代谢。该文主要从棉叶螨的种类及分布、用于防治棉叶螨的化学药剂、棉叶螨的抗药性现状、抗药性机制解析和抗药性治理策略5个方面进行阐述,提出因地制宜的抗药性治理策略,旨在为棉叶螨的田间防治提供指导。     

Genetics of spinosad resistance in a multi-resistant field-selected population of Plutella xylostella

Resistance to the bacteria-derived insecticides spinosad (Conserve), abamectin (Vertimec), Bacillus thuringiensis var kurstaki (Btk) (Dipel), B thuringiensis var aizawai (Bta) (Xentari), B thuringiensis crystal endotoxins Cry1Ac and Cry1Ca, and to the synthetic insecticide fipronil was estimated in a freshly-collected field population (CH1 strain) of Plutella xylostella (L) from the Cameron Highlands, Malaysia. Laboratory bioassays at G1 indicated significant levels of resistance to spinosad, abamectin, Cry1Ac, Btk, Cry1Ca, fipronil and Bta when compared with a laboratory insecticide-susceptible population. Logit regression analysis of F1 reciprocal crosses indicated that resistance to spinosad in the CH1 population was inherited as a co-dominant trait. At the highest dose of spinosad tested, resistance was close to completely recessive, while at the lowest dose it was incompletely dominant. A direct test of monogenic inheritance based on a back-cross of F1 progeny with CH1 suggested that resistance to spinosad was controlled by a single locus.     

Evidence for Resistance to Bacillus thuringiensis (Bt) subsp. kurstaki HD-1, Bt subsp. aizawai and Abamectin in Field Populations of Plutella xylostella from Malaysia

The efficacy of Bacillus thuringiensis (Bt) subsp. kurstaki HD-1 (‘Dipel’™; Btk; CryIA & CryII) and Bt. subsp. aizawai (‘Florbac’™; Bta; CryIA & CryIC) was assessed against larvae from various field populations of Plutella xylostella (F2 generation) collected in the Cameron Highlands, Malaysia in April 1994 and a lowland population (SERD 2; F10 generation) collected in December 1993. Evidence of resistance to Btk and to a lesser extent Bta is reported in these populations (LC₅₀ Toxicity Ratios [TR]=3–14 and 2–8 respectively), most notably in SERD 2. The first recorded evidence of resistance to abamectin (TR=17–195-fold) in field populations of P. xylostella is also reported. In an unselected sub-population of SERD 2, the TR values for Btk, Bta and abamectin declined 2- to 3-fold (P<0·01) over six generations in the laboratory (F10–F16) while in sub-populations of SERD 2 selected with these products (F11–F15) there was a significant (P<0·01) increase in the TR (15-, 3- and 2·5-fold respectively) when compared with the F10 generation. This suggests the presence of marked resistance to Btk and some resistance to Bta and abamectin. There is also evidence of slight cross-resistance to Btk in the Bta-selected sub-population but no evidence for the reverse selection of resistance or for cross-resistance between Btk and abamectin. Concurrent selection studies (F11–F15) with another sub-population of SERD 2 demonstrated resistance to the acylurea insect growth regulator, teflubenzuron (‘Nomolt’™) (29-fold increase in TR). Based on the selection experiments with SERD 2, estimates of realised heritability (h²) of resistance gave very high values for teflubenzuron and Btk (c.0·7) and moderate values for abamectin and Bta (c.0·3). The results are discussed in relation to integrated pest management (IPM) and insecticide resistance management (IRM) strategies for P. xylostella.     

Gene amplification and insecticide resistance

Pesticide resistance in arthropods has been shown to evolve by two main mechanisms, the enhanced production of metabolic enzymes, which bind to and/or detoxify the pesticide, and mutation of the target protein, which makes it less sensitive to the pesticide. One route that leads to enhanced metabolism is the duplication or amplification of the structural gene(s) encoding the detoxifying enzyme, and this has now been described for the three main families (esterases, glutathione S-transferases and cytochrome P450 monooxygenases) implicated in resistance. More recently, a direct or indirect role for gene duplication or amplification has been described for target-site resistance in several arthropod species. This mini-review summarises the involvement of gene duplication/amplification in the insecticide/acaricide resistance of insect and mite pests and highlights recent developments in this area in relation to P450-mediated and target-site resistance.     

Fitness costs associated with insecticide resistance

Insects are exposed to a variety of stress factors in their environment, and, in many cases for insect pests to agriculture, those factors include toxic chemical insecticides. Coping with the toxicity of insecticides can be costly and requires energy and resource allocation for adaptation and survival. Several behavioural, physiological and genetic mechanisms are used by insects to handle toxic insecticides, sometimes leading to resistance by constitutive overexpression of detoxification enzymes or inducing mutations in the target sites. Such actions are costly and may affect reproduction, impair dispersal ability and have several other effects on the insect's fitness. Fitness costs resulting from resistance to insecticides has been reported in many insects from different orders, and several examples are given in this mini‐review. Copyright © 2012 Society of Chemical Industry     

小菜蛾抗药性分子遗传机理的探讨与分析

采用核型分析和代表性差异分析方法,探讨了小菜蛾抗药性的分子遗传机理.结果表明,敏感品系和抗性品系小菜蛾的染色体数目均为2n=30条,两者的核型无明显差异;以敏感品系作为驱赶扩增子,抗溴氰菊酯、抗杀虫双、抗杀螟丹近等基因系分别作为检测扩增子进行消减杂交和差异片段的富集.最后随机选取部分差异片段作探针,Southern blot验证,分别在抗杀虫双、抗溴氰菊酯和抗杀螟丹近等基因系中筛选出2、2和3个特异片段.从研究结果可以看出,与敏感品系相比,三种抗性品系小菜蛾的核型没有发生明显的变化,但在DNA水平上存在明显的差异,说明小菜蛾的抗药性与基因组DNA的变化有关.