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Researchers developing new science-based crops, experts say
Posted by: Prof. Dr. M. Raupp (IP Logged)
Date: February 14, 2007 09:19AM
www.checkbiotech.org ; www.raupp.info ; www.czu.cz
Agricultural biotechnology research being conducted around the world is
leading to the development of new crops that will help fight human diseases
and increase productivity in cropland that is stressed due to such
conditions as drought and poor soil, February 2007 by Kathryn McConnell.
The research holds immense promise, especially for the developing world,
according to several scientists interviewed by USINFO.
Continuing improvements in biotechnologies are contributing to the
development of "functional foods" -- those with components associated with
the prevention or treatment of diabetes, cardiovascular disease,
hypertension, arthritis and improved mental alertness, said Martina
Newell-McGloughlin, director of the University of California?s biotechnology
research and education program.
Plants are being modified to deliver anti-oxidants, which protect against
cancer; lipids, which contain essential fatty acids that serve as energy
sources; vitamins, such as beta-carotene or vitamin A, which protect against
premature blindness and susceptibility to other illnesses; and iron, whose
deficiency results in fatigue and decreased immunity, she said.
Bananas and tomatoes are being engineered to deliver, among other things,
antibodies for E. coli bacteria-induced diarrhea, a major killer of children
around the world. Other plants are being engineered to counteract allergies,
Newell-McGloughlin said.
The first crops derived from biotechnology, or genetic modification, were
modified to be insect-resistant and herbicide-tolerant, which led to
increases in production, according to Bruce Chassy, executive associate
director of the University of Illinois? biotechnology center.
Research that began approximately 15 years ago on these and other traits in
a variety of crops continues today in laboratories around the world.
So far, the United States has approved more than 70 genetically modified
crops. These crops, which can be grown commercially, include canola, papaya,
potato, rice, squash, sugar beets, tomato and tobacco, which is used to help
produce a vaccine that fights against a type of lymphoma, said
Newell-McGloughlin.
The latest biotech crop commercialized in the United States was alfalfa, a
feed crop, which entered the market in 2006, according to Wayne Parrott,
professor of crop and soil sciences at the University of Georgia.
The first African-engineered crop to go into field trials is a type of maize
resistant to a devastating virus, Parrott said. It is expected to be planted
in 2007.
China, India, Indonesia, the Philippines, Canada, Argentina, Brazil and
South America are among countries at the forefront of research, the
scientists said. Biotech crops are being grown commercially in 22 countries.
Research is being directed to making already healthy foods, such as
protein-rich soy and soy oil with low or no saturated fats, taste better to
consumers, Chassy said.
Also being developed are bioengineered trees capable of absorbing harmful
chemicals from the soil and plants that can be converted into plastics and
industrial products, he said.
More research is being directed to plants such as cassava and sorghum that
are consumed mostly in developing countries but not in countries where most
biotech research has been taking place, the scientists said.
Another area of research is plants that can be grown productively in such
harsh conditions as drought, salty or acidic soil, and cold, and to resist
viruses and fungi, Parrott said.
Making more crops able to grow in current nonarable conditions could
contribute to food security and help promote sustainable agriculture, the
scientists said.
At the International Rice Research Institute (IRRI) in the Philippines,
researchers are developing plants that are "phytosynthetically more
efficient." These have more leaf surface exposed to the sun, making the
leaves more efficient in converting carbon to energy for higher yields,
according to Carlos Quiros, a professor and geneticist at the University of
California-Davis.
"Farmers now realize they have an economic and commercial advantage"
planting biotech seeds that produce crops that are easier to grow, have
greater harvests and various uses, Quiros said.
Although considerable research is being conducted by governments,
international organizations, foundations, companies and academic
institutions, few new products are being commercialized, the scientists
said.
They explained that the many, separate country regulatory and patent dispute
processes that often are lengthy and costly discourage commercial
production. Several of the researchers called for a worldwide regulatory
regime.
Also affecting the pace of commercialization is resistance from some
consumers to accept that bioengineered foods have been proven to be safe,
the scientists said.
Yet, said Chassy, "We are breeding plants that are safer than those from
conventional breeding."
[usinfo.state.gov]
Agricultural biotechnology research being conducted around the world is
leading to the development of new crops that will help fight human diseases
and increase productivity in cropland that is stressed due to such
conditions as drought and poor soil, February 2007 by Kathryn McConnell.
The research holds immense promise, especially for the developing world,
according to several scientists interviewed by USINFO.
Continuing improvements in biotechnologies are contributing to the
development of "functional foods" -- those with components associated with
the prevention or treatment of diabetes, cardiovascular disease,
hypertension, arthritis and improved mental alertness, said Martina
Newell-McGloughlin, director of the University of California?s biotechnology
research and education program.
Plants are being modified to deliver anti-oxidants, which protect against
cancer; lipids, which contain essential fatty acids that serve as energy
sources; vitamins, such as beta-carotene or vitamin A, which protect against
premature blindness and susceptibility to other illnesses; and iron, whose
deficiency results in fatigue and decreased immunity, she said.
Bananas and tomatoes are being engineered to deliver, among other things,
antibodies for E. coli bacteria-induced diarrhea, a major killer of children
around the world. Other plants are being engineered to counteract allergies,
Newell-McGloughlin said.
The first crops derived from biotechnology, or genetic modification, were
modified to be insect-resistant and herbicide-tolerant, which led to
increases in production, according to Bruce Chassy, executive associate
director of the University of Illinois? biotechnology center.
Research that began approximately 15 years ago on these and other traits in
a variety of crops continues today in laboratories around the world.
So far, the United States has approved more than 70 genetically modified
crops. These crops, which can be grown commercially, include canola, papaya,
potato, rice, squash, sugar beets, tomato and tobacco, which is used to help
produce a vaccine that fights against a type of lymphoma, said
Newell-McGloughlin.
The latest biotech crop commercialized in the United States was alfalfa, a
feed crop, which entered the market in 2006, according to Wayne Parrott,
professor of crop and soil sciences at the University of Georgia.
The first African-engineered crop to go into field trials is a type of maize
resistant to a devastating virus, Parrott said. It is expected to be planted
in 2007.
China, India, Indonesia, the Philippines, Canada, Argentina, Brazil and
South America are among countries at the forefront of research, the
scientists said. Biotech crops are being grown commercially in 22 countries.
Research is being directed to making already healthy foods, such as
protein-rich soy and soy oil with low or no saturated fats, taste better to
consumers, Chassy said.
Also being developed are bioengineered trees capable of absorbing harmful
chemicals from the soil and plants that can be converted into plastics and
industrial products, he said.
More research is being directed to plants such as cassava and sorghum that
are consumed mostly in developing countries but not in countries where most
biotech research has been taking place, the scientists said.
Another area of research is plants that can be grown productively in such
harsh conditions as drought, salty or acidic soil, and cold, and to resist
viruses and fungi, Parrott said.
Making more crops able to grow in current nonarable conditions could
contribute to food security and help promote sustainable agriculture, the
scientists said.
At the International Rice Research Institute (IRRI) in the Philippines,
researchers are developing plants that are "phytosynthetically more
efficient." These have more leaf surface exposed to the sun, making the
leaves more efficient in converting carbon to energy for higher yields,
according to Carlos Quiros, a professor and geneticist at the University of
California-Davis.
"Farmers now realize they have an economic and commercial advantage"
planting biotech seeds that produce crops that are easier to grow, have
greater harvests and various uses, Quiros said.
Although considerable research is being conducted by governments,
international organizations, foundations, companies and academic
institutions, few new products are being commercialized, the scientists
said.
They explained that the many, separate country regulatory and patent dispute
processes that often are lengthy and costly discourage commercial
production. Several of the researchers called for a worldwide regulatory
regime.
Also affecting the pace of commercialization is resistance from some
consumers to accept that bioengineered foods have been proven to be safe,
the scientists said.
Yet, said Chassy, "We are breeding plants that are safer than those from
conventional breeding."
[usinfo.state.gov]
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