Protecting food crops from powdery mildew

Mar 4, 2014

It looks harmless enough – a light dusting like baby powder sprinkled on the leaves. But powdery mildew can attack new buds and shoots, stunt growth and distort plant development. If not controlled, the fast spreading fungus can cause billions of dollars of crop damage in California. For example, powdery mildew is the most significant disease affecting grapes in California, with all productive acreage treated to help minimize loss. Borne by the wind, its spores race through fields and can easily damage a season's crop, resulting in losses of 30 percent or more.

Growers combat powdery mildew with sulfur, fungicides, and other deterrents, but treatment is costly, and timing is difficult. But a much more precise strategy may be on the way.

Mary Wildermuth in her lab at UC Berkeley. PHOTO: Peg Skorpinski
Mary Wildermuth in her lab at UC Berkeley. (Photo: Peg Skorpinski)
Using highly refined dissection of infected plant cells, coupled with genetic analysis, UC Berkeley plant and microbial biology associate professor Mary Wildermuth identified genes critical to a plant's response to mildew attack. Her research focuses on a plant breeding strategies that can weaken powdery mildew's grip.

With the funding from UC Berkeley's Bakar Fellows Program, which supports early-career faculty conducting commercially promising research, Wildermuth is applying her discoveries to protect commercially valuable crops. She uses a plant in the mustard family popular with researchers for it small, sequenced gene and a short life cycle.

“We've already identified the parallel genes in a number of important crops,” she said. “By targeted breeding to limit these genes' powdery mildew-promoting effects, we should be able to protect plants without extensive chemical treatments.”

When powdery mildew spores land on a leaf, the spore germinates and bores through the leaf surface to make a lobe-shaped feeding structure. The fungus also influences nearby plant cells, manipulating the leaf cell physiology to gain nutrients. A high nutrient supply is needed to support the large fungal network on the leaf surface and the formation of new spores, which propagate the infection.

Wildermuth's lab used a highly refined technique under an optical microscope to scrutinize the fungus-plant interaction and focus in on the plant cell housing the fungal feeding structure and the neighboring leaf cells.

"We can see these cells under the microscope and use the laser to cut them out. The dissected cells literally drop into a tube below," she said. "It's quite fun to do."

The research team isolated the cells and extracted the RNA. They then determined which genes are turned on and which are turned off in specific cells at the infection site versus uninfected cells. They zeroed in on genes likely to be critical to the infection process, and used plants in which these genes were knocked out in order to see if the plants respond differently to powdery mildew. 

The lab identified a set of genes that actually help the mildew fungus steal more food from the plant. The process, called endo-reduplication, allows cells in the leaf to increase production of DNA without dividing – one of the few ways cells can increase their metabolism and size, Wildermuth says.

“The fungus induces endo-reduplication in the plant cells underneath the feeding structure, and gains access to more nutrients in the leaf.” This, in turn, spurs fungal growth and reproduction. “We showed that if the DNA-enhancing process is blocked, the fungus gets put on a diet, and its proliferation is limited,” she says. 

The Bakar Fellowship supports her current effort to determine whether similar genes in grapes, tomatoes and other crops threatened by powdery mildew can be targeted to limit the fungus's growth. Crop strains in which these genes are less active or even absent could be selectively bred to thwart fungal growth.


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