We've cracked wheat's genetic code: Scientists
London: British scientists have decoded the genetic sequence of wheat — one of the world's oldest and most important crops — a development they hope could help the global staple meet the challenges of climate change, disease and population growth.
Wheat is grown across more of the world's farmland than any other cereal, and researchers said Friday they're posting its genetic code to the Internet in the hope that scientists can use it as a tool to improve farmers' harvests. One academic in the field called the discovery "a landmark."
"The wheat genome is the holy grail of plant genomes," said Nick Talbot, a professor of biosciences at the University of Exeter who wasn't involved in the research. "It's going to really revolutionize how we breed it."
University of Liverpool scientist Neil Hall, whose team cracked the code, said the information could eventually help breeders of varieties of wheat better identify genetic variations responsible for disease resistance, drought tolerance and yield. Although the genetic sequence remains a rough draft, and additional strains of wheat need to be analyzed for the work to be useful, Hall predicted it wouldn't take long for his work to make an impact in the field.
"Hopefully the benefit of this work will come through in the next five years," he said.
A genome is the full complement of an organism's DNA, complex molecules which direct the formation and function of all living organisms. Sequencing an organism's genome, gives unparalleled insight into how it is formed, develops and dies.
Wheat is a relative latecomer to the world of genetic sequencing. This year marks the 10th anniversary of the date the human genome was laid bare. Other crops have had their genetic codes unscrambled within the past few years — rice in 2005, corn in 2009, and soybeans earlier this year.
The reason for the delay in analyzing wheat's genetic code, Hall said, was that the code is massive — far larger than corn or rice and five times the length of the one carried by humans.
One reason for the outsize genome is that strains such as the Chinese spring wheat analyzed by Hall's team carry six copies of the same gene (most creatures carry two.) Another is that wheat has a tangled ancestry, tracing its descent from three different species of wild grass.
But sequencing techniques have improved dramatically over the past decade. The process used in this case is called pyrosequencing, a technique which involves extracting DNA, suspending it in fluid, breaking it apart with bursts of gas and using chemical reactions and a high-resolution camera to infer its makeup.
Hall said the machine used enabled his team to analyze a million strands of DNA at a time. The whole process took about a year to complete.
Although the code may yet see use by genetic engineers hoping to craft artificial strains of wheat, Hall was at pains to stress the conventional applications of his work. Until now, breeders seeking to combine the best traits of two strains of wheat would cross the pair, grow the hybrid crop and hope for the best.
Although the process has been used by farmers since wheat was first cultivated 10,000 years ago, Talbot described it as laborious and inefficient.
"Very often we were talking about 10-15 years of intensive breeding programs," he said. "We're talking now about doing things in less than five."
Talbot noted that rice cultivation had already benefited from the publication of its genetic code — and led to the development of vitamin-enriched and drought-resistant strains. He said that his own field of specialty, the study of the destructive rice blast fungus, had been revolutionized as a result of having the genome sequence.
The cracking of wheat's code comes at a time when prices have shot up in the wake of crop failures in Russia, highlighting how the vagaries of world food production can hit import-dependent countries such as Egypt.
Concerns over climate change, water shortages and population growth have loomed in the background for years. New risks include a mutant form of stem rust. The reddish, wind-borne fungus — known to scientists as Ug99 — has devastated wheat crops in places such as Kenya, where up to 80 percent of the wheat in afflicted farmers' fields have been ruined.