惠州地区褐飞虱对几种药剂的抗药性监测

2009年采用稻茎浸渍法测定广东省惠州地区褐飞虱Nilaparvata lugens(Stl)种群对吡虫啉、噻嗪酮、异丙威、丁烯氟虫腈、烯定虫胺和毒死蜱等杀虫剂的敏感性,测定结果表明:当地褐飞虱种群对吡虫啉产生了极高水平抗性(抗性倍数为422.2倍),对噻嗪酮、异丙威产生了中等水平抗性(抗性倍数分别为11.0和14.0倍),对丁烯氟虫腈仍处于敏感性降低(抗性倍数为3.7倍),对烯定虫胺和毒死蜱敏感(抗性倍数<3倍)。基于褐飞虱对这6种药剂抗性的明显差异,对田间治理褐飞虱合理使用药剂进行了讨论。     

褐飞虱和白背飞虱对几类杀虫剂的敏感性

为了科学用药和抗性治理提供理论基础, 采用稻茎浸渍法测定了2008年7月采自浙江省杭州市和宁波市褐飞虱 Nilaparvata lugens (Stål)种群对7种杀虫剂的抗药性及褐飞虱和白背飞虱Sogatella furcifera (Horváth)种群对16种杀虫剂的敏感性。褐飞虱抗药性测定结果表明, 与相对敏感品系相比, 杭州种群和宁波种群对吡虫啉的抗性倍数分别为479.0倍和366.1倍; 对氯噻啉的抗性倍数分别为81.1倍和50.9倍; 对噻虫嗪的抗性倍数分别为10.3倍和9.4倍; 对噻嗪酮和氟虫腈分别产生了5.0~8.6倍和15.8~17.0倍的抗药性; 对烯啶虫胺和啶虫脒的抗性倍数在3倍以下。两种稻飞虱对杀虫剂的敏感性测定结果表明: 噻虫嗪、噻嗪酮、烯啶虫胺和毒死蜱对褐飞虱和白背飞虱种群都具有较高的室内毒力。当田间褐飞虱和白背飞虱混合发生时, 可选用噻虫嗪、噻嗪酮、烯啶虫胺和毒死蜱进行防治, 不宜使用吡虫啉、氯噻啉和氟虫腈防治。     

几类杀虫剂对灰飞虱的相对毒力及田间种群的抗药性现状

采用浸苗法测定了6类11种杀虫剂对灰飞虱Laodelphax striatellus (Fallén)3龄若虫的毒力,并分析比较了江苏句容、通州、楚州、大丰、南京和苏州以及安徽庐江等7地灰飞虱种群对10种杀虫剂的抗药性水平。对云南种群而言,在所测杀虫剂中,以乙酰甲胺磷为标准药剂,氟虫腈的相对毒力最高;噻嗪酮、阿维菌素和噻虫嗪次之;高效氯氰菊酯、IPP（硝基亚甲基类化合物）、毒死蜱、敌敌畏和三唑磷间毒力处于同一数量级,低于阿维菌素等杀虫剂;吡虫啉的相对毒力最低。与云南种群相比,2007年采自苏、皖7个不同地区的灰飞虱种群对噻嗪酮产生了极高水平的抗性,其抗性倍数均超过200倍;对高效氯氰菊酯产生了中高水平的抗性,其抗性倍数为7.8～108.8;安徽庐江灰飞虱种群对三唑磷产生了7.7倍的抗性,对毒死蜱产生了12.0倍的抗性,江苏楚州、南京、大丰和句容灰飞虱种群对毒死蜱产生了5.7～12.6倍的抗性; 所有灰飞虱种群对敌敌畏仍然敏感,对氟虫腈、阿维菌素和新烟碱类杀虫剂吡虫啉、噻虫嗪和IPP等也比较敏感。     

中国和越南褐飞虱抗药性研究

2010年用稻茎浸渍法监测了我国和越南共14个褐飞虱Nilaparvata lugens(St(a)l)田间种群对5种杀虫剂的抗性,结果表明:14个褐飞虱田间种群对吡虫啉、噻嗪酮、氟虫腈、吡蚜酮和叶蝉散的LC50值分别在9.5287～46 6716、1.6621～17.8785、0.9818～ 8.4084、0.331...     

湖北稻区褐飞虱田间种群对常用杀虫剂抗药性监测

【目的】明确目前褐飞虱Nilaparvata lugens田间种群对常用防治药剂的抗性现状,为制定褐飞虱的科学用药策略提供科学依据。【方法】于2009-2014年采用稻茎浸渍法监测了湖北褐飞虱武穴梅川、枣阳十里铺、孝感陈店、鄂州长港和武汉江夏稻田的褐飞虱田间种群对11种杀虫剂的敏感性。【结果】湖北稻区褐飞虱田间种群已对吡虫啉(抗性倍数RR=101.8~1 239.4)、噻嗪酮(RR=15.9~1 326.3)产生高水平抗性;对噻虫嗪(RR=24.9~146.5)产生中等水平至高水平抗性;对噻虫胺(RR=9.9~16.5)、呋虫胺(RR=13.5~15.9)、乙虫腈(RR=18.3~60.4)、毒死蜱(RR=17.4~29.8)、异丙威(RR=13.9~46.0)产生中等水平抗性;对啶虫脒(RR=5.1~9.9)产生低水平抗性;对噻虫啉(RR=3.9~7.1)处于敏感至低水平抗性水平;对醚菊酯(RR=1.3~4.9)处于敏感水平。此外,褐飞虱对噻虫嗪、噻嗪酮抗性上升明显,同时褐飞虱对吡虫啉抗性也有上升的趋势。【结论】仍需暂停吡虫啉、噻嗪酮在水稻上防治稻飞虱,严格限制吡蚜酮在水稻上的使用次数;醚菊酯可作为吡虫啉、噻嗪酮和吡蚜酮的替代药剂或轮换药剂。     

褐飞虱抗药性研究现状

褐飞虱Nilaparvata lugens(Stal)对杀虫剂产生抗药性是其近年来暴发频繁的重要原因。文章综述国内外关于褐飞虱抗药性的研究成果,包括褐飞虱抗性测定方法、抗药性的发展、交互抗性、抗性遗传、抗性机理及抗性治理等。田间褐飞虱种群对新烟碱类药剂产生不同程度的抗药性,其中对吡虫啉产生高水平到极高水平抗性,对氯噻啉和噻虫嗪分别产生中等水平和低水平的抗药性,对呋虫胺和烯啶虫胺仍然处于敏感性阶段。此外,褐飞虱种群对噻嗪酮(昆虫生长调节剂)产生低水平到中等水平抗性。长期大面积使用化学药剂是褐飞虱产生抗药性的重要原因。因此,必须加强褐飞虱的抗性治理,以延缓其抗药性进一步发展。     

贵州稻区褐飞虱种群对六种杀虫剂的抗性动态

【目的】为明确贵州褐飞虱Nilaparvata lugens种群对常用杀虫剂的抗性水平。【方法】在室内采用浸渍法测定了2013-2015年采自贵州黄平、桐梓和开阳3地的褐飞虱种群对6种杀虫剂(吡虫啉、噻虫嗪、异丙威、噻虫胺、啶虫脒和醚菊酯)的抗性。【结果】贵州褐飞虱种群对不同的杀虫剂存在着抗性差异。与敏感品系相比,2013-2015年间3地田间褐飞虱种群对吡虫啉、噻虫嗪、异丙威、噻虫胺的抗性均达到中等水平抗性,抗性倍数(resistance ratio,RR)分别为21.88~95.38,10.91~69.36,13.00~57.23和23.11~39.54倍;而对啶虫脒和醚菊酯仍处于敏感阶段,RR分别为0.47~0.75和0.41~0.85倍。【结论】褐飞虱对吡虫啉和噻虫嗪的抗性较高,可能与近年来广泛地大量使用有关。本研究的抗性动态监测结果对贵州稻区褐飞虱的杀虫剂种类调整及施药策略等具有重要指导作用。     

灰飞虱对噻嗪酮的抗性风险及机理

为研究灰飞虱对噻嗪酮的抗性发展规律及抗性生化机理,采用稻苗喷雾法对灰飞虱种群进行连续筛选获得高抗性品系,估算其现实遗传力并进行田间抗性风险预测;采用稻苗浸渍法测定杀虫剂对灰飞虱的毒力及交互抗性;利用生物化学方法测定不同品系之间的解毒酶活力,探讨灰飞虱对噻嗪酮的抗性生化机理.结果表明:用噻嗪酮对灰飞虱种群连续筛选32代,其抗性倍数达到168.49倍,现实遗传力h~2为0.11.当杀死率为80%~90%时,预计灰飞虱对噻嗪酮的抗性增长10倍,仅需要5~6代.田间实际的现实遗传力要比室内选择种群估计低一些,预计田间抗性提高10倍所需要时间会更长.交互抗性测定结果表明,灰飞虱抗噻嗪酮品系与吡虫啉和噻虫嗪之间有高水平交互抗性,与啶虫脒有低水平交互抗性,与吡蚜酮和毒死蜱无交互抗性.增效作用和解毒酶活力测定结果显示,抗性品系细胞色素P450单加氧酶活力提高最大,酯酶次之,谷胱甘肽-S-转移酶无显著变化.田间使用噻嗪酮防治灰飞虱存在较大抗性风险,可与吡蚜酮和毒死蜱等交替使用以延缓抗性发展;3种解毒酶中,细胞色素P450单加氧酶在灰飞虱对噻嗪酮的抗性发展中起到了重要作用.     

5种杀虫剂对滇东白背飞虱种群的毒性及其田间药效

【目的】为持续有效防控白背飞虱,研究云南东部白背飞虱种群对常用5种杀虫剂的敏感性及药剂的田间防治效果。【方法】采用室内稻茎浸渍法测定白背飞虱种群对5种杀虫剂的敏感性,同期通过田间小区试验评价5种杀虫剂对白背飞虱种群的防治效果。【结果】与敏感种群比较,噻虫嗪、噻嗪酮、吡虫啉、吡蚜酮和毒死蜱对滇东白背飞虱种群的LC_(50)分别为0.208、0.459、0.608、3.108、1.256 mg·L~(-1),抗性倍数分别为2.2、10.4、5.6、6.5、5.3倍;白背飞虱对噻虫嗪无抗性,对吡虫啉、吡蚜酮和毒死蜱为低水平抗性,对噻嗪酮为中等水平抗性;5种杀虫剂药后1、5和10 d对白背飞虱种群的田间防控效果均有显著差异。除了吡蚜酮外,其他药剂的防效均在80%以上,其中以吡虫啉和噻嗪酮的持续期较长,药后10 d仍在90%以上;噻虫嗪和吡虫啉药后1和5 d的防效达90%以上;吡蚜酮药效在供试药剂中防效最低,在64.88%～77.82%之间。【结论】滇东师宗白背飞虱种群对噻嗪酮为中等水平抗性,对吡虫啉、吡蚜酮和毒死蜱均为低水平抗性,对噻虫嗪无抗性,田间防控效果以吡虫啉和噻嗪酮为最好。建议滇东稻区可以使用吡虫啉和噻嗪酮药剂防控白背飞虱,注意控制吡蚜酮的使用次数与用量。     

福建省烟粉虱田间种群抗药性发展及其影响因素

采用成虫浸叶生测法对福建省不同地区烟粉虱田间种群的抗药性发展进行监测.结果表明： 福建各地烟粉虱田间种群对氯氟氰菊酯、甲氰菊酯、毒死蜱仍保持较高水平抗性,对灭多威的抗性水平较低,对阿维菌素未产生明显的抗药性;烟粉虱田间种群对烟碱类杀虫剂的抗性发展极为迅速,其中漳州种群对吡虫啉、噻虫嗪已由2005年的中等水平抗性（抗性倍数分别为23和25倍）发展为2009年的高水平抗性（抗性倍数分别为103和228倍）,其他地区种群对吡虫啉、噻虫嗪也由2005年的低水平抗性（抗性倍数分别为1.5～3.3倍和1.7～5.5倍）发展为2009年的中等水平抗性（抗性倍数分别为23～33倍和29～49倍）.采用mtDNA CO I分子标记技术对福建省不同地区和寄主植物上采集的8个烟粉虱种群的生物型进行鉴定发现,采自漳州变叶木上的烟粉虱种群为本地土著种(未知生物型),其他7个采自大田蔬菜作物的烟粉虱种群均为B型.寄主植物和温度对烟粉虱种群的药剂敏感性影响有限,吡虫啉等烟碱类杀虫剂高强度使用是B型烟粉虱田间种群对该类型药剂迅速形成抗性的重要原因.     

Dynamics of imidacloprid resistance and cross-resistance in the brown planthopper, Nilaparvata lugens

Extensive use of imidacloprid for suppressing the brown planthopper, Nilaparvata lugens (Stål) (Homoptera: Delphacidae), has placed heavy selection pressure on the target insect. A systematic study was carried out to determine imidacloprid resistance dynamics and cross-resistance. Data collected from a 3-year study (2005–2007) showed that in 2005, the resistance levels in Nanning (Guangxi), Haiyan (Zhejiang), and Nanjing and Tongzhou (Jiangsu) populations ranged from 200- to 799-fold compared with the susceptible strain. However, the resistance levels decreased to 135- to 233-fold in 2007, after reduced application of the chemical. A laboratory population was challenged with imidacloprid in successive generations. After 23 generations, the resistance ratio had increased from 200- to 1 298-fold. Continuous selection with imidacloprid could increase the resistance level even more than has already been developed in the population. Stopping selection with imidacloprid led to a rapid decrease of resistance from 759- to 114-fold after 17 generations. Resistance levels then became stable without decreasing any further. A similar result was also obtained from a study involving a field population (resistance ratio = 625-fold) collected from Tongzhou. At first, the population showed a rapid decrease in resistance right after imidacloprid selection was stopped, and then the resistance stabilized at a level of 105–129-fold. More interestingly, resistance increased again when selection was resumed. In addition, the resistant strain selected with imidacloprid showed substantial cross-resistance to imidaclothiz, thiacloprid, and acetamiprid, and slight levels of cross-resistance to dinotefuran and thiamethoxam, but no obvious cross-resistance to nitenpyram, buprofezin, and fipronil. The information from this study is valuable for formulating resistance-management strategies against N. lugens .     

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.     

Baseline susceptibility of Planococcus ficus (Hemiptera: Pseudococcidae) from California to select insecticides

Between 2006 and 2008, 20 populations of Planococcus ficus (Signoret), from Coachella and San Joaquin Valleys of California were measured in the laboratory for susceptibility to buprofezin, chlorpyrifos, dimethoate, methomyl, and imidacloprid. Toxicity was assessed using a petri dish bioassay technique for contact insecticides and by a systemic uptake technique for imidacloprid. Mixed life stages were tested for susceptibility to all insecticides except for buprofezin, which was measured against early and late instars (first, second, and third). Dose-response regression lines from the mortality data established LC50 and LC99 values by both techniques. Responses of populations from the two geographical locations to all five insecticides varied, in some cases significantly. Variations in susceptibility to each insecticide among sample sites showed a sevenfold difference for buprofezin, 11-fold to chlorpyrifos, ninefold to dimethoate, 24-fold to methomyl, and 8.5-fold to imidacloprid. In spite of susceptibility differences between populations, baseline toxicity data revealed that all five insecticides were quite effective based on low LC50s. Chlorpyrifos was the most toxic compound to Planococcus ficus populations as shown by lowest LC50s. Buprofezin was toxic to all immature stages but was more potent to first instars. The highest LC99 estimated by probit analysis of the bioassay data of all 20 populations for each compound was selected as a candidate discriminating dose for use in future resistance monitoring efforts. Establishment of baseline data and development of resistance monitoring tools such as bioassay methods and discriminating doses are essential elements of a sustainable management program for Planococcus ficus.     

Effects of synergists on toxicity of six insecticides in parasitoid Diaeretiella rapae (Hymenoptera: Aphidiidae)

The resistance to and the effects of synergists on the toxicity of six insecticides in Diaeretiella rapae (M'Intosh) (Hymenoptera: Aphidiidae), a parasitoid of vegetable aphid collected in Jianxin at Fuzhou-City, Fujian, China, were studied. In comparison with susceptible F21 progeny, the resistance ratios in resistant F0 parents were 27.6 for methamidophos, 20.8 for fipronil, 47.5 for avermectin, 3.3 for fenvalerate, 4.5 for cypermethrin, and 74.7 for imidacloprid. Piperonyl butoxide (PB), triphenyl phosphate (TPP), and diethyl maleate (DEM) were chosen to be applied in susceptible F21 progeny, as well as in resistant F11 progeny and F0 parents. Significant synergistic effects on the toxicity of the six insecticides were found by using PB, TPP, and DEM in F0 parents; on methamidophos, avermectin, and imidacloprid by PB, TPP, and DEM in F11 progeny; on fipronil by PB and DEM in F11 progeny; and on fenvalerate and cypermethrin by PB in F11 progeny. PB also showed significant synergism on the six insecticides in susceptible F21 progeny, although the synergism was far less in F21 progeny than those in resistant F0 parents. TPP and DEM showed little or no synergistic effects on the toxicity of the six insecticides in F21 progeny. Compared with TPP and DEM, the highest synergistic ratios of PB for methamidophos, fipronil, avermectin, fenvalerate, cypermethrin, and imidacloprid were observed in F0 parents, and F11 and F21 progeny. The resistance levels to methamidophos, fipronil, avermectin, fenvalerate, and cypermethrin could be inhibited strongly by applying PB in F0 parents. From the results, oxidative degradation is believed to play a critical role in resistance to methamidophos, fipronil, avermectin, fenvalerate, and cypermethrin in D. rapae. To a lesser extent, hydrolytic reactions also were partially involved in the resistance to these five insecticides by using the synergists PB, TPP, and DEM. However, although high synergism of PB, TPP, and DEM on imidacloprid was found, the resistance levels to imidacloprid remained high in the presence of PB, TPP, and DEM. The mediated detoxification of oxidative degradation and hydrolytic reactions was thought to be involved in the resistance to imidacloprid in F0 parents.     

山东省五个棉花产区绿盲蝽对药剂的敏感性检测（英文）

利用闪烁管药膜法测定了2009年山东省德州、滨州、梁山、曲阜和聊城5个棉花产区绿盲蝽Lygus lucorum Meyer-Dür对硫丹、马拉硫磷、毒死蜱、灭多威、丁硫克百威、吡虫啉、联苯菊酯和氟虫腈8种杀虫剂的敏感性,筛选出适合各地区的高效防治药剂。结果表明：5个地区绿盲蝽种群对马拉硫磷、毒死蜱、丁硫克百威、联苯菊酯和吡虫啉处于敏感性阶段。不同种群之间对灭多威、硫丹和氟虫腈的敏感性差异较大,其中聊城种群为最敏感种群,滨州种群对灭多威、 硫丹和氟虫腈的LC₅₀值分别为聊城种群的5.12,6.04和39.80倍;曲阜种群对灭多威、硫丹和氟虫腈的LC₅₀值分别为聊城种群的22.12,5.48和22.80倍。两种群对此3种药剂的敏感性下降,而其余种群仍处于较敏感阶段。8种药剂对绿盲蝽成虫的毒力按大小依次排序为：氟虫腈＞灭多威、联苯菊酯、硫丹＞马拉硫磷、毒死蜱＞丁硫克百威＞吡虫啉。2009年7-10月间德州夏津绿盲蝽种群对8种杀虫剂的敏感性变化极微。