RALEIGH, N.C. — North Carolina State University research intended to extend the “vase life” of roses inserts a gene from celery inside rose plants to help fight off botrytis, or petal blight, one of the rose’s major post-harvest diseases.
Some fungal pathogens, the bad guys that infect plants, produce a sugar alcohol called mannitol that interferes with the plant’s ability to block disease like petal blight, which produces wilty, mushy petals — an effect similar to what happens to lettuce when it’s been in the crisper too long.
In an effort to make roses live longer, N.C. State horticultural scientists John Dole and John Williamson lead an effort to insert a gene called mannitol dehydrogenase from celery into roses to “chew up” mannitol and allow the plant to defend itself from one of its greatest threats.
“This gene is naturally found in many plants, but it’s uncertain whether the rose already has it,” Williamson says. “If it does, it doesn’t produce enough enzyme to help the plant fight against petal blight.”
The genetically modified roses currently growing in N.C. State test beds look and smell like “normal” roses. Now the roses will be tested to see whether they’re better able to withstand petal blight.
The research is just one part of an extensive N.C. State effort to build a better rose, Dole says. Other research thrusts include examining the types of sugars best suited for mixture with water to keep the plants thriving after they’ve been harvested; studying the variance in water quality across the country to see which water provides the best home for roses after they’ve been cut; and preventing various other important plant diseases.
The ultimate goal is to get roses to survive for three to four weeks after they’ve been harvested, Dole adds. Many of the roses in florists and grocery stores come from Colombia and Ecuador, so the longer shipping times can reduce vase life after purchase.
Other N.C. State project collaborators include Bryon Sosinski, who is working on identifying other resistance genes in the rose that could provide additional resistance to other environmental factors, and George Allen and Sergei Krasnyanski, who insert the genes of interest into rose plants.
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