Delaney C Foster, Peter A Dotray, Stanley Culpepper, Lawrence E Steckel
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引用次数: 0
Abstract
Abstract Cotton and soybean growers were offered new technologies in 2016, expanding in-crop herbicide options to include dicamba or 2,4-D. Within three years of commercialization, dicamba use in these crops increased ten-fold and growers began to report Palmer amaranth escapes in dicamba-tolerant production systems in western Tennessee. In 2020, Palmer amaranth seed was collected from eight Tennessee locations where growers witnessed poor control following dicamba. Greenhouse experiments were conducted to evaluate the response of these Palmer amaranth populations to dicamba. In 2021, field experiments were conducted on two tentative dicamba-susceptible populations in Georgia, on three confirmed dicamba-resistant populations in Tennessee, and on a tentative dicamba-susceptible population in Texas to evaluate cotton response following dicamba and to examine if malathion insecticide (a cytochrome P450 inhibitor) would improve weed control and not reduce cotton yield when applied in conjunction with dicamba. Palmer amaranth populations collected in 2020 survived dicamba in the greenhouse at 1, 2, and 4 times the labeled rate. There was 15 to 26% survival exhibited by five Palmer amaranth populations to the labeled dicamba rate (560 g ha -1 ) in the greenhouse. These findings were reinforced in the field when research on three of those populations in 2021 showed 55% control with the labeled dicamba rate and 69% control with 2 times the labeled rate. This demonstrates the dicamba resistance allele or alleles were passed between generations. This result was not consistent in the Macon County or Worth County, GA locations where malathion improved dicamba control of 15- to 38-cm tall Palmer amaranth. Cotton injury was observed when malathion was applied in combination with dicamba. These results further document the evolution of dicamba-resistant Palmer amaranth in Tennessee. Moreover, the non-reversal of resistance phenotype by malathion may suggest that the resistance mechanism is something other than metabolism.
2016年,棉花和大豆种植者获得了新技术,增加了麦草畏或2,4- d除草剂的选择。在商业化的三年内,麦草畏在这些作物中的使用增加了十倍,种植者开始报告在田纳西州西部耐麦草畏的生产系统中,帕尔默苋菜逃逸。2020年,从田纳西州的八个地方收集了帕尔默苋菜种子,种植者发现麦草畏后控制不佳。通过温室试验评价了这些苋菜群体对麦草畏的反应。2021年,对佐治亚州的两个麦草畏试探性易感种群、田纳西州的三个麦草畏抗性种群和德克萨斯州的一个麦草畏试探性易感种群进行了田间试验,以评估麦草畏对棉花的反应,并检验马拉硫磷杀虫剂(一种细胞色素P450抑制剂)与麦草畏联合使用是否会改善杂草控制,而不会降低棉花产量。2020年收集的苋菜种群在温室中麦草畏的存活率分别是标记率的1倍、2倍和4倍。在温室中,5个苋菜群体对标记的麦草畏用量(560 g ha -1)的存活率为15% ~ 26%。这些发现在2021年对其中三个种群的研究中得到了进一步的证实,55%的种群控制了标记的麦草畏含量,69%的种群控制了标记的麦草畏含量的两倍。这表明抗麦草畏等位基因或等位基因在代间传递。在乔治亚州的梅肯县或沃斯县,马拉硫磷改善了对15至38厘米高的帕尔默苋菜的麦草畏控制,但这一结果并不一致。马拉硫磷与麦草畏联用对棉花有伤害。这些结果进一步证明了田纳西州抗麦草畏苋菜的进化。此外,马拉硫磷对抗性表型的不逆转可能表明抗性机制不是代谢机制。
期刊介绍:
Weed Technology publishes original research and scholarship in the form of peer-reviewed articles focused on understanding how weeds are managed.
The journal focuses on:
- Applied aspects concerning the management of weeds in agricultural systems
- Herbicides used to manage undesired vegetation, weed biology and control
- Weed/crop management systems
- Reports of new weed problems
-New technologies for weed management and special articles emphasizing technology transfer to improve weed control
-Articles dealing with plant growth regulators and management of undesired plant growth may also be accepted, provided there is clear relevance to weed science technology, e.g., turfgrass or woody plant management along rights-of-way, vegetation management in forest, aquatic, or other non-crop situations.
-Surveys, education, and extension topics related to weeds will also be considered