宁夏稻田稗草对氰氟草酯抗药性及多抗性与交互抗性研究

为明确宁夏地区稻田稗草对乙酰辅酶A羧化酶抑制剂类除草剂氰氟草酯的抗药性水平以及对其他除草剂可能存在的交互抗性与多抗性情况,采用整株生物测定法研究了采自宁夏稻田的36个稗草种群对氰氟草酯的抗药性, 并使用单剂量法测定了各种群对五氟磺草胺、嘧啶肟草醚、噁唑酰草胺、二氯喹啉酸和敌稗的交互抗性及多抗性。结果表明, 以氰氟草酯GR50数值最小的生物型为敏感生物型计算抗性指数(RI), 仅有1个稗草种群在推荐剂量下被完全杀死, RI≤ 3.0; 11个稗草种群的RI范围为3.3～9.4, 表现出低水平抗性, 发生频率为30.56%; 19个种群的RI范围为10.3~58.3, 表现出中等水平抗性; 发生频率为52.78%; 5个稗草种群的RI＞100, 表现出高水平抗性, 占比13.89%, 其中采自银川市贺兰县立岗镇通义村的稗草种群抗性水平最高。交互抗性和多抗性研究结果表明, 在田间最高推荐剂量下氰氟草酯对稗草鲜重抑制率低于90%的种群中, 58%的稗草种群对噁唑酰草胺产生了交互抗性, 对五氟磺草胺、嘧啶肟草醚、二氯喹啉酸和敌稗产生多抗性的种群所占百分率分别为94%、100%、100%和18%。研究发现宁夏地区水稻田多数稗草种群对氰氟草酯产生了不同程度的抗药性, 并对其他常用稻田除草剂产生了交互抗性与多抗性, 其中银北地区稗草种群抗药性水平最高, 部分地区稗草抗性已达到高抗水平, 宁夏水稻田亟须抗性稗草综合治理技术的研究。     

Multiple resistance of Botrytis cinerea from kiwifruit to SDHIs,QoIs and fungicides of other chemical groups

BACKGROUND: Botrytis cinerea Pers.: Fr. is a high‐risk pathogen for fungicide resistance development that has caused resistance problems on many crops throughout the world. This study investigated the fungicide sensitivity profile of isolates from kiwifruits originating from three Greek locations with different fungicide use histories. Sensitivity was measured by in vitro fungitoxicity tests on artificial nutrient media. RESULTS: Seventy‐six single‐spore isolates were tested for sensitivity to the SDHI fungicide boscalid, the QoI pyraclostrobin, the anilinopyrimidine cyprodinil, the hydroxyanilide fenhexamid, the phenylpyrrole fludioxonil, the dicarboxamide iprodione and the benzimidazole carbendazim. All isolates from Thessaloniki showed resistance to both boscalid and pyraclostrobin, while in the other two locations the fungal population was sensitive to these two fungicides. Sensitive isolates showed EC₅₀ values to boscalid and pyraclostrobin ranging from 0.9 to 5.2 and from 0.04 to 0.14 mg L^?1 respectively, while the resistant isolates showed EC₅₀ values higher than 50 mg L^?1 for boscalid and from 16 to > 50 mg L^?1 for pyraclostrobin. All QoI‐resistant isolates carried the G143A mutation in cytb. Sensitivity determinations to the remaining fungicides revealed in total eight resistance phenotypes. No isolates were resistant to the fungicides fenhexamid and fludioxonil. CONCLUSION: This is the first report of B. cinerea field isolates with resistance to both boscalid and pyraclostrobin, and it strongly suggests that there may be a major problem in controlling this important pathogen on kiwifruit. Copyright © 2010 Society of Chemical Industry     

Response of two lacewing species to biorational and broad-spectrum insecticides

Green lacewings, includingChrysoperla rufilabris (Burmeister) andCeraeochrysa cubana (Hagen), are predators of small, soft-bodied insects including whiteflies. The silverleaf whitefly,Bemisia argentifolii Bellows & Perring [formerlyB. tabaci (Gennadius) strain B], is an important pest of agronomic, vegetable and ornamental crops. Practical use of these lacewings as biological control agents would be facilitated by better understanding of their responses to both biorational (selective) and broad-spectrum insecticides. The topical and residual toxicity of azadirachtin (Azatin-EC^TM), insecticidal soap (M-Pede^TM), paraffinic oil (Sunspray Ultra-Fine Spray Oil^TM) and the pyrethroid bifenthrin (Brigade^TM) to eggs, larvae and adults of the lacewings were studied in the laboratory. Larvae ofC. cubana were much more tolerant to residues of bifenthrin than wasC. rufilabris and were somewhat more tolerant to topically applied soap. At normal field concentrations, azadirachtin (0.005%, by wt a.i.), paraffinic oil (1.0% by volume) and soap (1.0% by volume) were not toxic to larvae or adults of either species either topically or residually. Oil was toxic topically to eggs but azadirachtin and soap were not. Bifenthrin was toxic topically and residually to larvae and adults but was not so toxic to eggs as was oil. Thus, selectivity of all materials tested was relative to lacewing species and lifestage. The relative tolerance to insecticide residues exhibited byC. cubana larvae may be related to its trash-carrying habit, suggesting that use of trash-carrying chrysopids in place of non-trash carriers for augmentative biological control would increase options for non-disruptive chemical intervention when necessary.