News Release

New study finds corn genome can gang up on multiple pathogens at once

Peer-Reviewed Publication

University of Illinois College of Agricultural, Consumer and Environmental Sciences

Tiffany Jamann

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University of Illinois Urbana-Champaign plant pathologist Tiffany Jamann (pictured) and her team identified genomic regions associated with four major diseases of maize, paving the way for future breeding programs that could develop multiple-disease-resistant hybrids. 

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Credit: Provided by Tiffany Jamann, University of Illinois.

URBANA, Ill. — In a changing climate, corn growers need to be ready for anything, including new and shifting disease dynamics. Because it’s impossible to predict which damaging disease will pop up in a given year, corn with resistance to multiple diseases would be a huge win for growers. Now, University of Illinois Urbana-Champaign researchers are moving the industry closer to that goal. 

Goss’s wilt, a bacterial disease, and fungal diseases gray leaf spot, northern corn leaf blight, and southern corn leaf blight are important to growers across the Midwestern U.S. and, in some cases, globally. The study, published in G3 Genes|Genomes|Genetics, reveals genomic regions associated with resistance to all four diseases.

“We not only found regions of the genome conferring resistance to each disease, but also identified a handful of experimental corn lines that were resistant to all of them. These findings should help the industry develop materials with resistance to multiple diseases at once,” said Tiffany Jamann, senior author of the new study and associate professor in the Department of Crop Sciences, part of the College of Agricultural, Consumer and Environmental Sciences (ACES) at U. of I.

The team made several strategic crosses between disease-resistant and susceptible corn lines that let them map resistance traits to specific locations in the genome. For now, those regions are fairly large, comprising hundreds of individual genes. If there are specific genes with outsized effects, they haven’t been identified yet. 

Still, identifying important regions is helpful, as disease resistance rarely comes down to a single gene. In fact, the additive or quantitative power of multiple genes working together can mean more durable resistance. There’s a backup if a pathogen finds a way around a given resistance mechanism. Interestingly, this durability may even work against different groups of pathogens. 

“We found 19 regions associated with resistance to the bacterial disease Goss’s wilt. Several of those regions are also involved with resistance to fungal pathogens,” Jamann said. “Thus, it is possible to breed for resistance to several diseases at one time using the same genetic regions.”

Fungi and bacteria are very different biologically, but both have to find ways to get into the plant, travel throughout, and reproduce. Jamann says it’s possible that resistance genes trigger changes in the plant’s vasculature to make it harder for both kinds of pathogens to move around, but she still can’t say exactly how the genes help plants protect themselves. She’s working on it, though, thanks to a 2022 grant from the National Science Foundation.  

Although the team identified three corn lines with resistance to all four diseases, it will be a while before growers can purchase seed for multiple-resistant corn as a result of this work. First, Jamann’s team will fine-map the regions highlighted in this study to find any major-effect genes, then pass that information off to breeders who can develop hardy new hybrids. Still, Jamann says, multiple resistance is on its way.  

The study, “Identification of loci conferring resistance to four foliar diseases of maize,” is published in G3 Genes|Genomes|Genetics [DOI: 10.1093/g3journal/jkad275]. Authors include Yuting Qiu, Pragya Adhikari, Peter Balint-Kurti, and Tiffany Jamann. The research was supported by USDA Hatch Project ILLU-802-985 and the National Science Foundation under award no. 2154872. Any opinions, findings, conclusions, or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation.


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