Resistance to ALS-inhibiting herbicides in Cyperus difformis has evolved rapidly in many rice areas worldwide. This study identified the mechanism of resistance, assessed cross-resistance patterns to all five chemical groups of ALS-inhibiting herbicides in four C. difformis biotypes, and attempted to sequence the ALS gene. Whole-plant and ALS enzyme activity dose-response assays indicated that the WA biotype was resistant to all ALS-inhibiting herbicides evaluated. The IR biotype was resistant to bensulfuron-methyl, orthosulfamuron, imazethapyr, and propoxycarbazone-sodium and less resistant to bispyribac-sodium and halosulfuron-methyl, and susceptible to penoxsulam. ALS enzyme activity assays indicated that resistance is due to an altered target site yet mutations previously found to endow target-site resistance in weeds were not detected in the sequences obtained. The inability to detect resistance mutations in C. difformis may result from the presence of additional ALS genes, which were not amplified by the primers used. This study reports the first ALS gene sequence from Cyperus difformis. Certain ALS-inhibiting herbicides can still be used to control some resistant C. difformis biotypes. However, because cross-resistance to all five classes of ALS-inhibitors was detected in other resistant biotypes, these herbicides should only be used within an integrated weed management program designed to delay the evolution of herbicide resistance.
Cross resistance to herbicides of five ALS-inibiting groups and sequencing of the ALS gene in Cyperus difformis L
VIDOTTO, Francesco;FERRERO, Aldo;
2009-01-01
Abstract
Resistance to ALS-inhibiting herbicides in Cyperus difformis has evolved rapidly in many rice areas worldwide. This study identified the mechanism of resistance, assessed cross-resistance patterns to all five chemical groups of ALS-inhibiting herbicides in four C. difformis biotypes, and attempted to sequence the ALS gene. Whole-plant and ALS enzyme activity dose-response assays indicated that the WA biotype was resistant to all ALS-inhibiting herbicides evaluated. The IR biotype was resistant to bensulfuron-methyl, orthosulfamuron, imazethapyr, and propoxycarbazone-sodium and less resistant to bispyribac-sodium and halosulfuron-methyl, and susceptible to penoxsulam. ALS enzyme activity assays indicated that resistance is due to an altered target site yet mutations previously found to endow target-site resistance in weeds were not detected in the sequences obtained. The inability to detect resistance mutations in C. difformis may result from the presence of additional ALS genes, which were not amplified by the primers used. This study reports the first ALS gene sequence from Cyperus difformis. Certain ALS-inhibiting herbicides can still be used to control some resistant C. difformis biotypes. However, because cross-resistance to all five classes of ALS-inhibitors was detected in other resistant biotypes, these herbicides should only be used within an integrated weed management program designed to delay the evolution of herbicide resistance.File | Dimensione | Formato | |
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Merotto et al. - 2009 - Cross-Resistance to Herbicides of Five ALS-Inhibit.pdf
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