Rosenzweig N, Hanson L E, Clark G, Franc G D, Stump W L, Jiang Q W, Stewart J, Kirk W W
Department of Plant, Soil and Microbial Sciences, Michigan State University, 612, Wilson Road, 35 Plant Biology Building, East Lansing, MI 48824, USA.
Department of Plant, Soil and Microbial Science, and United States Department of Agriculture Agricultural Research Service, 1066 Bogue Street, Room 494, East Lansing, MI 48824, USA.
Plant Dis. 2015 Mar;99(3):355-362. doi: 10.1094/PDIS-03-14-0241-RE.
Genetic resistance to Quinone outside inhibitor (QoI) and benzimidazole fungicides may be responsible for a recent decline in efficacy of chemical control management strategies for Cercospora leaf spot (CLS) caused by Cercospora beticola in Michigan sugarbeet (Beta vulgaris) fields. The target genes and fungicide resistance mutations are known for these two fungicides. Based on this, two standard polymerase chain reaction restriction fragment length polymorphism (PCR-RFLP) assays were developed to detect the G143A and E198A point mutations in the fungal mitochondrial cytochrome b and the β-tubulin genes, respectively. These mutations confer a high level of resistance to either QoI or benzimidazole fungicides. The presence of the G143A and E198A mutations was monitored within C. beticola populations recovered from Michigan sugarbeet production fields collected in 2012. Both the QoI-resistant cytochrome b allele and the benzimidazole-resistant β-tubulin allele were detected directly from leaf tissue following a PCR-RFLP assay. Using either detection assay, the G143A and E198A mutations were detected in over 90% of the 118 field samples originating from Michigan sugarbeet production under fungicide management programs for CLS control. Monitoring of the G143A and E198A mutations in fields located in 9 counties and 58 townships indicated that the mutations were widespread in Michigan sugarbeet production areas. The PCR-based assays used and developed in this study were effective in detecting the presence of the G143A and E198A mutations in C. beticola field populations from Michigan.
对醌外抑制剂(QoI)和苯并咪唑类杀菌剂的遗传抗性,可能是近期密歇根州甜菜(Beta vulgaris)田由甜菜生尾孢菌(Cercospora beticola)引起的叶斑病(CLS)化学防治管理策略效果下降的原因。这两种杀菌剂的靶标基因和抗药性突变是已知的。基于此,开发了两种标准的聚合酶链反应-限制性片段长度多态性(PCR-RFLP)检测方法,分别用于检测真菌线粒体细胞色素b和β-微管蛋白基因中的G143A和E198A点突变。这些突变赋予对QoI或苯并咪唑类杀菌剂的高水平抗性。在2012年从密歇根州甜菜生产田采集的甜菜生尾孢菌种群中监测G143A和E198A突变的存在。通过PCR-RFLP检测后,直接从叶片组织中检测到抗QoI的细胞色素b等位基因和抗苯并咪唑的β-微管蛋白等位基因。使用任何一种检测方法,在118个源自密歇根州实施CLS防治杀菌剂管理计划的甜菜生产田的田间样本中,超过90%检测到G143A和E198A突变。对位于9个县和58个乡镇的田间G143A和E198A突变的监测表明,这些突变在密歇根州甜菜产区广泛存在。本研究中使用和开发的基于PCR的检测方法,对于检测密歇根州甜菜生尾孢菌田间种群中G143A和E198A突变的存在是有效的。
