DNA Markers Could Keep Potatoes Fresher for Longer

EU-funded scientists have discovered genetic markers that could allow potatoes to be selected for their ability to be stored at low temperatures, keep

Published online: Feb 15, 2018 Articles, Potato Storage, Seed Potatoes
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Source: Community Research and Development Information Service

Ireland is world-renowned for producing potatoes, but Irish crisp and chip manufacturers face a shortage of locally grown potatoes, mainly due to long-term tuber storage problems. This means they need to import over 50,000 metric tons of potatoes each year.

Potatoes used for crisps and chips are usually stored at 8 degrees Celsius (46.4 degrees Fahrenheit)—a temperature high enough to prevent starch from breaking down into glucose and fructose. To slow sprouting, potato producers often use a suppressant like chlorpropham, a chemical the EU is looking to phase out due to health concerns.

Hoping to find an alternative to chemical sprout suppressors, the EU-funded Genomic Selection for Potato Improvement (GENSPI) project has developed a genetic marker system to identify plants that display a resistance to glucose and fructose formation. Their tubers can be stored at low enough temperatures to keep sprout growth at bay for very long periods.

“Glucose and fructose formed during cold storage can cause very dark fry colors, leaving potato crisps and chips with an unacceptably bitter taste,” says Dan Milbourne, GENSPI project coordinator. The sugars can also cause a buildup of acrylamide, a potential carcinogen.”

 

Slower to Sweeten

GENSPI developed new genomic selection breeding methodologies that will allow potato breeders to select the varieties of potato that seem to be resistant to sweetening at low temperatures.

To do this, researchers gathered a large collection of potato plants and fried thousands of tubers—the equivalent to 10,000 bags of potato crisps—that had been held in different storage conditions. They then measured their color once fried and drew the links between fry color and the genetic variation of the plant.

“Because the fry color is controlled by many genes, the best approach was to scan the genome for variation at many sites to find correlations between color and genetic variation,” says Milbourne.

Researchers then used the latest techniques in genome sequences—known as next-generation sequencing—to identify over 100,000 regions across the genome where the DNA sequence varied among the plants. They combined data on variation on the potato phenotype and genome to build statistical models that could predict fry color from DNA sequencing information.

“From the 100,000 regions showing genetic variation between the breeding lines, we were able to identify a smaller number of DNA markers that gave us a good ability to predict fry color,” says Stephen Byrne, the Marie Sklodowska-Curie fellow who carried out the research. “This means we can develop an inexpensive, DNA-based test to predict fry color that can be applied to tens of thousands of plants in a potato breeding program.”

Traditionally, potato breeders inter-cross plant varieties to produce up to 100,000 seedlings, and then eliminate poor-performing plant types over a period of 10 years. Varieties that are resistant to glucose and fructose formation can only be identified at the end of this time, meaning that many potential varieties have already been eliminated from the breeding process.

GENSPI carried out its research in collaboration with a commercial potato breeding program led by Denis Griffin. Its newly developed technique allows resistant plants to be identified early in the 10-year breeding program. The team hopes the project will lead to the release of one or more varieties that give an excellent fry color even at low-temperature storage, avoiding chemical sprout suppressants.

“We hope to see these varieties released in the next five years,” says Griffin.