Agroforestry and Plant Biochemistry, Proteomics and Systems Biology, Department of Biochemistry and Molecular Biology, University of Cordoba, UCO-CeiA3, 14014 Cordoba, Spain.
Biosciences Department, Polytechnic Institute of Beja, 7800-295 Beja, Portugal; VALORIZA-Research Centre for Endogenous Resource Valorization, Polytechnic Institute of Portalegre, 7300-555 Portalegre, Portugal.
Pestic Biochem Physiol. 2022 Nov;188:105226. doi: 10.1016/j.pestbp.2022.105226. Epub 2022 Sep 11.
Multiple resistance mechanisms to ALS inhibitors and auxin mimics in two Papaver rhoeas populations were investigated in wheat fields from Portugal. Dose-response trials, also with malathion (a cytochrome P450 inhibitor), cross-resistance patterns for ALS inhibitors and auxin mimics, alternative herbicides tests, 2,4-D and tribenuron-methyl absorption, translocation and metabolism experiments, together with ALS activity, gene sequencing and enzyme modelling and ligand docking were carried out. Results revealed two different resistant profiles: one population (R1) multiple resistant to tribenuron-methyl and 2,4-D, the second (R2) only resistant to 2,4-D. In R1, several target-site mutations in Pro197 and enhanced metabolism (cytochrome P450-mediated) were responsible of tribenuron-methyl resistance. For 2,4-D, reduced transport was observed in both populations, while cytochrome P450-mediated metabolism was also present in R1 population. Moreover, this is the first P. rhoeas population with enhanced tribenuron-methyl metabolism. This study reports the first case for P. rhoeas of the amino acid substitution Pro197Phe due to a double nucleotide change. This double mutation could cause reduced enzyme sensitivity to most ALS inhibitors according to protein modelling and ligand docking. In addition, this study reports a P. rhoeas population resistant to 2,4-D, apparently, with reduced transport as the sole resistance mechanism.
在葡萄牙的麦田中,研究了两个罂粟属种群对 ALS 抑制剂和生长素类似物的多种抗性机制。进行了剂量反应试验,还使用了马拉硫磷(一种细胞色素 P450 抑制剂),对 ALS 抑制剂和生长素类似物的交叉抗性模式、替代除草剂试验、2,4-D 和三甲嘧磺隆的吸收、转运和代谢实验,以及 ALS 活性、基因测序、酶建模和配体对接。结果显示出两种不同的抗性谱:一个种群(R1)对三甲嘧磺隆和 2,4-D 具有多重抗性,第二个种群(R2)仅对 2,4-D 具有抗性。在 R1 中,Pro197 中的几个靶位突变和增强的代谢(细胞色素 P450 介导)导致了三甲嘧磺隆的抗性。对于 2,4-D,两个种群都观察到转运减少,而细胞色素 P450 介导的代谢也存在于 R1 种群中。此外,这是第一个具有增强的三甲嘧磺隆代谢的罂粟属种群。本研究首次报道了由于双重核苷酸变化导致 Pro197Phe 氨基酸取代的罂粟属种群。根据蛋白质建模和配体对接,这种双重突变可能导致大多数 ALS 抑制剂的酶敏感性降低。此外,本研究还报道了一个对 2,4-D 具有抗性的罂粟属种群,显然,其唯一的抗性机制是转运减少。