Professor Peter Waterhouse and Dr Julia Bally have discovered a plant gene that could speed up plant genetics research and pave the way for growing food on a space station.
Credit: Erika Fish
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Magic plant discovery could lead to growing food in space
QUT scientists have discovered the gene that will open the door for space-based food production.
Professor Peter Waterhouse, a plant geneticist at QUT, discovered the gene in the ancient Australian native tobacco plant Nicotiana benthamiana, known as Pitjuri to indigenous Aboriginals tribes.
Professor Waterhouse made the discovery while tracing the history of the Pitjuri plant, which for decades has been used by geneticists as a model plant upon which to test viruses and vaccines.
“This plant is the ‘laboratory rat’ of the molecular plant world,” he said, “we think of it as a magical plant with amazing properties.
“We now know that in 1939 its seeds were sent by an Australian scientist to a scientist in America and have been passed from lab to lab all over the world.
“By sequencing its genome and looking through historical records we have been able to determine that the original plant came from the Granites area near the Western Australia and Northern Territory border, close to where Wolf Creek was filmed.
“We know, through using a molecular clock and fossil records, that this particular plant has survived in its current form in the wild for around 750,000 years.”
Lead researcher Dr Julia Bally said determining the exact species had led researchers on a quest to find out how the plant managed to survive in the wild for such a long period of time.
“What we found may have a big impact on future plant biotechnology research,” Dr Bally said.
“We have discovered that it is the plant equivalent of the nude mouse used in medical research.”
“The plant has lost its ‘immune system’ and has done that to focus its energies on being able to germinate and grow quickly, rapidly flower, and set seed after even a small amount of rainfall.
“Its focus is on creating small flowers but large seeds and on getting these seeds back into the soil in time for the next rain.
“The plant has worked out how to fight drought — its number one predator — in order to survive through generations.”
Professor Waterhouse, a molecular geneticist with QUT’s Centre for Tropical Crops and Biocommodities, said scientists could use this discovery to investigate other niche or sterile growing environments where plants were protected from disease — and space was an intriguing option.
“So the recent film The Martian, which involved an astronaut stranded on Mars growing potatoes while living in an artificial habitat, had a bit more science fact than fiction than people might think,” he said.
Professor Waterhouse said the team’s findings also have implications for future genetic research back here on Earth.
“Scientists can now know how to turn other species into ‘nude mice’ for research purposes. So just as nude mice can be really good models for cancer research, ‘nude’ versions of crop plants could also speed up agricultural research,” he said.
Professor Waterhouse said the fact that the N. benthamiana variety from central Australia had doubled its seed size also opened the door for investigations into how N. benthamiana could be used commercially as a biofactory, as seeds were an excellent place in which to make antibodies for pharmaceutical use.
Source : Queensland University of Technology