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Tropical wastelands to croplands with biotech
Posted by: Prof. Dr. M. Raupp (IP Logged)
Date: October 14, 2008 06:47PM
By Dennis T., Alex Avery
Imagine Africa feeding itself comfortably, instead of being overwhelmed by
its own expanding population.
Imagine millions of tropical consumers being fed without clearing more
forests, thus protecting the wildlife in the very regions where most of the
species of the world live and are critically threatened by population
pressure. Suddenly, high-yield conservation for the tropics may not be a
pipedream.
Half of the world's tropic croplands suffer from aluminum toxicity that
forces crop plants to shut down their growth. Grains and oilseeds produce
meager yields-and scientists haven't even known why. The resulting low
yields and food scarcity have stifled the tropics' efforts in health care,
technology, and economic growth. At the same time, tropical farmers have
been forced to clear more forest to grow enough food for their families
displacing the wild species that make the forests their home.
Now genetic engineering-and only genetic engineering-has found a potentially
massive food production breakthrough: crop plants that can ignore the
aluminum toxicity and produce ample yields on huge tracts of tropic land
that now produce little except stunted shrubs.
University of California/Riverside's Dr. Paul Larsen, while screening
mustard plants for their ability to grow despite toxic aluminum, discovered
a simple mutation to a single gene that lets plants thrive in spite of the
aluminum. He was able to shut down a gene called AtATR and the plants
ignored the toxic aluminum warnings from their roots.
"We have all these crop plants-wheat and corn and barley and so on-that
didn't evolve or get developed on aluminum-toxic soils," says Larsen. Plant
breeders have tried to cross-breed varieties that cope better with the
aluminum, but there has been little progress. Larsen's work dangles the
potential of a vast improvement, quickly. "It theoretically will eliminate
the big acid-soil yield penalties in any plant species," he says.
Larsen says the plants "are really worried about the long-term damage
aluminum toxicity could cause to their DNA over many generations." But that
thousand-year problem doesn't mean much when modern seeds can be bred-and
even grown out-on non-toxic soils and delivered to farms in the acid soil
regions. Larsen says even after growing five generations of his mutant
plants on aluminum-toxic soils, there are "no obvious deleterious effects on
growth, viability, [or] seed production."
The transformation itself is one of the simplest in biotechnology. The
scientists just block the gene that codes for aluminum sensitivity. No
foreign genes are added.
"It's a potential magic bullet, depending on how society decides to use it,"
says Larsen. "My dream is to see in my lifetime highly productive food crops
growing on soils that didn't use to be able to support them, so more poor
people can eat well. For that, it has massive potential. If we use (this
technology) instead to produce a bit more biofuel on cleared forest land-for
a huge fuel demand cropland can't meet-it could be terribly negative."
Larsen did his original experiments with Arabadopsis, an easily-manipulated
member of the mustard family. He's now seeking the funding to transform
tomatoes, and ultimately a whole range of food crops.
He also notes that other researchers have engineered plants that prevent
aluminum invasion by secreting citric acid from their roots. The
negatively-charged acid binds with the positively-charged aluminum so the
aluminum can't get into the roots. "We might combine my strategy of
by-passing the aluminum toxicity with the aluminum-blocking strategy to
create a family of tropical super-crops," he says.
Will this new breakthrough finally force the Green movement to recognize the
vital potential of biotechnology to both feed poor people and save wildlife
habitat?
Dennis T. Avery is a senior fellow for the Hudson Institute in Washington,
DC and is the Director for the Center for Global Food Issues. (www.cgfi.org)
Alex A. Avery is the Director of Research and Education for Hudson's Center
for Global Food Issues.
www.checkbiotech.org
Imagine Africa feeding itself comfortably, instead of being overwhelmed by
its own expanding population.
Imagine millions of tropical consumers being fed without clearing more
forests, thus protecting the wildlife in the very regions where most of the
species of the world live and are critically threatened by population
pressure. Suddenly, high-yield conservation for the tropics may not be a
pipedream.
Half of the world's tropic croplands suffer from aluminum toxicity that
forces crop plants to shut down their growth. Grains and oilseeds produce
meager yields-and scientists haven't even known why. The resulting low
yields and food scarcity have stifled the tropics' efforts in health care,
technology, and economic growth. At the same time, tropical farmers have
been forced to clear more forest to grow enough food for their families
displacing the wild species that make the forests their home.
Now genetic engineering-and only genetic engineering-has found a potentially
massive food production breakthrough: crop plants that can ignore the
aluminum toxicity and produce ample yields on huge tracts of tropic land
that now produce little except stunted shrubs.
University of California/Riverside's Dr. Paul Larsen, while screening
mustard plants for their ability to grow despite toxic aluminum, discovered
a simple mutation to a single gene that lets plants thrive in spite of the
aluminum. He was able to shut down a gene called AtATR and the plants
ignored the toxic aluminum warnings from their roots.
"We have all these crop plants-wheat and corn and barley and so on-that
didn't evolve or get developed on aluminum-toxic soils," says Larsen. Plant
breeders have tried to cross-breed varieties that cope better with the
aluminum, but there has been little progress. Larsen's work dangles the
potential of a vast improvement, quickly. "It theoretically will eliminate
the big acid-soil yield penalties in any plant species," he says.
Larsen says the plants "are really worried about the long-term damage
aluminum toxicity could cause to their DNA over many generations." But that
thousand-year problem doesn't mean much when modern seeds can be bred-and
even grown out-on non-toxic soils and delivered to farms in the acid soil
regions. Larsen says even after growing five generations of his mutant
plants on aluminum-toxic soils, there are "no obvious deleterious effects on
growth, viability, [or] seed production."
The transformation itself is one of the simplest in biotechnology. The
scientists just block the gene that codes for aluminum sensitivity. No
foreign genes are added.
"It's a potential magic bullet, depending on how society decides to use it,"
says Larsen. "My dream is to see in my lifetime highly productive food crops
growing on soils that didn't use to be able to support them, so more poor
people can eat well. For that, it has massive potential. If we use (this
technology) instead to produce a bit more biofuel on cleared forest land-for
a huge fuel demand cropland can't meet-it could be terribly negative."
Larsen did his original experiments with Arabadopsis, an easily-manipulated
member of the mustard family. He's now seeking the funding to transform
tomatoes, and ultimately a whole range of food crops.
He also notes that other researchers have engineered plants that prevent
aluminum invasion by secreting citric acid from their roots. The
negatively-charged acid binds with the positively-charged aluminum so the
aluminum can't get into the roots. "We might combine my strategy of
by-passing the aluminum toxicity with the aluminum-blocking strategy to
create a family of tropical super-crops," he says.
Will this new breakthrough finally force the Green movement to recognize the
vital potential of biotechnology to both feed poor people and save wildlife
habitat?
Dennis T. Avery is a senior fellow for the Hudson Institute in Washington,
DC and is the Director for the Center for Global Food Issues. (www.cgfi.org)
Alex A. Avery is the Director of Research and Education for Hudson's Center
for Global Food Issues.
www.checkbiotech.org
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