Behold the future of the apple: If the gene inserted into this apple plantlet makes it resistant to the fire blight bacterium, it could help save apple growers tens of millions of dollars a year. Researchers are also working on an apple that could vaccinate children against a virus that is the leading cause of pneumonia.
Here's what you need to know about the warming planet, how it's affecting us, and what's at stake.
BY REPUBLISHED FROM THE PAGES OF NATIONAL GEOGRAPHIC MAGAZINE
SCIENTISTS CONTINUE TO find new ways to insert genes for specific traits into plant and animal DNA. A field of promise—and a subject of debate—genetic engineering is changing the food we eat and the world we live in.
In the brave new world of genetic engineering, Dean DellaPenna envisions this cornucopia: tomatoes and broccoli bursting with cancer-fighting chemicals and vitamin-enhanced crops of rice, sweet potatoes, and cassava to help nourish the poor. He sees wheat, soy, and peanuts free of allergens; bananas that deliver vaccines; and vegetable oils so loaded with therapeutic ingredients that doctors "prescribe" them for patients at risk for cancer and heart disease. A plant biochemist at Michigan State University, DellaPenna believes that genetically engineered foods are the key to the next wave of advances in agriculture and health.
While DellaPenna and many others see great potential in the products of this new biotechnology, some see uncertainty, even danger. Critics fear that genetically engineered products are being rushed to market before their effects are fully understood. Anxiety has been fueled by reports of taco shells contaminated with genetically engineered corn not approved for human consumption; the potential spread of noxious "superweeds" spawned by genes picked up from engineered crops; and possible harmful effects of biotech corn pollen on monarch butterflies.
In North America and Europe the value and impact of genetically engineered food crops have become subjects of intense debate, provoking reactions from unbridled optimism to fervent political opposition.
Just what are genetically engineered foods, and who is eating them? What do we know about their benefits—and their risks? What effect might engineered plants have on the environment and on agricultural practices around the world? Can they help feed and preserve the health of the Earth's burgeoning population?
Q: Who's eating biotech foods?
A: In all likelihood, you are.
Most people in the United States don't realize that they've been eating genetically engineered foods since the mid-1990s. More than 60 percent of all processed foods on U.S. supermarket shelves—including pizza, chips, cookies, ice cream, salad dressing, corn syrup, and baking powder—contain ingredients from engineered soybeans, corn, or canola.
In the past decade or so, the biotech plants that go into these processed foods have leaped from hothouse oddities to crops planted on a massive scale—on 130 million acres (52.6 million hectares) in 13 countries, among them Argentina, Canada, China, South Africa, Australia, Germany, and Spain. On U.S. farmland, acreage planted with genetically engineered crops jumped nearly 25-fold from 3.6 million acres (1.5 million hectares) in 1996 to 88.2 million acres (35.7 million hectares) in 2001. More than 50 different "designer" crops have passed through a federal review process, and about a hundred more are undergoing field trials.
Q: How long have we been genetically altering our food?
A: Longer than you think.
Genetic modification is not novel. Humans have been altering the genetic makeup of plants for millennia, keeping seeds from the best crops and planting them in following years, breeding and crossbreeding varieties to make them taste sweeter, grow bigger, last longer. In this way we've transformed the wild tomato, Lycopersicon, from a fruit the size of a marble to today's giant, juicy beefsteaks. From a weedy plant called teosinte with an "ear" barely an inch long has come our foot-long (0.3-meter-long) ears of sweet white and yellow corn. In just the past few decades plant breeders have used traditional techniques to produce varieties of wheat and rice plants with higher grain yields. They have also created hundreds of new crop variants using irradiation and mutagenic chemicals.
But the technique of genetic engineering is new, and quite different from conventional breeding. Traditional breeders cross related organisms whose genetic makeups are similar. In so doing, they transfer tens of thousands of genes. By contrast, today's genetic engineers can transfer just a few genes at a time between species that are distantly related or not related at all.
Genetic engineers can pull a desired gene from virtually any living organism and insert it into virtually any other organism. They can put a rat gene into lettuce to make a plant that produces vitamin C or splice genes from the cecropia moth into apple plants, offering protection from fire blight, a bacterial disease that damages apples and pears. The purpose is the same: to insert a gene or genes from a donor organism carrying a desired trait into an organism that does not have the trait.
The engineered organisms scientists produce by transferring genes between species are called transgenic. Several dozen transgenic food crops are currently on the market, among them varieties of corn, squash, canola, soybeans, and cotton, from which cottonseed oil is produced. Most of these crops are engineered to help farmers deal with age-old agriculture problems: weeds, insects, and disease.
Farmers spray herbicides to kill weeds. Biotech crops can carry special "tolerance" genes that help them withstand the spraying of chemicals that kill nearly every other kind of plant. Some biotech varieties make their own insecticide, thanks to a gene borrowed from a common soil bacterium, Bacillus thuringiensis, or Bt for short.
Bt genes code for toxins considered to be harmless to humans but lethal to certain insects, including the European corn borer, an insect that tunnels into cornstalks and ears, making it a bane of corn farmers. So effective is Bt that organic farmers have used it as a natural insecticide for decades, albeit sparingly. Corn borer caterpillars bite into the leaves, stems, or kernels of a Bt corn plant, the toxin attacks their digestive tracts, and they die within a few days.
Other food plants—squash and papaya, for instance—have been genetically engineered to resist diseases. Lately scientists have been experimenting with potatoes, modifying them with genes of bees and moths to protect the crops from potato blight fungus, and grapevines with silkworm genes to make the vines resistant to Pierce's disease, spread by insects.
With the new tools of genetic engineering, scientists have also created transgenic animals. Atlantic salmon grow more slowly during the winter, but engineered salmon, "souped-up" with modified growth-hormone genes from other fish, reach market size in about half the normal time. Scientists are also using biotechnology to insert genes into cows and sheep so that the animals will produce pharmaceuticals in their milk. None of these transgenic animals have yet entered the market.
Q: Are biotech foods safe for humans?
A: Yes, as far as we know.
"Risks exist everywhere in our food supply," points out Dean DellaPenna. "About a hundred people die each year from peanut allergies. With genetically engineered foods we minimize risks by doing rigorous testing."
According to Eric Sachs, a spokesperson for
Monsanto, a leading developer of biotech products: "Transgenic products go
through more testing than any of the other foods we eat. We screen for
potential toxins and allergens. We monitor the levels of nutrients, proteins,
and other components to see that the transgenic plants are substantially
equivalent to traditional plants."
Three federal agencies regulate genetically engineered crops and
foods—the U.S. Department of Agriculture (USDA), the Environmental Protection
Agency (EPA), and the Food and Drug Administration (FDA). The FDA reviews data
on allergens, toxicity, and nutrient levels voluntarily submitted by companies.
If that information shows that the new foods are not substantially equivalent
to conventional ones, the foods must undergo further testing. Last year the
agency proposed tightening its scrutiny of engineered foods, making the safety
assessments mandatory rather than voluntary.
"When it comes to addressing concerns about health issues, industry
is being held to very high standards" says DellaPenna, "and it's
doing its best to meet them in reasonable and rigorous fashion."
In the mid-1990s a biotech company launched a project to insert a gene
from the Brazil nut into a soybean. The Brazil nut gene selected makes a
protein rich in one essential amino acid. The aim was to create a more
nutritious soybean for use in animal feed. Because the Brazil nut is known to
contain an allergen, the company also tested the product for human reaction,
with the thought that the transgenic soybean might accidentally enter the human
food supply. When tests showed that humans would react to the modified
soybeans, the project was abandoned.
For some people this was good evidence that
the system of testing genetically engineered foods works. But for some
scientists and consumer groups, it raised the specter of allergens or other
hazards that might slip through the safety net. Scientists know that some
proteins, such as the one in the Brazil nut, can cause allergic reactions in
humans, and they know how to test for these allergenic proteins. But the
possibility exists that a novel protein with allergenic properties might turn
up in an engineered food—just as it might in a new food produced by
conventional means—and go undetected. Furthermore, critics say, the technique
of moving genes across dramatically different species increases the likelihood
of something going awry—either in the function of the inserted gene or in the
function of the host DNA—raising the possibility of unanticipated health
effects.
An allergy scare in 2000 centered around StarLink, a variety of
genetically engineered corn approved by the U.S. government only for animal use
because it showed some suspicious qualities, among them a tendency to break
down slowly during digestion, a known characteristic of allergens. When
StarLink found its way into taco shells, corn chips, and other foods, massive
and costly recalls were launched to try to remove the corn from the food
supply.
No cases of allergic response have been pinned to StarLink. In fact,
according to Steve L. Taylor, chair of the Department of Food Science and
Technology at the University of Nebraska, "None of the current biotech
products have been implicated in allergic reactions or any other healthcare
problem in people." Nevertheless, all new foods may present new risks.
Only rigorous testing can minimize those risks.
Often overlooked in the debate about the health effects of these foods
is one possible health benefit: Under some conditions corn genetically
engineered for insect resistance may enhance safety for human and animal
consumption. Corn damaged by insects often contains high levels of fumonisins,
toxins made by fungi that are carried on the backs of insects and that grow in
the wounds of the damaged corn. Lab tests have linked fumonisins with cancer in
animals, and they may be potentially cancer-causing to humans. Among people who
consume a lot of corn—in certain parts of South Africa, China, and Italy, for
instance—there are high rates of esophageal cancer, which scientists associate
with fumonisins. Studies show that most Bt corn has lower levels of fumonisins
than conventional corn damaged by insects.
Should genetically engineered
foods be labeled? Surveys suggest that most Americans would say yes (although
they wouldn't want to pay more for the labeling). Professor Marion Nestle,
chair of the Department of Nutrition and Food Studies at New York University,
favors labeling because she believes consumers want to know and have the right
to choose. However, no engineered foods currently carry labels in the U.S.
because the FDA has not found any of them to be substantially different from
their conventional counterparts. Industry representatives argue that labeling
engineered foods that are not substantially different would arouse unwarranted
suspicion.
Q: Can biotech foods harm the environment?
A: It depends on
whom you ask.
Most scientists agree: The
main safety issues of genetically engineered crops involve not people but the
environment. "We've let the cat out of the bag before we have real data,
and there's no calling it back," says Allison Snow, a plant ecologist at
Ohio State University.
Snow is known for her research
on "gene flow," the movement of genes via pollen and seeds from one
population of plants to another, and she and some other environmental
scientists worry that genetically engineered crops are being developed too
quickly and released on millions of acres of farmland before they've been
adequately tested for their possible long-term ecological impact.
Advocates of genetically
engineered crops argue that the plants offer an environmentally friendly
alternative to pesticides, which tend to pollute surface and groundwater and
harm wildlife. The use of Bt varieties has dramatically reduced the amount of
pesticide applied to cotton crops. But the effects of genetic engineering on
pesticide use with more widely grown crops are less clear-cut.
What might be the effect of
these engineered plants on so-called nontarget organisms, the creatures that
visit them? Concerns that crops with built-in insecticides might damage
wildlife were inflamed in 1999 by the report of a study suggesting that Bt corn
pollen harmed monarch butterfly caterpillars.
Monarch caterpillars don't feed on corn
pollen, but they do feed on the leaves of milkweed plants, which often grow in
and around cornfields. Entomologists at Cornell University showed that in the
laboratory Bt corn pollen dusted onto milkweed leaves stunted or killed some of
the monarch caterpillars that ate the leaves. For some environmental activists
this was confirmation that genetically engineered crops were dangerous to
wildlife. But follow-up studies in the field, reported last fall, indicate that
pollen densities from Bt corn rarely reach damaging levels on milkweed, even
when monarchs are feeding on plants within a cornfield.
"The chances of a caterpillar finding Bt pollen doses as high as
those in the Cornell study are negligible," says Rick Hellmich, an
entomologist with the Agricultural Research Service and one author of the
follow-up report. "Butterflies are safer in a Bt cornfield than they are
in a conventional cornfield, when they're subjected to chemical pesticides that
kill not just caterpillars but most insects in the field."
Perhaps a bigger concern has to do with insect evolution. Crops that
continuously make Bt may hasten the evolution of insects impervious to the
pesticide. Such a breed of insect, by becoming resistant to Bt, would rob many
farmers of one of their safest, most environmentally friendly tools for
fighting the pests.
To delay the evolution of resistant insects, U.S. government regulators,
working with biotech companies, have devised special measures for farmers who
grow Bt crops. Farmers must plant a moat or "refuge" of conventional
crops near their engineered crops. The idea is to prevent two resistant bugs from
mating. The few insects that emerge from Bt fields resistant to the insecticide
would mate with their nonresistant neighbors living on conventional crops
nearby; the result could be offspring susceptible to Bt. The theory is that if
growers follow requirements, it will take longer for insects to develop
resistance.
It was difficult initially to convince farmers who had struggled to keep
European corn borers off their crops to let the insects live and eat part of
their acreage to combat resistance. But a 2001 survey by major agricultural
biotech companies found that almost 90 percent of U.S. farmers complied with
the requirements.
Many ecologists believe that the most
damaging environmental impact of biotech crops may be gene flow. Could
transgenes that confer resistance to insects, disease, or harsh growing
conditions give weeds a competitive advantage, allowing them to grow rampantly?
"Genes flow from crops to weeds all the time when pollen is
transported by wind, bees, and other pollinators," says Allison Snow.
"There's no doubt that transgenes will jump from engineered crops into
nearby relatives." But since gene flow usually takes place only between
closely related species, and since most major U.S. crops don't have close
relatives growing nearby, it's extremely unlikely that gene flow will occur to
create problem weeds.
Still, Snow says, "even a very low probability event could occur
when you're talking about thousands of acres planted with food crops." And
in developing countries, where staple crops are more frequently planted near
wild relatives, the risk of transgenes escaping is higher. While no known
superweeds have yet emerged, Snow thinks it may just be a matter of time.
Given the risks, many ecologists believe that industry should step up
the extent and rigor of its testing and governments should strengthen their
regulatory regimes to more fully address environmental effects. "Every
transgenic organism brings with it a different set of potential risks and
benefits," says Snow. "Each needs to be evaluated on a case-by-case
basis. But right now only one percent of USDA biotech research money goes to
risk assessment."
Q: Can biotech foods help
feed the world?
A: There are obstacles to overcome.
"Eight hundred million people on this planet are
malnourished," says Channapatna Prakash, a native of India and an
agricultural scientist at the Center for Plant Biotechnology Research at
Tuskegee University, "and the number continues to grow."
Genetic engineering can help address the urgent problems of food
shortage and hunger, say Prakash and many other scientists. It can increase
crop yields, offer crop varieties that resist pests and disease, and provide
ways to grow crops on land that would otherwise not support farming because of
drought conditions, depleted soils, or soils plagued by excess salt or high
levels of aluminum and iron. "This technology is extremely
versatile," Prakash explains, "and it's easy for farmers to use
because it's built into the seed. The farmers just plant the seeds, and the
seeds bring new features in the plants."
Some critics of genetic engineering argue
that the solution to hunger and malnutrition lies in redistributing existing
food supplies. Others believe that the ownership by big multinational companies
of key biotechnology methods and genetic information is crippling public-sector
efforts to use this technology to address the needs of subsistence farmers. The
large companies that dominate the industry, critics also note, are not devoting
significant resources to developing seed technology for subsistence farmers
because the investment offers minimal returns. And by patenting key methods and
materials, these companies are stifling the free exchange of seeds and
techniques vital to public agricultural research programs, which are already
under severe financial constraints. All of this bodes ill, say critics, for
farmers in the developing world.
Prakash agrees that there's enough food in the world. "But
redistribution is just not going to happen," he says. "The protest
against biotech on political grounds is a straw man for a larger frustration
with globalization, a fear of the power of large multinational corporations.
People say that this technology is just earning profit for big companies. This
is true to some extent, but the knowledge that companies have developed in the
production of profitable crops can easily be transferred and applied to help
developing nations."
"Biotechnology is no panacea for world hunger," says Prakash,
"but it's a vital tool in a toolbox, one that includes soil and water
conservation, pest management, and other methods of sustainable agriculture, as
well as new technologies."
The debate over the use of biotechnology in developing countries
recently went from simmer to boil about rice, which is eaten by three billion
people and grown on hundreds of millions of small farms.
"White rice," explains Dean DellaPenna, "is low in
protein. It has very little iron, and virtually no vitamin A."However, in
1999 a team of scientists led by Ingo Potrykus, of the Swiss Federal Institute
of Technology, and Peter Beyer, of the University of Freiburg, Germany,
announced a new breakthrough: They had introduced into rice plants two daffodil
genes and one bacterial gene that enable the rice to produce in its grains
beta-carotene, a building block of vitamin A. According to the World Health
Organization, between 100 million and 140 million children in the world suffer
from vitamin A deficiency, some 500,000 go blind every year because of that
deficiency, and half of those children die within a year of losing their sight.
"Golden rice," so named for the yellow color furnished by the
beta-carotene, was hailed by some as a potential solution to the suffering and
illness caused by vitamin A deficiency.
Skeptics consider golden rice little more
than a public relations ploy by the biotechnology industry, which they say
exaggerated its benefits. "Golden rice alone won't greatly diminish
vitamin A deficiency," says Marion Nestle. "Beta-carotene, which is
already widely available in fruit and vegetables, isn't converted to vitamin A
when people are malnourished. Golden rice does not contain much beta-carotene,
and whether it will improve vitamin A levels remains to be seen."
Potrykus and Beyer are now developing new versions of the rice that may
be more effective in delivering beta-carotene for the body to convert to
vitamin A. Their plan is to put the improved rices free of charge into the
hands of poor farmers. According to Beyer, golden rice is still at least four
years away from distribution. It could take much longer if opposing groups
delay plans for field trials and safety studies.
Q: What next?
A: Proceed with caution.
Whether biotech foods
will deliver on their promise of eliminating world hunger and bettering the
lives of all remains to be seen. Their potential is enormous, yet they carry
risks—and we may pay for accidents or errors in judgment in ways we cannot yet
imagine. But the biggest mistake of all would be to blindly reject or endorse
this new technology. If we analyze carefully how, where, and why we introduce
genetically altered products, and if we test them thoroughly and judge them
wisely, we can weigh their risks against their benefits to those who need them
most.
Fonte: National Geographic
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