Holtum J A, Matthews J M, Häusler R E, Liljegren D R, Powles S B
Department of Crop Protection, Waite Agricultural Research Institute, University of Adelaide, Glen Osmond, 5064, South Australia, Australia.
Plant Physiol. 1991 Nov;97(3):1026-34. doi: 10.1104/pp.97.3.1026.
Annual ryegrass (Lolium rigidum) biotype SLR 31 is resistant to the postemergent graminicide methyl-2-[4-(2,4-dichlorophenoxy)phenoxy]-propanoate (diclofop-methyl). Uptake of (14)Cdiclofop-methyl and root/shoot distribution of radioactivity in susceptible and resistant plants were similar. In both biotypes, diclofop-methyl was rapidly demethylated to the biocidal metabolite diclofop acid which, in turn, was metabolized to ester and aryl-O-sugar conjugates. Susceptible plants accumulated 5 to 15% more radioactivity in dicloflop acid than did resistant plants. Resistant plants had a slightly greater capacity to form nonbiocidal sugar conjugates. Despite these differences, resistant plants retained 20% of (14)C in the biocidal metabolite diclofop acid 192 hours after treatment, whereas susceptible plants, which were close to death, retained 30% in diclofop acid. The small differences in the pool sizes of the active and inactive metabolites are by themselves unlikely to account for a 30-fold difference in sensitivity to the herbicide at the whole plant level. Similar high-pressure liquid chromatography elution patterns of conjugates from both susceptible and resistant biotypes indicated that the mechanisms and the products of catabolism in the biotypes are similar. It is suggested that metabolism of diclofop-methyl by the resistant biotype does not alone explain resistance observed at the whole-plant level. Diclofop acid reduced the electrochemical potential of membranes in etiolated coleoptiles of both biotypes; 50% depolarization required 1 to 4 mum diclofop acid. After removal of diclofop acid, membranes from the resistant biotype recovered polarity, whereas membranes from the susceptible biotype did not. Internal concentrations of diclofop acid 4 h after exposing plants to herbicide were estimated to be 36 to 39 micromolar in a membrane fraction and 16 to 17 micromolar in a soluble fraction. Such concentrations should be sufficient to fully depolarize membranes. It is postulated that differences in the ability of membranes to recover from depolarization are correlated with the resistance response of biotype SLR 31.
一年生黑麦草(多花黑麦草)生物型SLR 31对苗后禾本科除草剂甲基-2-[4-(2,4-二氯苯氧基)苯氧基]-丙酸酯(禾草灵)具有抗性。¹⁴C禾草灵在敏感和抗性植株中的吸收以及放射性在根/地上部的分布相似。在这两种生物型中,禾草灵迅速脱甲基形成具有杀生活性的代谢物禾草灭酸,而禾草灭酸又进一步代谢为酯和芳基-O-糖缀合物。敏感植株在禾草灭酸中积累的放射性比抗性植株多5%至15%。抗性植株形成无杀生活性的糖缀合物的能力略强。尽管存在这些差异,但在处理192小时后,抗性植株在具有杀生活性的代谢物禾草灭酸中保留了20%的¹⁴C,而接近死亡的敏感植株在禾草灭酸中保留了30%。活性和非活性代谢物库大小的微小差异本身不太可能解释在整株水平上对除草剂敏感性30倍的差异。来自敏感和抗性生物型的缀合物相似的高压液相色谱洗脱模式表明,这两种生物型中分解代谢的机制和产物是相似的。有人认为抗性生物型对禾草灵的代谢并不能单独解释在整株水平上观察到的抗性。禾草灭酸降低了两种生物型黄化胚芽鞘中膜的电化学势;50%的去极化需要1至4 μmol的禾草灭酸。去除禾草灭酸后,抗性生物型的膜恢复了极性,而敏感生物型的膜没有。在将植株暴露于除草剂4小时后,膜部分中禾草灭酸的内部浓度估计为36至39 μmol/L,可溶部分中为16至17 μmol/L。这样的浓度应该足以使膜完全去极化。据推测,膜从去极化中恢复能力的差异与生物型SLR 31的抗性反应相关。