BIOTECH: THE BASICS, PART 1

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BIOTECH: THE BASICS, PART 1

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Jan 09, 2007 16:30 PST

 

BIOTECH: THE BASICS, PART 1

by Rachel Massey*

Genetic engineering is the process by which genes are altered and

transferred artificially from one organism to another. Genes,

which are made of DNA, contain the instructions according to

which cells produce proteins; proteins in turn form the basis for

most of a cell's functions. Genetic engineering makes it possible

to mix genetic material between organisms that could never breed

with each other. It allows people to take genes from one species,

such as a flounder, and insert them into another species, such as

a tomato -- thus, for example, creating a tomato that has some of

the characteristics of a fish.

 

 

Starting in the 1980s and accelerating rapidly in the past

decade, companies have begun using genetic engineering to insert

foreign genes into many crops, including important foods such as

corn and soybeans.[1] Just in the past few years, genetically

engineered ingredients have begun appearing in many foods in U.S.

supermarkets; they have been detected in processed foods such as

infant formulas, drink mixes, and taco shells, to name a few

examples.[2] These foods are not labeled, so consumers have no

way to know when they are eating genetically engineered food.

 

 

Genetic engineering is an extremely powerful technology whose

mechanisms are not fully understood even by those who do the

basic scientific work. In this series, we will review the main

problems that have been identified with genetically engineered

crops.[3]

 

 

Most genetically engineered crops planted worldwide are designed

either to survive exposure to certain herbicides or to kill

certain insects. Herbicide tolerant crops accounted for 71% of

the acreage planted with genetically engineered crops in 1998 and

1999, and crops designed to kill insects (or designed both to

kill insects AND to withstand herbicides) accounted for most of

the remaining acreage. A small proportion (under 1%) of

genetically engineered crops planted in 1998 and 1999 were

designed to resist infection by certain viruses.[4]

 

 

Genetically engineered herbicide-tolerant crops are able to

survive applications of herbicides that would ordinarily kill

them. The U.S. food supply currently includes products made from

genetically engineered herbicide-tolerant crops including

" Roundup Ready " canola, corn, and soybeans which are engineered

to withstand applications of Monsanto's Roundup (active

ingredient, glyphosate), as well as crops engineered to survive

exposure to other herbicides.[1]

 

 

Genetically engineered pest-resistant (or pesticidal) crops are

toxic to insects that eat them. For example, corn can be

engineered to kill the European corn borer, an insect in the

order lepidoptera (the category that includes butterflies and

moths). This is accomplished by adding genetic material derived

from a soil bacterium, BACILLUS THURINGIENSIS (Bt), to the

genetic code of the corn. BACILLUS THURINGIENSIS naturally

produces a protein toxic to some insects, and organic farmers

sometimes spray Bt on their crops as a natural pesticide. In

genetically engineered " Bt corn, " every cell of the corn plant

produces the toxin ordinarily found only in the bacterium.

 

 

Unfortunately, genetically engineered crops can have adverse

effects on human health and on ecosystems. And by failing to test

or regulate genetically engineered crops adequately, the U.S.

government has allowed corporations to introduce unfamiliar

substances into our food supply without any systematic safety

checks.

 

 

Here are some of the reasons why we might not want to eat

genetically engineered crops:

 

 

** Ordinary, familiar foods can become allergenic through the

addition of foreign genes.

 

 

Genetic engineering can introduce a known or unknown allergen

into a food that previously did not contain it. For example, a

soybean engineered to contain genes from a brazil nut was found

to produce allergic reactions in blood serum of individuals with

nut allergies. (See REHN #638.) Allergic reactions to nuts can be

serious and even fatal. Researchers were able to identify the

danger in this particular case because nut allergies are common

and it was possible to conduct proper tests on blood serum from

allergic individuals. In other cases, testing for allergenic

potential can be much more difficult. When genetic engineering

causes a familiar food to start producing a substance previously

not present in the human food supply, it is impossible to know

who may have an allergic reaction.

 

 

** Genetic engineering has the potential to make ordinary,

familiar foods become toxic.

 

 

In some cases, new characteristics introduced intentionally may

create toxicity. The Bt toxin as it appears in the bacteria that

produce it naturally is considered relatively safe for humans. In

these bacteria, the toxin exists in a " protoxin " form, which

becomes dangerous to insects only after it has been shortened, or

" activated, " in the insect's digestive system. In contrast, some

genetically engineered Bt crops produce the toxin in its

activated form, which previously only appeared inside the

digestive systems of certain insects.[5] Humans have little

experience with exposure to this form of the toxin. Furthermore,

in the past humans have had no opportunity or reason to ingest

any form of the Bt toxin in large quantities. When the Bt toxin

is incorporated into our common foods, we are exposed each time

we eat those foods.[6, pgs. 64-65.] And of course, a pesticide

engineered into every cell of a food source cannot simply be

washed off before a meal.

 

 

Toxicity can also result from characteristics introduced

unintentionally. For example, a plant that ordinarily produces

high amounts of a toxin in its leaves and low amounts in its

fruit could unexpectedly begin to concentrate the toxin in its

fruit after addition of a new gene. (See REHN #696.)

 

 

Unpleasant surprises of this sort can result from our ignorance

about exactly how a foreign gene has been incorporated into the

engineered cell. Foreign genes can be added to cells by various

methods; among other options, they can be blasted into cells

using a " gene gun, " or a virus or bacterium can be used to carry

them into the target cells.[7] The " genetic engineer " who sets

this process in motion does not actually control where the new

genes end up in the genetic code of the target organism. The

" engineer " essentially inserts the genes at a random, unknown

location in the cell's existing DNA. These newly-inserted genes

may sometimes end up in the middle of existing genetic

instructions, and may disrupt those instructions.

 

 

A foreign gene could, for example, be inserted in the middle of

an existing gene that instructs a plant to shut off production of

a toxin in its fruit. The foreign gene could disrupt the

functioning of this existing gene, causing the plant to produce

abnormal levels of the toxin in its fruit. This phenomenon is

known as " insertional mutagenesis " -- unpredictable changes

resulting from the position in which a new gene is inserted.[8]

Genetic engineering can also introduce unexpected new toxicity in

food through a well-known phenomenon known as pleiotropy, in

which one gene affects multiple characteristics of an organism.

(See REHN #685.)

 

 

** Genetically engineered crops can indirectly promote the

development of antibiotic resistance, making it difficult or

impossible to treat common human diseases.

 

 

Whatever method is used to introduce foreign genes into a target

cell, it only works some of the time, so the " genetic engineer "

needs a way to identify those cells that have successfully taken

up the foreign genes. One way to identify these cells is to

attach a gene for antibiotic resistance to the gene intended for

insertion. After attempting to introduce the foreign genes, the

" engineer " can treat the mass of cells with an antibiotic. Only

those cells that have incorporated the new genes survive, because

they are now resistant to antibiotics.

 

 

From these surviving cells, a new plant is generated. Each cell

of this plant contains the newly introduced genes, including the

gene for antibiotic resistance. Once in the food chain, in some

cases these genes could be taken up by and incorporated into the

genetic material of bacteria living in human or animal digestive

systems. A 1999 study published in APPLIED AND ENVIRONMENTAL

MICROBIOLOGY found evidence supporting the view that bacteria in

the human mouth could potentially take up antibiotic resistance

genes released from food.[9] Antibiotic resistance among

disease-causing bacteria is already a major threat to public

health; due to the excessive use of antibiotics in medical

treatment and in agriculture, we are losing the ability to treat

life-threatening diseases such as pneumonia, tuberculosis, and

salmonella.[10] (See REHN #402.) By putting antibiotic resistance

genes into our food, we may be increasing the public health

problem even further.

 

 

The British Medical Association, the leading association of

doctors in Britain, urged an end to the use of antibiotic

resistance genes in genetically engineered crops in a 1999

report. " There should be a ban on the use of antibiotic

resistance marker genes in GM [genetically modified] food, as the

risk to human health from antibiotic resistance developing in

micro-organisms is one of the major public health threats that

will be faced in the 21st Century. The risk that antibiotic

resistance may be passed on to bacteria affecting human beings,

through marker genes in the food chain, is one that cannot at

present be ruled out, " the Association said.[11]

 

 

To be continued.

 

 

==========

 

 

*Rachel Massey is a consultant to Environmental Research

Foundation.

 

 

[1] Union of Concerned Scientists, " Foods on the Market, "

available at http://www.ucsusa.org. Choose " biotechnology " in the

bar at the bottom of the screen, then click on " Foods on the

Market. "

 

 

[2] Consumers Union, " CONSUMER REPORTS: Genetically Engineered

Foods in Your Shopping Cart, " Press Release, August 23, 1999.

Available at http://www.consumersunion.org/food/gefny999.htm.

 

 

[3] For one recent overview, see Environmental Media Services

(EMS), REPORTERS' GUIDE: GENETIC ENGINEERING IN AGRICULTURE,

Edition 1 (October 2000), available from EMS, Washington, D.C.,

(202) 463-6670 or at http://www.ems.org. Also see Pesticide

Action Network North America (PANNA), " Genetically Engineered

Crops and Foods: Online Presentation, " available at

http://www.panna.org/panna/resources/geTutorial.html.

 

 

[4] Clive James, " Global Review of Commercialized Transgenic

Crops: 1999 " ISAAA BRIEFS No. 12: Preview, produced by

International Service for the Acquisition of Agri-Biotech

Applications (ISAAA). Available at

http://www.isaaa.org/Global%20Review%201999/briefs12cj.htm.

 

 

[5] See Michael Hansen, " Potential Environmental and Human Health

Problems Associated with Genetically Engineered Food. "

Presentation delivered at CREA International Seminar on

Transgenic Products, Curitiba, Brazil, October 11, 1999.

Available from Consumer Policy Institute, Yonkers, N.Y.:

914-378-2455.

 

 

[6] National Research Council, GENETICALLY MODIFIED

PEST-PROTECTED PLANTS: SCIENCE AND REGULATION (Washington, D.C.:

National Academy of Sciences, 2000). ISBN 0309069300.

 

 

[7] Union of Concerned Scientists, " Fact Sheet: Genetic

Engineering Techniques. " Available at http://www.ucsusa.org.

Choose " biotechnology " in the bar at the bottom of the screen,

then click on " Genetic Engineering Techniques. "

 

 

[8] See Food and Drug Administration, " Premarket Notice

Concerning Bioengineered Foods, " FEDERAL REGISTER Vol. 66, No. 12

(January 18, 2001), pg. 4710.

 

 

[9] Derry K. Mercer and others, " Fate of Free DNA and

Transformation of the Oral Bacterium STREPTOCOCCUS GORDONII DL1

by Plasmid DNA in Human Saliva, " APPLIED AND ENVIRONMENTAL

MICROBIOLOGY Vol. 65, No. 1 (January 1999), pgs. 6-10.

 

 

[10] See World Health Organization (WHO), OVERCOMING

ANTIMICROBIAL RESISTANCE (Geneva, Switzerland: World Health

Organization, 2000). Available at

http://www.who.int/infectious-disease-report/2000/.

 

 

[11] British Medical Association Board of Science and Education,

" The Impact of Genetic Modification on Agriculture, Food and

Health -- An Interim Statement, " May 1999. Summary statement

available at http://www.bma.org.uk/public/science/genmod.htm.

 

 

RACHEL'S ENVIRONMENT & HEALTH NEWS #717 .

---February 1, 2001--- .

 

BIOTECH--THE BASICS, PART 2

 

 

by Rachel Massey*

 

 

In the last issue, we looked at hazards associated with eating

genetically engineered foods: unexpected allergic reactions;

unexpected toxicity; and the development of antibiotic

resistance.[1] It is increasingly clear that genetic engineering

is neither precise nor predictable; " genetic engineers " are

tampering with the instructions for basic cell functions, without

understanding fully how those instructions work.

 

 

** One source of unpredictable effects is the use of " promoter "

genes. As we saw in REHN #716, the aim of genetic engineering is

to take a gene from one organism and insert it into another

organism. However, organisms have elaborate defense mechanisms to

prevent foreign genes from affecting them, so a gene moved from a

bacterium to a plant will not automatically work in its new host.

To overcome the target organism's defenses and make the new gene

function, it is necessary to add a " promoter " gene -- a genetic

switch that " turns on " the foreign gene.

 

 

The promoter of choice in most cases is derived from a plant

virus called the cauliflower mosaic virus. Known as the CaMV 35S

promoter, this genetic sequence causes hyperexpression of other

genes. A gene is hyperexpressed when the proteins for which it

contains instructions are produced in excessive amounts --

perhaps ten to a thousand times as great as normal levels.

Because the CaMV 35S gene is so powerful, in addition to " turning

on " the target gene, it may also " turn on " other genes near where

it is inserted, causing the engineered cell to display

unpredictable new features.[2]

 

 

** Plants can defend themselves against the intrusion of foreign

genetic instructions through the phenomenon of " gene silencing, "

in which the cell blocks expression of the foreign DNA. Silencing

may occur in unpredictable ways in genetically engineered plants.

For example, a recent study found that infection with the

cauliflower mosaic virus could trigger silencing of a newly

inserted trait for herbicide tolerance, which was linked to the

CaMV 35S promoter. Apparently, the plant defended itself against

the infection through silencing of the viral genes. At the same

time, it silenced other newly-inserted genes.[3]

 

 

** Genetically engineered foods may also produce unexplained

health effects in laboratory animals. An article published in THE

LANCET by Stanley Ewen and Arpad Pusztai reports on a study of

laboratory rats fed genetically engineered potatoes.[4] The

potatoes were designed to produce a substance known as GALANTHUS

NIVALIS agglutinin (GNA), which is ordinarily found in snowdrops

(a type of flower). The purpose of adding GNA to potatoes was to

increase resistance to certain insects and other pests.

 

 

Ewen and Pusztai worked with three groups of rats. One received

the genetically engineered potatoes designed to produce GNA; the

second received ordinary, non-engineered potatoes, without GNA;

and the third group received ordinary, non-engineered potatoes

mixed with a dose of GNA. Ewen and Pusztai studied the changes

that occurred in the digestive systems of the rats in each group.

 

 

The researchers found that eating engineered or non-engineered

potatoes with GNA was associated with certain changes in the

rats' stomachs. In addition, the engineered GNA potatoes were

associated with certain intestinal changes NOT found in the rats

fed ordinary potatoes laced with GNA. The researchers do not know

the reason for these additional changes. They could be due to a

" positioning effect " -- the foreign gene may have been inserted

at a location in the existing genetic material that caused it to

disrupt normal functioning of an existing gene. Or it could be

due to the activity of other genetic material inserted along with

the target gene, such as the promoter.

 

 

Pusztai was forced to retire from his research position at the

Rowett Research Institute in Scotland after he spoke publicly

about the results of his work. (See REHN #649.) His article in

THE LANCET is one of only a few animal feeding studies that have

been published on the altered foods that are now present,

unlabeled, in our grocery stores.

 

 

** In some cases, genetically engineered crops can have altered

nutritional content. One study found that glyphosate-tolerant

soybeans had significantly altered levels of naturally occurring

compounds known as isoflavones, which are thought to have some

health benefits.[5] The consequences of changes like this could

be minor in some cases and serious in others. The important

lesson is that when we eat soy, corn, or other important foods

that have been genetically altered, we may not be getting the

nutrient mix we could expect in the past. As long as these

altered foods are unlabeled, we do not have the information we

need to make informed choices about the foods we eat.

 

 

Last fall, corn products in U.S. supermarkets were found to be

contaminated with " StarLink " corn, a genetically engineered

variety approved only for use as animal feed due to concerns

about possible allergic reactions in humans.[6] The contamination

was detected by a non-governmental organization, Friends of the

Earth, working as part of a national collaborative effort, the

Genetically Engineered Food Alert coalition. Had Friends of the

Earth not taken responsibility for testing foods -- a function

that should be performed by government -- we could have continued

to consume unapproved StarLink corn with no way to trace the

health consequences. We do not know what other errors may already

have occurred; and since we do not know when we are eating

genetically engineered foods, we have no way to watch for links

between eating these foods and developing certain illnesses.

Those who favor the rapid and unregulated introduction of

genetically engineered foods into our food supply often say

genetic engineering is really nothing new; it is simply an

extension of conventional agricultural breeding techniques. In

fact, as Michael Hansen of Consumers Union explains in a review

article, there are some obvious differences.[2]

 

 

** Gene transfers across natural boundaries: Conventional

breeding transfers genetic information among organisms that are

related to one another -- members of the same species, or related

species, or (rarely) of closely-related genera. (Genera is the

plural of genus; a genus is a biological grouping that includes

multiple species.) Genetic engineering, on the other hand, may

transfer genes from any organism to any other organism (fish to

fruit, bacteria to vegetables, etc.).

 

 

** Location of gene insertion: Variations of a gene are known as

alleles. Genes are carried in chromosomes, and each gene has a

specific place in a chromosome. Conventional breeding shuffles

alleles of existing genes. In general, conventional breeding does

not move genes from one place to another in a chromosome. Genetic

engineering, on the other hand, inserts genes that were not in

the original chromosome of the target organism. These genes may

be inserted in unpredictable locations in the chromosome,

producing unforseeable changes in the plant.

 

 

** Extra genetic material: Genetically engineered foods contain

extra genetic material that is unrelated to the target

characteristics. This extra genetic material can include vectors,

which are added to move genes across natural barriers; promoters,

added to " turn on " the foreign genes; marker genes, added to show

the engineer whether the target gene has been successfully

inserted; and random extra genetic material that the engineer

inserts unintentionally. Here is a brief discussion of each of

these categories:

 

 

a) Vectors: Genetic engineering often uses " vectors, " genetic

sequences derived from viruses or bacteria, to move genes into

the target cell. One vector used frequently is derived from

AGROBACTERIUM TUMEFACIENS, a bacterium that causes tumors in

plants by inserting DNA from its own genetic code into the

genetic code of the plant. A study published in PROCEEDINGS OF

THE NATIONAL ACADEMY OF SCIENCES in January 2001 reported that

AGROBACTERIUM may be able to insert DNA into human cells as

well.[7]

 

 

When AGROBACTERIUM infects a plant under natural conditions, the

genes are incorporated only into the infected part of the plant;

they do not move throughout the plant and are not passed on to

subsequent generations. In contrast, when AGROBACTERIUM genes are

used as vectors in genetic engineering, the resulting plant

includes AGROBACTERIUM genes in all its cells. Conventional

breeding does not require the use of vectors.

 

 

b) Promoters: As we have seen, most genetically engineered crops

include the CaMV 35S " promoter " gene to " turn on " the foreign

gene and overcome normal cell defense mechanisms. Viral promoters

are not necessary for conventional breeding.

 

 

c) Marker genes: As we saw in REHN #716, genetic engineering

often involves the insertion of antibiotic resistance marker

genes. This does not occur in conventional breeding.

 

 

d) Unintentional additions: Sometimes genetic engineers introduce

additional genetic material into the target cell without knowing

it. Last spring, for example, newspapers reported that Monsanto's

Roundup Ready (glyphosate-tolerant) soybeans contained extra

fragments of DNA that the company's genetic engineers were not

aware of having introduced.[8]

 

 

On the basis of these points, some people would say that genetic

engineering is " very different " from conventional breeding,

whereas others would say that it is only " somewhat different. "

Either way, the differences have obvious implications for the

ways in which governments should regulate genetically engineered

foods. At a minimum, governments should require companies to

conduct pre-market safety tests related to the special hazards

associated with genetic engineering, and any altered foods

allowed onto the market should be labeled.

 

 

[To be continued.]

 

 

===========================

 

 

*Rachel Massey is a consultant to Environmental Research

Foundation.

 

 

[1] For a thorough collection of resources on agricultural

biotechnology, see AgBioTech InfoNet, maintained by Benbrook

Consulting Services at http://www.biotech-info.net.

 

 

[2] Michael K. Hansen, " Genetic Engineering is Not an Extension

of Conventional Plant Breeding; How Genetic Engineering Differs

from Conventional Breeding, Hybridization, Wide Crosses, and

Horizontal Gene Transfer, " available at http://-

www.consumersunion.org/food/widecpi200.htm. Also see Michael

Hansen and Ellen Hickey, " Genetic Engineering: Imprecise and

Unpredictable, " in GLOBAL PESTICIDE CAMPAIGNER, Vol. 10, No. 1,

April 2000, available from Pesticide Action Network

(415-981-1771; pan-).

 

 

[3] Nadia S. Al-Kaff and others, " Plants Rendered

Herbicide-Susceptible by Cauliflower Mosaic Virus-Elicited

Suppression of a 35S Promoter-Regulated Transgene, " NATURE

BIOTECHNOLOGY Vol. 18 (September 2000), pgs. 995-999.

 

 

[4] Stanley W. B. Ewen and Arpad Pusztai, " Effect of Diets

Containing Genetically Modified Potatoes Expressing GALANTHUS

NIVALIS Lectin on Rat Small Intestine, " THE LANCET Vol. 354, No.

9187 (October 16, 1999), pgs. 1353-1354.

 

 

[5] Marc A. Lappe and others, " Alterations in Clinically

Important Phytoestrogens in Genetically Modified,

Herbicide-Tolerant Soybeans, " JOURNAL OF MEDICINAL FOOD Vol. 1,

No. 4 (July 1999), pgs. 241-245.

 

 

[6] Andrew Pollack, " Case Illustrates Risks of Altered Food. " NEW

YORK TIMES October 14, 2000. Available at http://-

www.biotech-info.net/altered_food.html

 

 

[7] Talya Kunik and others, " Genetic Transformation of HeLa Cells

by AGROBACTERIUM, " PROCEEDINGS OF THE NATIONAL ACADEMY OF

SCIENCES, published online before print (January 30, 2001). Full

text available for U.S. $5 at

http://www.pnas.org/cgi/doi/10.1073/pnas.041327598.

 

 

[8] James Meikle, " Soya Gene Find Fuels Doubts on GM Crops, " THE

GUARDIAN (London) (May 31, 2000). Available at http://-

www.guardianunlimited.co.uk/gmdebate/Story/0,2763,326569,00.html

Also see " Monsanto GM Seeds Contain 'Rogue' DNA, " SCOTLAND ON

SUNDAY (May 30, 2000). Available at http://www.biotech-info.net/-

Rogue_DNA.html

 

 

RACHEL'S ENVIRONMENT & HEALTH NEWS #718 .

---February 15, 2001--- .

 

 

BIOTECH: THE BASICS, PART 3

 

 

By Rachel Massey*

 

 

As we saw in REHN #716, genetically engineered crops now planted

in the U.S. and worldwide are mostly designed to tolerate

herbicides or to kill insects or other pests. A small percentage

is designed for other purposes such as resisting infection by

certain viruses. Here we will look at some of the threats

genetically engineered crops pose to ecosystems.

 

 

Pesticidal crops may be toxic to nontarget organisms - organisms

they were not designed to kill. For example, BT corn designed to

kill the European corn borer can also be toxic to other closely

related insects, including butterflies and moths.

 

 

Monarch butterfly larvae feed on milkweed, which often grows in

or near corn fields. In a laboratory, scientists found that

monarch larvae feeding on milkweed dusted with BT corn pollen

grew more slowly and died at a higher rate than larvae that were

not exposed to the toxic pollen.[1] Another study found these

effects were likely to occur outside the laboratory as well.

Researchers placed potted milkweed plants in fields of BT corn

and measured the number of BT pollen grains that were deposited

on the milkweed leaves. Monarch larvae exposed to BT corn pollen

at these levels had high death rates compared with larvae exposed

to non-engineered corn pollen or placed on milkweed leaves with

no pollen.[2]

 

 

The U.S. Environmental Protection Agency (EPA) now expresses

concern about the effects of BT corn pollen on monarchs and other

butterfly species, including the endangered Karner Blue

butterfly.[3] EPA has asked companies to submit data on these

effects, but this " data call-in " occurred four years AFTER EPA

allowed BT corn to be used on U.S. farms.[2,pg.13]

 

 

BT corn may also harm the green lacewing, a beneficial insect

that eats agricultural pests. The lacewing may be affected by the

toxin in the digestive systems of insects that have eaten BT corn

but have not been killed by it.[4] This example shows how

non-target effects may interfere with a chain of predator-prey

relationships, disrupting the natural balance that keeps pest

populations under control.

 

 

BT crops may also affect non-target organisms by changing soil

chemistry. A 1999 article in NATURE reported that the roots of BT

corn plants released BT toxin into soil. The researchers found

that 90 to 95% of susceptible insect larvae exposed to the

substance released from the roots died after 5 days.[5]

 

 

The use of BT crops can also promote the development of

BT-resistant pest populations. As we saw in REHN #716, organic

farmers use BT sprays occasionally as a natural insecticide to

combat severe pest outbreaks. BT crops, in contrast, generally

expose insects to BT toxins day after day, whether or not there

is a major infestation. These conditions increase the likelihood

that BT-resistant insects will evolve. The widespread appearance

of BT-resistant insect pests would mean the loss of one of the

most valuable tools available to organic farmers for dealing with

serious pest outbreaks.[6,pg.139]

 

 

Herbicide-tolerant crops are designed to make it easier for

farmers to use certain herbicides. A 1999 study of soybean

farming in the U.S. midwest found that farmers planting Roundup

Ready soybeans used 2 to 5 times as many pounds of herbicide per

acre as farmers using conventional systems, and ten times as much

herbicide as farmers using Integrated Weed Management systems,

which are intended to reduce the need for chemical

herbicides.[7,pg.2] Glyphosate, the active ingredient in Roundup,

can sometimes persist in soil over long periods of time[8] and

may affect the growth of beneficial soil bacteria, among other

environmental effects.[9] A recent, unpublished study conducted

at the University of Missouri suggests that applications of

Roundup to Roundup Ready crops may be associated with elevated

levels of soil fungi that sometimes cause plant diseases.[10]

 

 

More hazards may lie ahead as new products of genetic engineering

come to market. According to the NEW YORK TIMES, Scotts Company

is collaborating with Monsanto to develop Roundup Ready grass for

lawns.[11] Studies suggest that Roundup exposures can be harmful

to human health. For example, exposure to glyphosate herbicides

may be associated with increased occurrence of non-Hodgkins

lymphoma, a cancer of white blood cells.[12] (See REHN #660.) And

a study published last August in ENVIRONMENTAL HEALTH

PERSPECTIVES found that in a laboratory, Roundup exposure

interfered with sex hormone production in cells of testicular

tumors taken from mice.[13] If the introduction of Roundup Ready

grass leads to increased use of Roundup on lawns, children's

exposure to the herbicide could rise.

 

 

In some cases, genetically engineered crops might become problem

weeds, disrupting existing ecosystems. A recent study published

in NATURE found that some genetically engineered crops are

unlikely to become problem weeds. Researchers planted genetically

engineered crops that were available in 1990 and monitored their

growth for ten years. Many of the plants simply died out, and

those that did survive showed no signs of spreading.[14] But some

crop plants, such as canola, survive well on their own without

human intervention. In Canada, genetically engineered canola

plants designed to resist various herbicides appear to have

exchanged genetic material so that some canola plants now can

survive exposure to two or three herbicides. These plants with

multiple herbicide resistance can be difficult for farmers to

control.[6,pgs.122-123]

 

 

Genetically engineered virus-resistant crops are supposed to

reduce problems from viral infections, but in some cases they

could make those problems worse. Virus-resistant crops are

created by adding virus genes to the plant's existing genetic

material. If a genetically engineered crop resistant to one virus

is infected by another virus, the genetic material from the two

viruses may sometimes interact to produce new virus types, which

could be more harmful or could infect a wider range of plants

than the original.[15,pgs.59-68]

 

 

All the hazards discussed above are compounded by the problem of

genetic pollution. Many crop plants disperse genetic material

through pollen, which may be carried by the wind or by

pollinators such as bees. This means genetically engineered

plants may " share " their genetic material with other,

non-engineered plants. For example, pollen from genetically

engineered corn can blow into a neighboring field and pollinate

conventional corn. Because of genetic pollution, some organic

farmers whose fields border genetically engineered crops may no

longer be able to certify their crops as organic.[6,pg.127]

 

 

In animals, sexual reproduction between different species is

usually impossible. In a few cases, reproduction between closely

related species can occur but the offspring are generally

sterile. For example, a horse and a donkey can mate to produce a

mule, but mules cannot reproduce. In contrast, many plants are

able to reproduce sexually with related species, and the

offspring of these combinations are often fertile. When crop

plants grow near wild plants to which they are related, they may

reproduce with these plants. This means that genetic material

inserted into a crop plant can find its way into wild plant

populations.

 

 

A recent article in SCIENCE reviews the literature on " ecological

risks and benefits " of genetically engineered crops and confirms

what advocates of precaution have been saying for years: we lack

basic information on how genetically engineered crops may affect

ecosystems.[16] Here are a few examples of what scientists do not

know about ecological effects of genetically engineered crops:

 

 

** No published studies have looked at whether novel genes

introduced into crops have become established in populations of

wild relatives.[16, pg. 2088]

 

 

** We know that BT toxin can be released from the roots of BT

corn plants, but no published studies have looked at the

ecological consequences of adding BT toxin to soil in this way.

[16, pg. 2089]

 

 

** As we have seen, BT toxin in the digestive systems of

plant-eating insects may affect the predator insects that eat

them. Right now it is impossible to model how an ecosystem might

change due to these effects on predators, the authors say.[16,

pg. 2089]

 

 

** Scientists are currently unable to estimate the likelihood

that planting genetically engineered virus-resistant crops will

lead to the development of new types of plant viruses. [16, pg.

2089]

 

 

A precautionary approach would require that we investigate these

questions before, rather than after, permitting large-scale

commercial cultivation of genetically engineered crops.

 

==============

*Rachel Massey is a consultant to Environmental Research

Foundation

 

 

[1] John E. Losey and others, " Transgenic Pollen Harms Monarch

Larvae. " NATURE Vol. 399, No. 6733 (May 20, 1999), pg. 214.

 

 

[2] Laura C. Hansen and John J. Obrycki, " Field Deposition of BT

Transgenic Corn Pollen: Lethal Effects on the Monarch Butterfly, "

OECOLOGIA Vol. 125, No. 2 (2000), pgs. 241-248.

 

 

[3] U.S. Environmental Protection Agency, " Biopesticide Fact

Sheet: BACILLUS THURINGIENSIS Cry1Ab Delta-Endotoxin and the

Genetic Material Necessary for Its Production (Plasmid Vector

pCIB4431) in Corn [Event 176], " April 2000. EPA Publication No.

730-F-00-003. Available at

http://www.epa.gov/pesticides/biopesticides/factsheets/fs006458t.htm.

 

 

 

[4] A. Hilbeck and others, " Effects of Transgenic BACILLUS

THURINGIENSIS corn-fed prey on Mortality and Development Time of

Immature CHYSOPERLA CARNEA (Neuroptera: Chrysopidae). "

ENVIRONMENTAL ENTOMOLOGY Vol. 27, No. 2 (April 1998), pgs.

480-487.

 

 

[5] Deepak Saxena and others, " Insecticidal Toxin in Root

Exudates from BT Corn, " NATURE Vol. 402, No. 6761 (December 2,

1999), pg. 480.

 

 

[6] Royal Society of Canada, ELEMENTS OF PRECAUTION:

RECOMMENDATIONS FOR THE REGULATION OF FOOD BIOTECHNOLOGY IN

CANADA (Ottawa: Royal Society of Canada, January 2001). ISBN

0-920064-71-X. Available from the Royal Society at (Ottawa,

Canada) phone: (613) 991-6990 or at

http://www.rsc.ca/foodbiotechnology/-GMreportEN.pdf.

 

 

[7] Charles Benbrook, " Evidence of the Magnitude and Consequences

of the Roundup Ready Soybean Yield Drag from University-Based

Varietal Trials in 1998, " AgBioTech InfoNet Technical Paper #1,

July 13, 1999. Available at

http://www.biotech-info.net/RR_yield_drag_98.pdf.

 

 

[8] U.S. Environmental Protection Agency, " Pesticide and

Environmental Fate One Line Summary: Glyphosate, " May 6, 1993.

 

 

[9] See T. B. Moorman and others, " Production of Hydrobenzoic

Acids by BRADYRHIZOBIUM JAPONICUM strains after treatment with

glyphosate. " JOURNAL OF AGRICULTURAL AND FOOD CHEMISTRY Vol. 40

(1992), pgs. 289-293. For a review of other relevant studies, see

Caroline Cox, " Herbicide Factsheet: Glyphosate (Roundup) " JOURNAL

OF PESTICIDE REFORM Vol. 18, No. 3 (Fall 1998), updated October

2000, available at http://www.pesticide.org/gly.pdf

 

 

[10] R.J. Kremer and others, " Herbicide Impact on FUSARIUM spp.

and Soybean Cyst Nematode in Glyphosate-Tolerant Soybean. "

American Society of Agronomy study abstract, available at

http://www.biotech-info.net/fungi_buildup_abstract.html. Also see

University of Missouri press release, " MU Researchers Find Fungi

Buildup in Glyphosate-Treated Soybean Fields " (December 21,

2000), available at

http://www.biotech-info.net/fungi_buildup.html.

 

 

[11] David Barboza, " Suburban Genetics: Scientists Searching for

a Perfect Lawn, " NEW YORK TIMES July 9, 2000, pg. A1.

 

 

[12] Lennart Hardell and Mikael Eriksson, " A Case-Control Study

of Non-Hodgkin Lymphoma and Exposure to Pesticides, " CANCER Vol.

85, No. 6 (March 15, 1999), pgs. 1353-1360.

 

 

[13] Lance P. Walsh and others, " Roundup Inhibits Steroidogenesis

by Disrupting Steroidogenic Acute Regulatory (StAR) Protein

Expression, " ENVIRONMENTAL HEALTH PERSPECTIVES Vol. 108, No. 8

(August 2000), pgs. 769-776.

 

 

[14] M. Crawley and others, " Transgenic Crops in Natural

Habitats. " NATURE Vol. 409, No. 6821 (February 8, 2001), pgs.

682-683.

 

 

[15] Jane Rissler and Margaret Mellon, THE ECOLOGICAL RISKS OF

ENGINEERED CROPS (Cambridge, Mass.: MIT Press, 1996).

 

 

[16] L. L. Wolfenbarger and P.R. Phifer, " The Ecological Risks

and Benefits of Genetically Engineered Plants. " SCIENCE Vol. 290

No. 5499 (December 15, 2000) pgs. 2088-2093.

 

.

RACHEL'S ENVIRONMENT & HEALTH NEWS #719 .

---March 1, 2001--- .

 

BIOTECH--THE BASICS, FINAL PART

 

 

by Rachel Massey*

 

 

Biotechnology corporations want people in the U.S. and around the

world to believe that the U.S. government has fully tested

genetically engineered crops for ecological and human health

hazards. Three federal agencies -- U.S. Food and Drug

Administration (FDA), U.S. Department of Agriculture (USDA), and

U.S. Environmental Protection Agency (EPA) -- have responsibility

for genetically engineered foods, but there is no guarantee that

a genetically engineered food sold in the U.S. has been tested

for ecological or human health effects. In the rush to promote

genetic engineering, safety testing has fallen through the

cracks.

 

 

 

Biotechnology corporations also want us to believe that

genetically engineered foods have been embraced by the public. In

fact, genetically engineered foods are not labeled, so the public

has no knowledge -- and no choice -- about purchasing and eating

them.

 

 

U.S. Food and Drug Administration

 

 

The U.S. Food and Drug Administration (FDA) issued its basic

policy statement on genetically engineered foods in 1992. Under

this policy, FDA considers genetically engineered foods to be

" generally recognized as safe " (GRAS), unless in the judgment of

the manufacturer there is some reason for concern.[2, pg. 22990]

Foods considered GRAS are not subject to pre-market safety

testing.

 

 

FDA states that the need for safety testing depends on the

characteristics of a food, not on the methods used to produce it.

In other words, the fact that a food was produced using genetic

engineering is not sufficient to trigger safety tests.[2, pgs.

22984-5]

 

 

FDA's 1992 policy says that a genetically engineered food must be

labeled if it " differs from its traditional counterpart such that

the common or usual name no longer applies to the new food, or if

a safety or usage issue exists to which consumers must be

alerted. " [2, pg. 22991] For example, it says a tomato containing

peanut genes might need to be labeled so that people with peanut

allergies could avoid it.[2, pg. 22991] But FDA allows

biotechnology corporations to decide whether a hazard of this

sort exists. Under FDA's no-labels policy, we can find out the

fat, cholesterol, sodium, potassium, carbohydrate, and protein

content of our breakfast cereal but we can't find out whether it

contains antibiotic-resistance genes, viral promoters, or

proteins normally produced only by bacteria. (See REHN #716,

#717, #718.)

 

 

In 1998 a coalition of non-governmental organizations,

scientists, and others filed a lawsuit against FDA for failing to

fulfill its regulatory duties. During the suit, FDA was forced to

release internal documents that showed FDA staff scientists had

strongly opposed the 1992 policy.[3] (See REHN #685.)

 

 

The lawsuit also forced FDA to release details of its safety

evaluation of the first genetically engineered food that entered

U.S. supermarkets, the Flavr Savr tomato. Calgene, the company

that developed the Flavr Savr, submitted three safety tests to

FDA in which rats were fed engineered tomatoes. After

twenty-eight days of the Flavr Savr tomato diet, researchers

examined the rats' stomachs. The three studies produced

inconsistent results that Calgene was unable to explain. The

first study showed no unusual effects. In the second study, some

of the rats fed genetically engineered tomatoes developed gastric

erosions (damage to the lining of the stomach). In the third

study, gastric erosions appeared in some of the rats fed

genetically engineered tomatoes AND in some of the rats fed

ordinary tomatoes.[4]

 

 

Calgene concluded these stomach problems were unrelated to eating

genetically engineered tomatoes, but it had no explanation for

why they appeared. An FDA staff scientist who reviewed Calgene's

data said there were " doubts as to the validity of any scientific

conclusion(s) which may be drawn from the studies' findings, "

because Calgene could not explain the variations in results among

the three tests.[4] In spite of the doubts expressed by its own

staff, FDA categorized the Flavr Savr tomato as GRAS and approved

it for sale. (The Flavr Savr did not sell well, so it has

disappeared from stores.)[1, pgs. 83-84]

 

 

In January 2001, the FDA proposed new regulations on genetically

engineered food. These proposed regulations still fail to require

either pre-market safety testing or labeling of genetically

engineered foods.[5] FDA says " there does not appear to be any

new scientific information that raises questions about the safety

of bioengineered food currently being marketed, " and states once

again that genetically engineered foods are " generally recognized

as safe. " [6, pgs. 4708-9]

 

 

To make this claim, FDA had to ignore scientific information that

had been brought to its attention explicitly during the previous

year. In March 2000, the Center for Food Safety and partner

organizations filed a legal petition asking FDA to start

requiring pre-market safety testing, environmental impact

assessments, and labeling for all genetically engineered foods.

The petition included a thorough review of new scientific

evidence on safety concerns associated with genetic

engineering.[7]

 

 

The main new requirement in FDA's proposed regulations is that

producers of genetically engineered foods must notify FDA 120

days before bringing a new genetically engineered food to market.

This notification, known as a pre-market biotechnology notice

(PBN), would include various information, such as whether the

product contains antibiotic-resistance marker genes and whether

it is likely to produce allergic reactions. FDA says it will make

a list of PBNs available to the public, but the list may not be

complete. In some cases, FDA says, the existence of a PBN could

be considered " confidential commercial information. " [6, pg.

4723] As a result, under the proposed regulations a company could

market a genetically engineered food without any public

notification. FDA's proposed regulations are open for public

comment until April 3, 2001.[5]

 

 

FDA has also proposed to create non-binding guidance for

voluntary labeling. This guidance is clearly not intended for

companies using genetically engineered crops, which have nothing

to gain by telling consumers what is in their food. Instead, the

guidance undermines consumers' right to know what they are buying

and threatens to limit the free speech of organic and other food

producers, by discouraging the use of labels with phrases such as

" biotech free " or " no genetically engineered materials. " FDA says

these labels will be misleading on most foods, because ordinary

food could be contaminated with the products of genetic

engineering. In addition, FDA says these phrases could imply that

non-engineered food is superior to engineered food, which, FDA

says, would be misleading.[8, pg. 4840]

 

 

U.S. Department of Agriculture

 

 

Under the Federal Plant Pest Act, the U.S. Department of

Agriculture (USDA) is responsible for regulating " plant pests " --

organisms that could cause harm to a plant. USDA considers

genetically engineered plants to be possible plant pests if they

contain genetic material from organisms, such as some bacteria,

included on an official list of plant pests.[1, pg. 109] Plants

engineered without the use of genes from a recognized plant pest

may escape USDA regulation entirely. Even when genes from a plant

pest are involved, the manufacturer has discretion to decide

whether the engineered plant is itself a plant pest. USDA does

not tell manufacturers what data to take into account when they

make this decision.[1, pgs. 110-111]

 

 

Under USDA's rules, genetically engineered crops that are

considered plant pests must first be approved for field testing

before they are approved for commercial planting. After

conducting field tests, the developer of a genetically engineered

crop can apply for " nonregulated status, " under which the crop

can be planted commercially with no further oversight from USDA.

USDA leaves it up to the developer to decide what data to submit

in support of its application for nonregulated status.[1, pg.

111] According to a recent article in AMERICAN SCIENTIST, many

tests that companies submit to USDA are poorly designed, so they

are unlikely to reveal any adverse effects that may occur.[9]

 

 

U.S. Environmental Protection Agency

 

 

As we saw in REHN #716, crops can be engineered to kill certain

insects by adding a gene derived from the bacterium BACILLUS

THURINGIENSIS (Bt). Under its authority to regulate pesticides,

the U.S. Environmental Protection Agency (EPA) is responsible for

evaluating the health and environmental consequences of these

engineered plants, which are, themselves, pesticidal.

 

 

EPA has registered pesticidal crops for five years, but the

agency makes these registration decisions on a case-by-case

basis; it does not have a standard testing system tailored to the

hazards posed by genetically engineered crops.[1, pg. 176] EPA

says it is reviewing existing registrations for Bt corn and

cotton this year, in order to decide whether it is safe to

continue growing them.[10]

 

 

When EPA registers a chemical pesticide for use on food crops, it

establishes a tolerance level -- an amount of pesticide residue

that is allowable on food. However, thus far EPA has exempted all

pesticidal crops from this requirement.[1, pg. 106]

 

 

Pesticidal crops are likely to promote the development of Bt-

resistant pest populations. (See REHN #637, #718.) Despite ample

scientific knowledge about this danger, EPA waited until December

1999 to issue requirements for resistance management. Under these

requirements, companies selling Bt corn are responsible for

making sure that farmers grow " refuges " of ordinary corn

alongside their pesticidal crops. The idea is that some pest

insects will eat only the ordinary corn, so they will be

sheltered from the evolutionary pressure that promotes the

development of resistant pest populations.[1, pgs. 106-7]

 

 

In the past five years, corporations have introduced a powerful

new technology into our food system without understanding the

basics of how this technology works. Government agencies have

refused to gather crucial data on how this technology can affect

ecosystems and human health. Once again, we are flying blind.

 

 

==============

 

 

*Rachel Massey is a consultant to Environmental Research

Foundation.

 

 

[1] Thomas O. McGarity and Patricia I. Hansen, BREEDING DISTRUST:

AN ASSESSMENT AND RECOMMENDATIONS FOR IMPROVING THE REGULATION OF

PLANT DERIVED GENETICALLY MODIFIED FOODS. Report prepared for the

Food Policy Institute of the Consumer Federation of America,

January 11, 2001. Available at http://-

www.biotech-info.net/Breeding_Distrust.html.

 

 

[2] U.S Food and Drug Administration (FDA), " Statement of Policy:

Food Derived from New Plant Varieties, " FEDERAL REGISTER Vol. 57,

No. 104, May 29, 1992, pgs. 22984-23005. Available at

http://vm.cfsan.fda.gov/~lrd/fr92529b.html

 

 

[3] Marion Burros, " Documents Show Officials Disagreed on Altered

Food, " NEW YORK TIMES December 1, 1999. Available at

http://www.biotech-info.net/officials_disagree.html.

 

 

[4] Fred A. Hines, " FLAVR SAVR Tomato (Pathology Review PR-152;

FDA Number FMF-000526): Pathology Branch's Evaluation of Rats

with Stomach Lesions from Three Four-Week Oral (Gavage) Toxicity

Studies (IRDC Study Nos. 677-002, 677-004, and 677-005) and an

Expert Panel's Report. " Memo to Linda Kahl, Biotechnology Policy

Branch, June 16, 1993. Available at

http://www.bio-integrity.org/FDAdocs/17/fhlkp.pdf

 

 

[5] See Joseph Mendelson, " The Food and Drug Administration's New

Proposal on Genetically Engineered Foods: First Draft Analysis, "

January 17, 2001. Available at http://-

www.centerforfoodsafety.org/facts & issues/-

CFSNewFDAAnalysis.html?cam_id=70. Also see this web site for

information on writing to FDA about the proposed regulations.

 

 

[6] U.S. Food and Drug Administration (FDA), " Premarket Notice

Concerning Bioengineered Foods, " FEDERAL REGISTER Vol. 66, No.

12, January 18, 2001, pgs. 4706-4738. Available at http://-

www.centerforfoodsafety.org/FRPremarketNotice.html?cam_id=70.

 

 

[7] Center for Food Safety and others, " Citizen Petition Before

the United States Food and Drug Administration. " Available at

http://www.centerforfoodsafety.org/li/FDApetition.html.

 

 

[8] U.S. Food and Drug Administration (FDA), " Draft Guidance for

Industry: Voluntary Labeling Indicating Whether Foods Have or

Have Not Been Developed Using Bioengineering; Availability, "

FEDERAL REGISTER Vol. 66, No. 12, January 18, 2001, pgs.

4839-4842. Available at http://www.centerforfoodsafety.org/-

FRVolLabel.html

 

 

[9] Michelle Marvier, " Ecology of Transgenic Crops, " AMERICAN

SCIENTIST Vol. 89, No. 2 (March-April, 2001), pgs. 160-167.

Available at http://americanscientist.org/articles/01articles/-

Marvier.html.

 

 

[10] See Union of Concerned Scientists, " Bt Crop Renewals, "

http://www.ucsusa.org/food/btcrops.html.

 

 

Thanks to Charles Benbrook, Caroline Cox, Michael Hansen, Ellen

Hickey, Sheldon Krimsky, and Joseph Mendelson for reviewing

portions of this series.

 

 

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