芳氧苯氧基丙酸酯类除草剂的应用进展

芳氧苯氧基丙酸酯（简称APP）类除草剂是近二十年发展起来的活性很好的新型除草剂,用于防除一年或多年生禾本科杂草。本文主要综述了APP的发展历史、作用机理、主要品种以及应用研究进展。     

靶标酶在除草剂研究与开发中的作用

大多数除草剂都是通过特殊酶的抑制而产生杀草作用的。根据作用靶标对除草剂进行分类,了解靶标酶的作用机理及特性,对于新型除草剂的设计和杂草抗性的防治能够起到很大的帮助。本文介绍了谷胱甘肽转移酶(GST)、细胞色素P450酶、乙酰乳酸合成酶(ALS)、乙酞辅酶A羧化酶(ACCace)的研究进展。并分别从酶的生理功能、酶学特征、抑制剂作用机理、抑制剂的研究、抗性等方面进行了不同程度的阐述。     

上海市水稻田千金子对3种乙酰辅酶A羧化酶抑制剂的抗性现状及酶突变机制

为明确上海市水稻田千金子对乙酰辅酶A羧化酶 (ACCase) 抑制剂类除草剂的抗性发生情况及可能存在的抗性机制,在上海市千金子发生严重地区的水稻田共采集51个种群,采用单剂量抗性甄别法测定了不同千金子种群对3种ACCase抑制剂类除草剂的抗性水平,扩增和比对了靶标酶ACCase基因部分片段的差异。结果显示:在氰氟草酯105 g/hm2有效成分剂量选择压下,8个千金子种群标记为抗性种群,6个种群为发展中抗性种群;在噁唑酰草胺 120 g/hm2有效成分剂量选择压下,4个千金子种群标记为抗性种群,5个种群为发展中抗性种群;在精噁唑禾草灵62.1 g/hm2有效成分剂量选择压下,6个千金子种群标记为抗性种群,2个种群为发展中抗性种群。对15个抗性千金子种群靶标酶基因片段的测序发现,9个种群共发生了4种ACCase基因突变类型,分别为ACCase基因 1999 位点色氨酸 (TGG) 突变为丝氨酸 (TCG)、1999位点色氨酸 (TGG) 突变为半胱氨酸 (TGT)、2027位点色氨酸 (TGG) 突变为丝氨酸 (TCG) 以及2027位点色氨酸 (TGG) 突变为半胱氨酸 (TGT/TGC)。其中,5个抗性千金子种群ACCase 基因突变频率均大于60%。研究表明,ACCase抑制剂类除草剂抗性千金子在上海市部分地区发生已较为严重,ACCase 基因突变是导致不同千金子种群对该类除草剂产生抗性的重要原因之一。     

河南省多花黑麦草对ACCase和ALS抑制剂的抗性及其靶标基因突变分析

为明确河南省部分地区的多花黑麦草Lolium multiflorum种群对乙酰辅酶A羧化酶（acetylCoA carboxylase,ACCase）和乙酰乳酸合成酶（acetolactate synthase,ALS）抑制剂类除草剂的抗性水平和抗性机理,采用整株生物测定法测定采自新乡市和驻马店市的多花黑麦草种群对ACCase抑制剂类除草剂精噁唑禾草灵、炔草酯、唑啉草酯和ALS抑制剂类除草剂甲基二磺隆、氟唑磺隆、啶磺草胺的抗性水平,并对多花黑麦草ACCase和ALS靶标酶编码基因进行克隆及氨基酸序列比对,分析其靶标抗性机理。结果显示,与多花黑麦草敏感种群HNXX01相比,HNZMD04和HNXX05种群对6种除草剂均产生了抗性,HNZMD04种群对精噁唑禾草灵和啶磺草胺的相对抗性倍数分别为44.65和40.31,对炔草酯和氟唑磺隆的相对抗性倍数分别为11.91和11.93;HNXX05种群对精噁唑禾草灵和氟唑磺隆的相对抗性倍数分别为27.70和25.67。HNZMD04和HNXX05抗性种群的ACCase基因均发生了D2078G突变,2个种群的突变率分别为55%和70%;HNZMD04...     

Cross-resistance profile of mesosulfuron-methyl-resistant Italian ryegrass in the southern United States

Diclofop-resistant Lolium species (ryegrass) is a major weed problem in wheat production worldwide. This study was conducted to determine the resistance pattern of diclofop-resistant ryegrass accessions from the southern United States to mesosulfuron-methyl, a recently commercialized herbicide for ryegrass control in wheat; to determine the cross-resistance pattern of a Lolium multiflorum Lam. (Italian ryegrass) accession, 03-1, to acetolactate synthase (ALS) and acetyl-CoA carboxylase (ACCase) inhibitors; and to determine the resistance mechanism of Italian ryegrass to mesosulfuron-methyl. Seventeen ryegrass accessions from Arkansas and Louisiana, including standard resistant and susceptible accessions, were used in this experiment. Fourteen of the 17 accessions were more resistant (four- to > 308-fold) to diclofop than the standard susceptible biotype. One accession, 03-1, was resistant to mesosulfuron-methyl as well as to other ALS inhibitor herbicides such as chlorsulfuron, imazamox and sulfometuron. Accession 03-1, however, did not show multiple resistance to the ACCase inhibitor herbicides diclofop, fluazifop, clethodim, sethoxydim and pinoxaden, nor to glyphosate. The in vivo ALS activity of the 03-1 biotype was less affected by mesosulfuron-methyl than the susceptible biotype. This indicates that the resistance mechanism of Italian ryegrass to mesosulfuron-methyl is partly due to an alteration in the target enzyme, ALS. It is concluded that diclofop-resistant ryegrass in the southern United States can be generally controlled by mesosulfuron-methyl. However, mesosulfuron-methyl must be used with caution because not all ryegrass populations are susceptible to it. There is a need for more thorough profiling of ryegrass resistance to herbicides.     

Metabolomics - A robust bioanalytical approach for the discovery of the modes-of-action of pesticides: A review

The agrochemical industry is facing great undertaking that includes increasing demand for the development of new crop protection agents that are safe for the environment and the consumers, and at the same time combat the issue of the emergence of resistance pest strains. The mode-of-action (MoA) is among the features of a bioactive compound that largely determine whether the abovementioned issues are addressed or not, and subsequently whether its commercial development will be addressed. The early discovery of the MoA of bioactive compounds could accelerate pesticide research and development by reducing the required time and costs. Based on advances in synthetic and natural product chemistry, scientists have access to a vast number of compounds that could potentially be developed as crop protection agents. The screening of such compounds with respect to their MoA requires accurate and robust bioanalytical tools. Metabolomics is a powerful bioanalytical tool that will likely play a significant role in the acceleration of the discovery of MoA of bioactive compounds. In the present review, the capabilities and principles and applications of metabolomics for the study of the MoA of herbicides, insecticides, acaricides, fungicides, and antibiotics are discussed.