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Genetic Basis and Monitoring of Resistance of Botryotinia fuckeliana to Anilinopyrimidines.灰葡萄孢对苯胺嘧啶类药剂的抗性遗传基础及监测
Plant Dis. 1998 May;82(5):496-500. doi: 10.1094/PDIS.1998.82.5.496.
2
Resistance of Botrytis cinerea to Multiple Fungicides in Northern German Small-Fruit Production.德国北部小浆果生产中灰葡萄孢对多种杀菌剂的抗性
Plant Dis. 2011 Oct;95(10):1263-1269. doi: 10.1094/PDIS-03-11-0209.
3
Phenotypic Characterization of Multifungicide Resistance in Botrytis cinerea Isolates from Strawberry Fields in Florida.佛罗里达州草莓田灰葡萄孢菌分离株对多种杀菌剂抗性的表型特征分析
Plant Dis. 2013 Mar;97(3):393-401. doi: 10.1094/PDIS-08-12-0748-RE.
4
Fenhexamid Resistance in Botrytis cinerea from Strawberry Fields in the Carolinas Is Associated with Four Target Gene Mutations.卡罗来纳州草莓田灰葡萄孢中苯菌灵抗性与四个靶基因突变有关。
Plant Dis. 2013 Feb;97(2):271-276. doi: 10.1094/PDIS-06-12-0587-RE.
5
Differential Effect of SdhB Gene Mutations on the Sensitivity to SDHI Fungicides in Botrytis cinerea.SdhB基因突变对灰葡萄孢菌对琥珀酸脱氢酶抑制剂类杀菌剂敏感性的差异影响
Plant Dis. 2013 Jan;97(1):118-122. doi: 10.1094/PDIS-03-12-0322-RE.
6
Resistance to Cyprodinil and Lack of Fludioxonil Resistance in Botrytis cinerea Isolates from Strawberry in North and South Carolina.来自北卡罗来纳州和南卡罗来纳州草莓上的灰葡萄孢菌分离株对嘧菌环胺的抗性及对咯菌腈的敏感性
Plant Dis. 2013 Jan;97(1):81-85. doi: 10.1094/PDIS-06-12-0539-RE.
7
Location-Specific Fungicide Resistance Profiles and Evidence for Stepwise Accumulation of Resistance in Botrytis cinerea.灰葡萄孢中特定位置的杀菌剂抗性谱及抗性逐步积累的证据
Plant Dis. 2014 Aug;98(8):1066-1074. doi: 10.1094/PDIS-10-13-1019-RE.
8
Resistance to Fluopyram, Fluxapyroxad, and Penthiopyrad in Botrytis cinerea from Strawberry.草莓灰霉病菌对氟吡菌酰胺、氟唑菌酰胺和戊唑嘧菌胺的抗性
Plant Dis. 2014 Apr;98(4):532-539. doi: 10.1094/PDIS-07-13-0753-RE.
9
Occurrence of fungicide resistance in populations of Botryotinia fuckeliana (Botrytis cinerea) on table grape and strawberry in southern Italy.意大利南部鲜食葡萄和草莓上灰霉病菌(灰葡萄孢)群体中杀菌剂抗性的发生情况
Pest Manag Sci. 2014 Dec;70(12):1785-96. doi: 10.1002/ps.3711. Epub 2014 Jan 24.
10
Fitness and competitive ability of Botrytis cinerea field isolates with dual resistance to SDHI and QoI fungicides, associated with several sdhB and the cytb G143A mutations.对 SDHI 和 QoI 杀菌剂具有双重抗性的灰葡萄孢田间分离物的适应性和竞争能力,与多个 sdhB 和 cytb G143A 突变有关。
Phytopathology. 2014 Apr;104(4):347-56. doi: 10.1094/PHYTO-07-13-0208-R.

植物病原真菌中杀菌剂抗性的威胁日益增加:以灰霉病菌为例的研究

The rising threat of fungicide resistance in plant pathogenic fungi: Botrytis as a case study.

作者信息

Hahn Matthias

机构信息

Department of Biology, University of Kaiserslautern, P.O. box 3049, Kaiserslautern, Germany.

出版信息

J Chem Biol. 2014 May 28;7(4):133-41. doi: 10.1007/s12154-014-0113-1. eCollection 2014 Oct.

DOI:10.1007/s12154-014-0113-1
PMID:25320647
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4182335/
Abstract

The introduction of site-specific fungicides almost 50 years ago has revolutionized chemical plant protection, providing highly efficient, low toxicity compounds for control of fungal diseases. However, it was soon discovered that plant pathogenic fungi can adapt to fungicide treatments by mutations leading to resistance and loss of fungicide efficacy. The grey mould fungus Botrytis cinerea, a major cause of pre- and post-harvest losses in fruit and vegetable production, is notorious as a 'high risk' organism for rapid resistance development. In this review, the mechanisms and the history of fungicide resistance in Botrytis are outlined. The introduction of new fungicide classes for grey mould control was always followed by the appearance of resistance in field populations. In addition to target site resistance, B. cinerea has also developed a resistance mechanism based on drug efflux transport. Excessive spraying programmes have resulted in the selection of multiresistant strains in several countries, in particular in strawberry fields. The rapid erosion of fungicide activity against these strains represents a major challenge for the future of fungicides against Botrytis. To maintain adequate protection of intensive cultures against grey mould, strict implementation of resistance management measures are required as well as alternative strategies with non-chemical products.

摘要

大约50年前,位点特异性杀菌剂的引入彻底改变了化学植物保护领域,为控制真菌病害提供了高效、低毒的化合物。然而,人们很快发现,植物病原真菌能够通过导致抗性和杀菌剂效力丧失的突变来适应杀菌剂处理。灰霉病菌(Botrytis cinerea)是水果和蔬菜生产中采前和采后损失的主要原因,作为一种抗药性快速发展的“高风险”生物体而声名狼藉。在这篇综述中,概述了灰霉病菌抗药性的机制和历史。用于控制灰霉病的新型杀菌剂类别一经推出,田间种群中就会出现抗性。除了靶标位点抗性外,灰霉病菌还发展出了一种基于药物外排转运的抗性机制。过度的喷洒方案导致几个国家,特别是草莓田,出现了多重抗性菌株。针对这些菌株的杀菌剂活性迅速丧失,这对未来防治灰霉病菌的杀菌剂构成了重大挑战。为了持续充分保护集约栽培作物免受灰霉病侵害,需要严格实施抗性管理措施以及采用非化学产品的替代策略。