Ryegrass resistance to glyphosate and amitrole is becoming common in New Zealand vineyards

Q3 Agricultural and Biological Sciences

New Zealand Plant Protection Pub Date : 2022-09-21 DOI:10.30843/nzpp.2022.75.11760

C. Buddenhagen, Ben P. Harvey, Ben Wynne-Jones, D. Hackell, H. Ghanizadeh, Yuichi Ando, Zachary Ngow, T. James

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引用次数: 5

Abstract

The prevalence of herbicide resistance in ryegrass (Lolium spp.) in the wine-growing regions in New Zealand is poorly understood. Cases of glyphosate, glufosinate and amitrole-resistant ryegrass were documented in a few vineyards in New Zealand in 2013, but there have been no regional surveys for resistance. To address this knowledge gap, 106 vineyards were visited across the important New Zealand wine-growing regions of Marlborough and Waipara in late February 2021, and Hawke’s Bay and Gisborne in late February 2022, and seed samples from individual plants at each site surviving weed-control measures were collected. Ryegrass was found in more South Island (68%) than North Island (20%) vineyards. These seeds, and those from a susceptible ryegrass population were sown in marked rows into trays (10-20 seeds per herbicide) and grown in a glasshouse. When seedlings reached the 3-4 leaf stage, trays were sprayed at the highest recommended label rate of glyphosate. Samples with enough seed were also screened against additional herbicides, amitrole, glufosinate or clethodim. The results indicated 39% of the surveyed vineyards contained glyphosate-resistant ryegrass, with cases detected across all regions, including 58% of vineyards in Marlborough. Eleven of the 27 Marlborough vineyards screened contained amitrole-resistant ryegrass; six samples were also resistant to glyphosate. However, glufosinate and clethodim were still effective against ryegrass at the sites tested. Considering the levels of herbicide resistance to ryegrass observed in this study, growers should explore alternative weed-suppression measures, including tilling, cover-crops, grazing, mowing and the use of herbicides with different modes of action.

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黑麦草对草甘膦和硝唑的抗性在新西兰葡萄园越来越普遍

在新西兰的葡萄酒产区，黑麦草(Lolium spp.)除草剂抗性的流行程度尚不清楚。2013年，在新西兰的一些葡萄园中记录了草甘膦、草铵膦和氨硝抗性黑麦草的病例，但没有对抗性进行区域调查。为了解决这一知识差距，研究人员于2021年2月底访问了马尔堡和怀帕拉等新西兰重要葡萄酒产区的106个葡萄园，并于2022年2月底访问了霍克湾和吉斯伯恩，并收集了每个地点幸存的单株植物的种子样本。黑麦草在南岛(68%)的葡萄园中比在北岛(20%)的葡萄园中更多。这些种子，以及那些来自易感黑麦草种群的种子，被标记成行地播种在托盘中(每种除草剂10-20粒种子)，并在温室中生长。当幼苗长到3-4叶期时，在托盘上喷洒草甘膦的最高推荐标示率。含有足够种子的样品也被筛选为不使用其他除草剂，如氨硝、草铵膦或噻虫酮。结果显示，39%的被调查葡萄园含有抗草甘膦黑麦草，在所有地区都发现了病例，其中包括马尔伯勒58%的葡萄园。在筛选的27个马尔伯勒葡萄园中，有11个葡萄园含有抗真菌黑麦草;6个样本对草甘膦也有抗性。然而，草铵膦和氯噻虫胺对黑麦草仍然有效。考虑到本研究中观察到的黑麦草对除草剂的抗性水平，种植者应探索替代的杂草抑制措施，包括耕作、覆盖作物、放牧、刈割和使用不同作用方式的除草剂。

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来源期刊

New Zealand Plant Protection Agricultural and Biological Sciences-Insect Science

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： New Zealand Plant Protection is the journal of the New Zealand Plant Protection Society. It publishes original research papers on all aspects of biology, ecology and control of weeds, vertebrate and invertebrate pests, and pathogens and beneficial micro-organisms in agriculture, horticulture, forestry and natural ecosystems of relevance to New Zealand.