Annotated
Bibliography Entry
Reference:
Pew 2001
Title: Harvest on the Horizon: Future Uses of Agricultural Biotechnology
Authors: Pew Initiative on Food and Biotechnology
Publisher: Pew Initiative on Food and Biotechnology, 1331 H Street, Suite 900,
Washington, DC 20009 USA
Publication details: September
2001, 106p.
Summary
The Context of Biotechnology
Food Crops
Trees,
Turf and Decorative Plants
Biotech
Industrial Products, Pharmaceuticals and Environmental Clean-up
Animals
Fish
and Aquatic Organisms
Insects
Conclusion
Table of Contents
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Summary
The
increasing use of modern biotechnology in agriculture has generated
significant debate, much of which centers on the rapidly growing use of food
crops that have been genetically modified to make them more resistant to pests
or chemical herbicides. As a result, the debate has not usually addressed the
potential products of agricultural biotechnology that are on the horizon.
While technology developers believe that these new products will offer
benefits in meeting needs for food, fuel and fiber, as well as for novel
industrial and pharmaceutical uses, some of these future products are also
likely to raise environmental and other concerns that will need to be
addressed by the regulatory system.
Harvest
on the Horizon: Future Uses of Agricultural Biotechnology is
intended to enrich both the knowledge and dialogue surrounding agricultural
biotechnology by profiling some of the genetically engineered products being
developed by industry and university scientists. The report reviews some of
the current research on largescale crops like corn and soybeans, but it also
outlines ongoing research on a much broader range of plants, trees, grasses,
animals, insects and fish. While not a comprehensive inventory, Harvest on
the Horizon reveals the breadth and scope of current research activities
and gives a snapshot of how industry and university researchers are thinking
about potential future agricultural biotechnology products.
The
report should not be viewed as an endorsement of biotechnology or any of the
potential future applications discussed. Indeed, many of the applications
noted in the report are likely to generate strong public debate over their
relative risks and benefits. The report deliberately does not address these
policy issues in order to provide a clear picture of the breadth of current
agricultural biotechnology research and development efforts, an understanding
of which is also critical to the public debate.
Nor
should the report be construed as a forecast of which products will be
successful and brought to market. Much of the research cited is at an early
stage, and many of the applications
face significant technical, economic, marketing and regulatory challenges
before they can be commercialized. This report does not attempt to delve into
those challenges. Instead, Harvest on the Horizon simply focuses on the
research underway to use agricultural biotechnology to create new products. By
demonstrating what could be the “next generation" of products created
from agricultural biotechnology, the Pew Initiative on Food and Biotechnology
hopes to facilitate and enhance the ongoing public debate about this
technology.
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The
Context of Biotechnology
While
biotechnology falls within the tradition of improving crops and livestock to
better meet human needs, it also greatly expands the ability to move genes
within and across species and creates a new ability to move genes across
distantly related species and biologic kingdoms. It is this attribute of
biotechnology that makes it a potentially powerful tool for modifying nature
but which also raises ethical, health, and environmental issues.
While
the public is not widely knowledgeable about biotechnology and genetically
modified food, consumer awareness appears to be growing. When the Pew
Initiative on Food and Biotechnology compared the findings of two polls,
respectively conducted in January 2001 and June 2001, it found consumer
awareness of genetically modified foods sold in grocery stores had increased
by 11 percent between the polls.
At
the same time, use of the technology is also increasing in American fields,
with farmers planting more genetically modified soybeans and cotton this year,
according to a recent U.S. Department of Agriculture survey. The government's
report also notes that currently 68 percent of soybean acreage, 69 percent of
all cotton acreage, and 26 percent of total corn acreage planted is
genetically modified.
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Food Crops
Making
Food Production Easier
To
date, much of the focus of industry research has been on the development of
products to reduce crop losses to pests and disease while maintaining yields.
The first applications of biotechnology, now on the market for several years,
include staple crops such as corn and cotton that are bioengineered to make
toxins capable of killing insect pests. Other crops such as squash, potatoes,
wheat, papaya and raspberries, engineered to resist
common plant diseases, have recently become commercially available or
may soon reach the market. Genetically modified soybeans, corn, canola and
cotton have been developed with resistance to the herbicide glyphosate and are
widely used in the United States. Scientists are continuing to work on other
methods to directly improve crop yields and on ways to help crops grow in
difficult environments such as those that have limited water supplies or soils
that lack nutrients.
Food Quality and
Nutrition
Improving
crop yields and reducing crop losses to pests are important to farmers, but
they do not necessarily deliver obvious benefits to consumers. Biotechnology
research is proceeding on ways to develop products with direct benefits to
consumers, such as improved food quality and nutrition. In particular,
scientists are using biotechnology to add nutrients to foods traditionally
lacking in those nutrients. For example, research is ongoing on ways to add
vitamin A to rice, a staple part of the diet in developing countries, to
increase the nutritional quality of diets in these regions.
Similar
research is being undertaken to add vitamin E, an anti-oxidant thought to
prevent cancer, to vegetable oils; to reduce the harmful saturated fats of
cooking oils; to increase protein quality in vegetable staples; and to reduce
the allergenic properties of milk, heat, and other products to make them
available to those who are ordinarily sensitive to them. The report does not
address the likelihood that these products will be as beneficial as some
proponents believe, an issue of current policy debate.
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Trees,
Turf and Decorative Plants
The
applications of biotechnology in agriculture are not limited to food and feed
crops: some research on forestry and trees is currently underway. Researchers
are exploring ways to make trees grow more quickly and to be more disease and
stress resistant. For example, scientists are working on changing the amount
of a tree's lignin—a substance that helps provide rigidity. Reducing lignin
could improve the ease and efficiency of processing trees into paper.
Alternatively, increasing lignin content could be desirable for lumber and
could possibly provide advantages for energy production when wood is used as
fuel. Again, the report does not discuss any of the ethical and environmental
issues that have been raised about some potential applications of this
research.
Genetic
engineering is also being applied to the recovery of tree species threatened
by disease. The American chestnut is a hardwood tree formerly common in
Appalachia and the East Coast that was destroyed by a blight that killed 3.5
billion trees—all during the first 40 years of the 20th century. The
discovery of genes responsible for resistance to the fungus in a few surviving
trees may make it possible to develop resistance in genetically modified
American chestnut trees.
Turf
commonly found on golf courses and also used in commercial landscaping
requires enormous quantities of water, herbicides and pesticides to preserve
its appearance and functional quality. Industry researchers are working to
genetically engineer grass to resist herbicides that may allow for better weed
control. In the more aesthetic arena, researchers are looking to engineer
flowers and potted plants to have different shades of color and intensity than
would normally be found in nature, and are investigating ways to change their
size and shape (e.g. dwarf plants). Biotechnology techniques may also be able
to extend the shelf life of cut flowers.
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Biotech
Industrial Products, Pharmaceuticals and Environmental Clean-up
Researchers
are using biotechnology to modify plants to produce industrial products and
pharmaceuticals. Examples of products currently under development include:
proteins and enzymes for diagnostic, therapeutic and manufacturing purposes;
modified fatty acids and oils for paints and manufacturing; biopolymers as
substitutes for plastics; and specialty substances. One potential product that
is currently being explored is the creation of fibers for clothing and other
materials. Using bacteria engineered to make polymers that closely resemble
natural fibers (such as silk, elastin, collagen and keratin), it may be
possible to produce unique fibers similar to some of the most popular textiles
used in the production of the latest fashions.
Plants
and animals can also be modified to act as biosensors, detecting or monitoring
hazardous materials in the environment. For example, researchers have modified
bacteria
Scientists
are working on ways to use biotechnology for environmental preservation and
remediation. For example, scientists are working with a number of plant
species to enhance their natural ability to absorb and store toxic and
hazardous substances that could assist in the cleanup of oil spills and
chemical leaks. Scientists have found that genetically modified plants can
produce vaccines for human and animal illnesses ranging from colon cancer to
traveler's diarrhea to tooth decay. Technology developers believe that using
foods to deliver vaccines could have the benefit of permitting the vaccine to
be consumed directly by humans or animals as food or feed, and eliminating the
need for purification of the vaccine strain and the hazards associated with
injections. Some of the plants used to develop the vaccines include corn,
spinach, tobacco, lettuce, tomato, soybeans and potatoes. Plants may also be
used to produce medical compounds for use in
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Animals
In
addition to research on plants that can produce human medical treatments,
scientists are also investigating ways to bioengineer animals to produce human
medical treatments for disorders or diseases such as cystic fibrosis. There
are efforts underway to modify sheep to be able to produce fibrinogen, a major
component in blood clotting that may be used for wound treatment. Scientists
are also using genetic engineering to try to use animal tissue and organs for
transplantation into humans. But with biotechnology, researchers may be able
to genetically modify pigs to suppress a natural protein that causes the
animal's tissue or organs to be rejected in humans. Harvest on the Horizon does
not address any of the animal welfare, ethical or other policy issues that
have been raised with respect to biotechnology research on animals.
Another
area of animal research is the production of spider silk from genetically
modified goats. Spider silk, an ultra-strong material that can be used in a
variety of industrial products, including sutures and bulletproof vests, is
difficult to cultivate commercially. Industry researchers are now able to
produce spider silk by harvesting protein from the milk of goats engineered
with a spider gene.
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Fish and Aquatic
Organisms
According
to the UN's Food and Agriculture Organization (FAO), close to 100 billion tons
of fish are annually consumed worldwide. It is, therefore, not surprising that
researchers have focused on using biotechnology to increase yields for the
production of salmon and other fish. For example, the U.S. Food and Drug
Administration (FDA) is currently reviewing an application for a genetically
modified salmon that grows at three to five times the rate of its unmodified
counterpart.
At
least nine species of fish—none of which are commercially available
yet—have been genetically modified for enhanced growth including: the common
carp, Crucian carp, channel catfish, loach, tilapia, pike, rainbow trout,
Atlantic salmon, Pacific salmon and Sockeye salmon. The possible ecological
issues raised by the unintended introduction of a genetically modified fish
into the environment are beyond the scope of this report.
Because
diseases can spread rapidly in aquaculture with potentially devastating
economic consequences, scientists are investigating techniques to protect fish
and seafood from such diseases by improving disease resistance. In addition,
by modifying salmon for tolerance to sub-freezing temperatures, the geographic
range where caged salmon could be farmed could be extended.
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Insects
Looking
at efforts to control insect devastation, researchers are investigating
alternatives
One
area of research has centered on reducing the ability of mosquitoes to spread
disease, such as malaria. The ability to make mosquitoes resistant to the
malaria parasites they host could reduce the insects' ability to transmit
devastating diseases in places like Africa and other developing countries
where some 300 to 500 million cases of the disease occur each year.
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Conclusion
Biotechnology
is a tool. It does not provide the only approach to addressing a particular
set of problems, and other approaches or applications may offer better
solutions for particular needs. The report does not attempt to weigh the costs
and benefits of any particular biotechnology approach or to compare the
relative merits of potential alternatives.
Current
biotechnology research is addressing a wide range of possible future uses,
from enhancing the nutritional value of food and increasing food supply to
controlling or preventing disease in humans and animals. While some
applications are already on the market and widely used, others are a decade or
more away.
Industry
and university scientists are applying the new tools of biotechnology across a
broad range of plants and animals for a wide variety of possible future uses.
Much of this research remains at early stages. The broad scope of current
research suggests challenges ahead. As new products emerge, state and federal
regulators tasked with the responsibility to protect the environment and
ensure the safety of food are likely to face novel questions.
Public
attitudes about biotechnology will be affected both by the adequacy of the
regulatory response and the perceived benefits and risks of the particular
products brought to market. In that context, understanding the potential uses
of this technology can help us anticipate and prepare for these coming
questions.
Whether
today's research projects become tomorrow's products depends not only on
continued scientific progress, but also on addressing concerns about
environmental impacts and other risks, meeting regulatory requirements, and
dealing with marketplace realities. In that context, understanding the
potential uses of this technology is one critical part of the process by which
the public's decisions about biotechnology products will be made.
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Pew
2001. Harvest
on the Horizon: Future Uses of Agricultural Biotechnology
Table
of Contents
Preface 1
Introduction: Putting
Biotechnology in Context 4
PART
I. PLANTS 17
Applying biotechnology to
increase agricultural production, to improve food characteristics and to use
plants and trees for novel industrial purposes
SECTION 1: GENETICALLY MODIFYING FOOD CROPS 19
Pest and Disease Resistance:
Minimizing crop loss due to
insects and blight 19
Improvements to Crops:
Helping plants defend
themselves and ways to help farmers improve yield 27
Applications for Improved
Product Characteristics:
Creating better food 32
Summary
Chart of Food Crop Products 41
SECTION 2: GENETICALLY MODIFYING TREES 45
Making forestry products such
as paper, fuel, lumber, fruits and nuts easier to grow and process.
Summary Chart of Tree
Products 50
SECTION 3: GENETICALLY
MODIFYING TURF GRASS AND FLOWERS 51
Developing heartier grass and
flowers and creating flowers in new colors
Summary
Chart of Grass and Flower Products 52
SECTION 4: INDUSTRIAL
PRODUCTS, PHARMACEUTICALS AND ENVIRONMENTAL
REMEDIATION 53
Industrial Products:
Producing novel industrial
products from plants 53
Pharmaceuticals:
Experimenting with
plant-produced vaccines that help fight diseases 58
Environmental Remediation and
Conservation:
Exploring plants that can
detoxify soils or detect hazardous substances,and
ways to rescue endangered trees and plants 63
Summary
Chart of Industrial, Pharmaceutical and Remediation Products 67
PART
II. ANIMALS 69
Biotech moves beyond crops
and into animals, sea creatures and insects to create medical treatments,
prevent disease and increase food supplies
SECTION 1: GENETICALLY
ENGINEERED MAMMALS 71
Basic Genetic Research:
A summary of initial research
in animals 71
Production of Human Proteins:
Producing treatments for
genetic disorders and creating medical therapies 71
Xenotransplantation:
Modifying tissues and organs
for human transplantation 73
Farm Animal Production:
Improving farm animal health,
growth and yield for human consumption 74
Industrial Products:
Using animals to produce
industrial products 75
Summary
Chart of Mammals 76
SECTION 2: GENETICALLY
ENGINEERED AQUATIC ORGANISMS 77
Enhanced Growth:
Creating larger,
faster-growing fish for increased food production 78
Summary
Chart of Aquatic Organisms 80
SECTION 3: GENETICALLY
ENGINEERED INSECTS 81
Improving insect control and
preventing disease transmission
Summary
Chart of Insects 84
Conclusion 85
Glossary 87
Selected Bibliography 93
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Web site: http://pewagbiotech.org/research/harvest/
New Genetics, Food &
Agriculture: Scientific Discoveries - Societal Dilemmas