Barley Genome Sequenced

Apr 27, 2017
Barley is one of the world's most important cereal crops.
 
Looking for a better beer or single malt Scotch whiskey?
 
A team of researchers at the University of California, Riverside may have you covered. They are among a group of 77 scientists worldwide who have sequenced the complete genome of barley, a key ingredient in beer and single malt Scotch. The research, 10 years in the making, was just published in the journal Nature.
 
"This takes the level of completeness of the barley genome up a huge notch," said Timothy Close, a professor of genetics at UC Riverside. "It makes it much easier for researchers working with barley to be focused on attainable objectives, ranging from new variety development through breeding to mechanistic studies of genes."
 
The research will also aid scientists working with other "cereal crops," including rice, wheat, rye, maize, millet, sorghum, oats and even turfgrass, which like the other food crops, is in the grass family, Close said.
 
Barley has been used for more than 10,000 years as a staple food and for fermented beverages, and as animal feed.
 
It is found in breakfast cereals and all-purpose flour and helps bread rise. Malted barley gives beer color, body, protein to form a good head, and the natural sugars needed for fermentation. And single malt Scotch is made from only water and malted barley.
 
The report in Nature provides new insights into gene families that are key to the malting process. The barley genome sequence also enabled the identification of regions of the genome that have been vulnerable to genetic bottlenecking during domestication, knowledge that helps to guide breeders to optimize genetic diversity in their crop improvement efforts.
 
Ten years ago, the International Barley Genome Sequencing Consortium, which is led by Nils Stein of the Leibniz Institute of Plant Genetics and Crop Plant Research in Germany, set out to assemble a complete reference sequence of the barley genome.
 
This was a daunting task, as the barley genome is almost twice the size of the human genome and 80 percent of it is composed of highly repetitive sequences, which cannot be assigned accurately to specific positions in the genome without considerable extra effort.
 
Multiple novel strategies were used in this paper to circumvent this fundamental limitation. Major advances in sequencing technology, algorithmic design and computing made it possible. Still, this work kept teams around the world - in Germany, Australia, China, Czech Republic, Denmark, Finland, Sweden, Switzerland, United Kingdom and the United State - occupied for a decade. This work provides knowledge of more than 39,000 barley genes.
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