If a grower does not stop using a herbicide soon after resistance to it evolves, resistance can be accelerated for the next herbicide alternative employed even if it provides a different mode of action.
Lawrence, Kansas (PRWEB) February 19, 2014
Effective herbicides are essential to rice production in the mid-southern United States. In recent decades, the primary weed that challenges rice fields, barnyardgrass, developed resistance to two widely used herbicides – propanil and quinclorac. To ensure that current herbicides remain effective, a simulation model is being used to predict the weed’s resistance in future years to guide weed management plans today.
Barnyardgrass can reduce rice yield up to 30 percent, and herbicides are the major component for controlling the weed. Simulation models can be beneficial in understanding the resistance evolution and developing strategies to prevent it.
An article in the journal Weed Technology discusses the development of a model that can analyze the simultaneous evolution of resistance to herbicides that inhibit the acetolactate synthase (ALS) and acetyl-CoA carboxylase (ACCase) enzymes. The model assumes the use of Clearfield rice, a commercial brand of rice cultivars that is resistant to certain ALS-inhibiting herbicides.
Using data from three locations in the rice-growing Mississippi Delta region of eastern Arkansas, the computer simulation model creates weed management scenarios across 1,000 hypothetical rice fields. The model takes into account three stages of growth—dormant seedbank, emerged seedlings, and mature plants—and extends over a 30-year period.
The simulation shows that if an ALS-inhibiting herbicide was used alone in three annual applications, weed resistance would develop within 4 years. Weed management that used both ALS- and ACCase-inhibiting herbicides reduced the risk of barnyardgrass developing a resistance to the ALS-inhibitor, but found a higher risk for the weed developing resistance to the ACCase-inhibitor by year 14. Resistance to both of these herbicide types when used together was predicted by year 16.
Several weed management strategies were revealed through the simulation model. An important insight was that if a grower does not stop using a herbicide soon after resistance to it evolves, resistance can be accelerated for the next herbicide alternative employed even if it provides a different mode of action. Minimizing the weed seedbank should be the focus of successful weed management. The model shows that diversified management techniques combined with timely applications of herbicide is the best way to achieve positive results.
Full text of the article, “Modeling the Simultaneous Evolution of Resistance to ALS- and ACCase-Inhibiting Herbicides in Barnyardgrass (Echinochloa crus-galli) in Clearfield Rice,” Weed Technology, Vol. 28, No. 1, January–March 2014, is now available.
About Weed Technology
Weed Technology presents (1) original research on weed/crop management systems, herbicides, weed resistance to herbicides, and weed biology; (2) reports of new weed problems, weed-related surveys, and new technologies for weed management; and (3) special articles emphasizing technology transfer to improve weed control. The journal is a publication of the Weed Science Society of America. To learn more about the society, please visit: http://www.wssa.net/.