Plant and Environmental Sciences, Weizmann Institute of Science, Rehovot, Israel.
Pest Manag Sci. 2018 Mar;74(3):511-515. doi: 10.1002/ps.4777. Epub 2017 Dec 8.
Microbiome organisms can degrade environmental xenobiotics including pesticides, conferring resistance to most types of pests. Some cases of pesticide resistance in insects, nematodes and weeds are now documented to be due to microbiome detoxification, and is a demonstrated possibility with rodents. Some cases of metabolic resistance may have been misattributed to pest metabolism, and not to organisms in the microbiome, because few researchers use axenic pests in studying pesticide metabolism. Instances of microbiomes evolving pesticide resistance contributing to resistance of their hosts may become more common due the erratic nature of climate change, as microbiome populations typically increase and evolve faster in stressful conditions. Conversely, microbiome organisms can be engineered to provide crops and beneficial insects with needed resistance to herbicides and insecticides, respectively, but there has not been sufficient efficacy to achieve commercial products useful at the field level, even with genetically engineered microbiome organisms. © 2017 Society of Chemical Industry.
微生物组生物可以降解环境中的外来化合物,包括杀虫剂,从而使大多数类型的害虫产生抗药性。目前已有文献记录表明,昆虫、线虫和杂草中的一些杀虫剂耐药性是由于微生物组的解毒作用所致,并且在啮齿动物中已得到证实。一些代谢抗性的情况可能被错误地归因于害虫的新陈代谢,而不是微生物组中的生物,因为很少有研究人员在研究农药代谢时使用无菌害虫。由于气候变化的不稳定性质,微生物组进化出的杀虫剂抗性可能会导致其宿主的抗性增加,这种情况可能会变得更加普遍,因为在压力条件下,微生物组种群通常会更快地增加和进化。相反,微生物组生物可以被设计为分别为作物和有益昆虫提供对除草剂和杀虫剂的所需抗性,但即使使用基因工程微生物组生物,也没有足够的功效来实现可在田间使用的商业产品。© 2017 英国化学工业学会
