Plant pathologists help thwart vexing grain disease

May 23, 2014 by Blaine Friedlander
Damaged by Fusarium head blight, many wheat spikelets are prematurely bleached, while others on the same plant remain green. Credit: Gary Bergstrom/Cornell

(Phys.org) —To protect wheat for bread and barley for beer, Cornell plant pathologists have been evaluating ways to battle fungal blight. Recently the scientists found that a local fungal strain is no longer controlled by a key fungicide. Their findings provide warning to farmers, who can, however, surmount field problems with sound pest management practices.

Fusarium head blight distresses wheat and barley, destroys prospering green fields and contaminates grains with a fungal toxin known as vomitoxin. The disease has caused exceptionally high crop loss in the past few decades. Following a blight infestation about 14 years ago, U.S. producers suffered a $2.7 billion loss.

Plant pathology professor Gary Bergstrom, Pierri Spolti, lead author and a visiting plant pathologist in Bergstrom's lab, and colleagues examined fungal sensitivity to the widely used tebuconazole. They found the first tebuconazole-resistant field isolate of Fusarium graminearum ever reported in North or South America.

Bergstrom explains that judiciously applying a family of fungicides called triazoles - of which tebuconazole is a member - when the crop flowers will continue as a successful crop management strategy. However, he cautions that multiple applications of the same fungicide at different crop stages and over wide geographic areas pose a risk for eventual resistance in fungal populations.

All agriculturists involved in North American cereal production should realize that decreased effectiveness of important head-blight control fungicides could occur if these materials are not managed carefully to reduce the selection pressure on Fusarium head blight fungus populations, Bergstrom said. We hope our findings will spur more routine screening of Fusarium populations. That way producers can put into place resistance-management strategies that prevent failures in the future.

The research, Triazole Sensitivity in a Contemporary Population of Fusarium graminearum From New York Wheat and Competitiveness of a Tebuconazole-resistant Isolate, was co-authored by Emerson Del Ponte, Federal University of Vicosa, Brazil; Yanghong Dong, University of Minnesota; and Jaime Cummings, Cornell research support specialist.

Explore further: Biochemical pathways may be key to scab resistance

More information: Triazole Sensitivity in a Contemporary Population of Fusarium graminearum from New York Wheat and Competitiveness of a Tebuconazole-Resistant Isolate. Pierri Spolti, et al. Plant Disease Journal. May 2014, Volume 98, Number 5. Pages 607-613. dx.doi.org/10.1094/PDIS-10-13-1051-RE

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