DNA rice breakthrough raises ‘green revolution’ hopes
Los Baños, Philippines: Rice-growing techniques learned through thousands of years of trial and error are about to be turbocharged with DNA technology in a breakthrough hailed by scientists as a potential second ‘green revolution’.
Over the next few years farmers are expected to have new genome sequencing technology at their disposal, helping to offset a myriad of problems that threaten to curtail production of the grain that feeds half of humanity.
Drawing on a massive bank of varieties stored in the Philippines and state-of-the-art Chinese technology, scientists recently completed the DNA sequencing of more than 3,000 of the world’s most significant types of rice.
With the huge pool of data unlocked, rice breeders will soon be able to produce higher-yielding varieties much more quickly and under increasingly stressful conditions, scientists involved with the project told AFP.
Other potential new varieties being dreamt about are ones that are resistant to certain pests and diseases, or types that pack more nutrients and vitamins.
‘This will be a big help to strengthen food security for rice eaters,’ said Kenneth McNally, an American biochemist at the Philippines-based International Rice Research Institute (IRRI).
Since rice was first domesticated thousands of years ago, farmers have improved yields through various planting techniques.
For the past century breeders have isolated traits, such as high yields and disease resistance, then developed them through cross breeding.
However, they did not know which genes controlled which traits, leaving much of the effort to lengthy guesswork.
The latest breakthroughs in molecular genetics promise to fast-track the process, eliminating much of the mystery, scientists involved in the project told AFP.
Better rice varieties can now be expected to be developed and passed on to farmers’ hands in less than three years, compared with 12 without the guidance of DNA sequencing.
Genome sequencing involves decoding DNA, the hereditary material of all living cells and organisms. The process roughly compares with solving a giant jigsaw puzzle made up of billions of microscopic pieces.
A multinational team undertook the four-year project with the DNA decoding primarily in China by BGI, the world’s biggest genome sequencing firm.
Leaf tissue from the samples, drawn mostly from IRRI’s gene bank of 127,000 varieties were ground by McNally’s team at its laboratory in Los Banos, near Manila’s southern outskirts, before being shipped for sequencing.
A non-profit research outfit founded in 1960, IRRI works with governments to develop advanced varieties of the grain.
Threats to rice
Farmers and breeders will need the new DNA tools, which scientists take pains to say is not genetic modification, because of the increasingly stressful conditions for rice growing expected in the 21st Century.
While there will be many more millions to feed, there is expected to be less land available for planting as farms are converted for urban development, destroyed by rising sea levels or converted to other crops.
Rice-paddy destroying floods, drought and storms are also expected to worsen with climate change. Meanwhile, pests and diseases that evolve to resist herbicides and pesticides will be more difficult to kill.
And fresh water, vital for growing rice, is expected to become an increasingly scarce commodity in many parts of the world.
As scientists develop the tools necessary to harness the full advantages of the rice genome database, the hope is that new varieties can be developed to combat all those problems.
‘Essentially, you will be able to design what properties you want in rice, in terms of the drought resistance, resistance to diseases, high yields, and others,’ said Russian bioanalytics expert and IRRI team member Nickolai Alexandrov.
Scientists behind the project hope it will lead to a second ‘green revolution’.
The first began in the 1960s as the development of higher-yielding varieties of wheat and rice was credited with preventing massive global food shortages around the world.
That giant leap to producing more food involved the cross-breeding of unrelated varieties to produce new ones that grew faster and produced higher yields, mainly by being able to respond better to fertiliser.