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澳大利亚羽毛草(Chloris virgata)种群中对草甘膦具有抗性的靶位突变。

Target-site mutations conferring resistance to glyphosate in feathertop Rhodes grass (Chloris virgata) populations in Australia.

机构信息

School of Agriculture, Food and Wine, University of Adelaide, Glen Osmond, Adelaide, SA, Australia.

出版信息

Pest Manag Sci. 2018 May;74(5):1094-1100. doi: 10.1002/ps.4512. Epub 2017 Feb 13.

DOI:10.1002/ps.4512
PMID:28019078
Abstract

BACKGROUND

Chloris virgata is a warm-season, C , annual grass weed affecting field crops in northern Australia that has become an emerging weed in southern Australia. Four populations with suspected resistance to glyphosate were collected in South Australia, Queensland and New South Wales, Australia, and compared with one susceptible (S) population to confirm glyphosate resistance and elucidate possible mechanisms of resistance.

RESULTS

Based on the rate of glyphosate required to kill 50% of treated plants (LD ), glyphosate resistance (GR) was confirmed in four populations of C. virgata (V12, V14.2, V14.16 and V15). GR plants were 2-9.7-fold more resistant and accumulated less shikimate after glyphosate treatment than S plants. GR and S plants did not differ in glyphosate absorption and translocation. Target-site EPSPS mutations corresponding to Pro-106-Leu (V14.2) and Pro-106-Ser (V15, V14.16 and V12) substitutions were found in GR populations. The population with Pro-106-Leu substitution was 2.9-4.9-fold more resistant than the three other populations with Pro-106-Ser substitution.

CONCLUSION

This report confirms glyphosate resistance in C. virgata and shows that target-site EPSPS mutations confer resistance to glyphosate in this species. The evolution of glyphosate resistance in C. virgata highlights the need to identify alternative control tactics. © 2016 Society of Chemical Industry.

摘要

背景

Chloris virgata 是一种温暖季节的 C4 一年生杂草,影响澳大利亚北部的大田作物,在澳大利亚南部已成为一种新兴杂草。在澳大利亚南澳大利亚州、昆士兰州和新南威尔士州收集了四个疑似对草甘膦具有抗性的种群,并与一个敏感(S)种群进行比较,以确认草甘膦抗性并阐明可能的抗性机制。

结果

根据杀死 50%处理植物所需的草甘膦剂量(LD),在 Chloris virgata 的四个种群(V12、V14.2、V14.16 和 V15)中确认了草甘膦抗性(GR)。GR 植株比 S 植株对草甘膦的抗性高 2-9.7 倍,并且在草甘膦处理后积累的莽草酸较少。GR 和 S 植物在草甘膦吸收和转运方面没有差异。在 GR 种群中发现了对应于 Pro-106-Leu(V14.2)和 Pro-106-Ser(V15、V14.16 和 V12)取代的靶标位点 EPSPS 突变。与具有 Pro-106-Ser 取代的三个种群相比,具有 Pro-106-Leu 取代的种群对草甘膦的抗性高 2.9-4.9 倍。

结论

本报告确认了 Chloris virgata 对草甘膦的抗性,并表明靶标位点 EPSPS 突变赋予该物种对草甘膦的抗性。Chloris virgata 中草甘膦抗性的进化突出表明需要确定替代的控制策略。© 2016 化学工业协会。

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