[CTRL] How the Terminator terminates: an explanation for the non-scientist of a remarkable patent for killing second generation seeds of crop plants

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<A HREF="http://www.bio.indiana.edu/people/terminator.html">How the Terminator
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How the Terminator terminates:

an explanation for the non-scientist of a remarkable patent for killing
second generation seeds of crop plants



by

Martha L. Crouch, Associate Professor of Biology
Indiana University
Bloomington, Indiana, USA
[EMAIL PROTECTED]

This paper is one in a series of essays meant to stimulate and inform
discussion of the subject. The author invites readers to correspond with
her directly if they have comments or questions about her interpretation
of the Terminator patent.

revised edition©1998





an occasional paper of

The Edmonds Institute
20319-92nd Avenue West
Edmonds, Washington 98020
USA



published with the help of grants from:

The HKH Foundation
The Funding Exchange
C.S. Fund





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Introduction

Genetically modified organisms (GMOs) have become a commercial reality
in agriculture. For example, it is estimated that in 1998 over 18
million acres in the United States will be planted in Roundup Ready®
soybeans, which were first introduced in 1996 (Horstmeier 1998). These
soybeans are engineered by Monsanto Corporation to contain a bacterial
gene that confers tolerance to the herbicide glyphosate, or Roundup® ,
also made by Monsanto. Only two years after the introduction of Roundup
Ready® soybeans, over 30% of the corn and soybeans planted in the United
States, and close to 50% of the canola planted in Canada, have been
genetically engineered to be either herbicide or pesticide resistant.

Monsanto and the other companies that have invested heavily in
biotechnology in the last two decades are starting to make some money
after years of promises without products, and they are aggressively
protecting their patented seeds. In a recent issue of the Farm Journal
 (Monsanto 1997), Monsanto ran a full page advertisement asking farmers
to respect the company's property rights:

It takes millions of dollars and years of research to develop the
biotech crops that deliver superior value to growers. And future
investment in biotech research depends on companies' ability to share in
the added value created by these crops. Consider what happens if growers
save and replant patented seed. First, there is less incentive for all
companies to invest in future technology, such as the development of
seeds with traits that produce higher-yielding, higher-value and
drought-tolerant crops....In short, these few growers who save and
replant patented seed jeopardize the future availability of innovative
biotechnology for all growers. And that's not fair to anyone.

In the future, companies and government breeders who genetically
engineer crops may not have to ask for such compliance. If the procedure
outlined in a recent patent comes to fruition and is widely used, plant
variety protection will be biologically built into the plants
themselves.

In March of 1998, a seed company later to be purchased by Monsanto,
Delta and Pine Land Company, in collaboration with the United States
Department of Agriculture, was awarded U.S. Patent Number 5,723,765:
Control of Plant Gene Expression. Although the patent is broad and
covers many applications, one application favored by the patent's
authors is a scheme to engineer crops to kill their own seeds in the
second generation, thus making it impossible for farmers to save and
replant seeds.

This "invention" has been dubbed the "Terminator Technology" by Rural
Advancement Foundation International (RAFI), and that group of
researchers have analyzed some of the technology's serious social,
economic and environmental implications (RAFI 1998). However, many of
the consequences of Terminator cannot be fully appreciated without an
understanding of the science behind the invention. In this paper, I
outline the steps involved in engineering Terminator Technology into a
specific crop. After explaining the process, I then discuss which
details might have the devil in them.



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Overview

To help describe the Terminator procedure, I have confined the
explanation to only one of the many possibilities covered by the patent.
The example I have chosen is cotton seed, which previously has been
genetically-engineered with a unique trait, herbicide tolerance. In my
discussion, I have assumed that to ensure that the descendants of the
herbicide tolerant seeds are not used without compensation to the seed
company, the company has additionally genetically engineered the cotton
with Terminator. Although this is a hypothetical case -- Terminator
cotton is not yet on the market, after all -- all the components of the
procedure have been shown to function, at least in the text of the
patent for Terminator.

Cotton is not often sold as a hybrid seed, and is thus a likely
candidate for Terminator protection. By way of contrast, corn is usually
planted as a hybrid, and thus has some measure of variety protection
already. This is because the first generation of a hybrid is genetically
fairly uniform, and has been bred to have desired characteristics that
are not present in either parent alone. When these hybrids make seeds,
however, the second generation is quite variable because of the
shuffling of genes that occurs during sexual reproduction. Industrial
agriculture requires uniformity, because the plants must dovetail with
mechanization. Therefore, industrial farmers who grow corn usually buy
new seed every year.

There are several major crops which usually are not grown from hybrid
seeds. These include wheat, rice, soybeans, and cotton. Farmers often
save the seeds from these crops, and may not go back to the seed company
for several years--or longer, in some parts of the world-- to purchase a
new variety.

It would be a big boost to seed company profits if people who now grow
non-hybrid crops would have to buy new seed every year. This may have
been the major incentive for developing the Terminator Technology.

There likely were other reasons for developing Terminator. One reason
may relate to the way in which Terminator's effect differs from
hybridization. When Terminator is used, the second generation is killed.
With hybridization, the second generation is variable, but alive; and
any genes present in the hybrid will be present in the second
generation, although in unpredictable combinations. Therefore, a plant
breeder who wanted to use the genetic material from the hybrid in his or
her own breeding program could retrieve it from these plants. With
Terminator, the special genes, such as the herbicide tolerance of my
example, would not be easily available for use by competitors.

Another reason sometimes cited for using Terminator in combination with
a genetically-engineered variety is to keep the GMOs from "escaping"
into the environment. Many critics of biotechnology cite problems with
releasing GMOs into the wild, noting that their effects on ecosystems
and their members would be difficult to predict (Rissler and Mellon
1996). Having all of the second generation seeds die would circumvent
this problem altogether.



Rough Sketch and Review

Terminator is a complicated process to understand and it helps to review
beforehand some of the basic information about how genes function during
the life-cycle of a plant. Readers with a good grasp of molecular
biology may want to skip the review section (A simplified version of
basic biological processes) following the general description and
proceed directly to the details of the Terminator Technology.



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General Description of Terminator in Cotton

In the cotton example, the goal is to develop a variety of cotton that
will grow normally until the crop is almost mature . Then, and only
then, a toxin will be produced in the (seed) embryos, specifically
killing the entire next generation of seeds.

The system has three key components: 1. A gene for a toxin that will
kill the seed late in development, but that will not kill any other part
of the plant. 2. A method for allowing a plant breeder to grow several
generations of cotton plants, already genetically-engineered to contain
the seed-specific toxin gene, without any seeds dying. This is required
to produce enough seeds to sell for farmers to plant. 3. A method for
activating the engineered seed-specific toxin gene after the farmer
plants the seeds, so that the farmer's second generation will be killed.

These three tasks are accomplished by engineering a series of genes,
which are all transferred permanently to the plant, so that they are
passed on via the normal reproduction of the plant.



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A simplified version of basic biological processes

A plant starts life as a single cell, an egg that has been fertilized by
sperm which has been delivered to the egg by the pollen. This first cell
divides many times to form the tissues and organs characteristic of the
species. The process of going from a single cell to an adult is called
development. As development proceeds, cells become different from each
other and change. Cells in the leaf become distinct from cells in the
root, for example. Most of the differences can be attributed to changes
in the kinds and amounts of proteins made in the cells, because many of
the structures in cells are made of proteins, and most of the processes
that occur are influenced by enzymes, which are also proteins. Thus,
scientists who study development spend a lot of effort describing
protein patterns.

By studying which proteins are present in different tissues and organs,
biologists have learned that each cell has several thousand different
proteins, but most of the proteins are very rare in the cell. A few
hundred proteins may be moderately abundant, and a few may be quite
abundant. Also, some proteins are found in all kinds of cells and at all
times in development, whereas other proteins are only present in a
particular tissue, or at a specific time. For example, the gluten
proteins responsible for the elasticity of bread dough are found only in
the seed,and are present there in very large amounts. In contrast, the
enzyme that splits glucose as a first step in releasing energy is found
in all living cells, but in fairly small amounts.

Some proteins are made in response to environmental changes, such as
increases in temperature, and thus may or may not be present during the
life of a particular plant.

The most common way for a cell to control how much of which kinds of
proteins are present is to control which genes are functioning
(Rosenfeld et al. 1983). Proteins are chains of different amino acids,
and the order of amino acids and the length of the chain are unique for
each kind of protein. Each unique amino acid sequence is specified by a
code on a chromosome in the cell's nucleus. The code is made of DNA. For
the purposes of this discussion, a gene is a piece of DNA that contains
the code for a specific protein. Genes are present in specific places
along the length of the chromosomes.

It turns out that just about every cell has two full sets of genes (one
set of chromosomes from the sperm and one from the egg), which code for
the proteins made in all of the tissues and organs that an individual
plant will need during its life cycle. However, only those genes whose
proteins are needed in a particular cell will be used by that cell.
These are the active genes. The other genes just sit there on the
chromosomes, inactive in that cell, but active somewhere else in the
plant.

Whether a gene is active or not depends on complex interactions between
the DNA and other molecules in the cell. Specifically, a typical gene
can be divided into parts. The first part is a stretch of DNA
responsible for interacting with the cell or the environment, and is
called the promoter. The second part actually contains the code for the
order of amino acids in the protein, and is called the coding sequence.
When the gene is active, the promoter is interacting with other
molecules in a way that allows the coding sequence to direct the
synthesis of a specific protein (through a complex set of steps).

Genetic engineering can be defined as the process of manipulating the
pattern of proteins in an organism by altering genes. Either new genes
are added, or existing genes are changed so that they are made at
different times or in different amounts.

Because the genetic code is similar in all species, genes taken from a
mouse can function in a corn plant; and so on. Also, promoters from one
coding sequence can be removed and placed in front of another coding
sequence to change when or where the protein is made. For example, when
the promoter for casein, the major protein in milk, is removed and put
in front of the coding sequence for human growth hormone, it causes
human growth hormone to be made in cow's milk instead of casein. Of
course, in order to make human growth hormone in cow's milk, the
engineered gene has to be incorporated into the genetic material of the
cow. There are many ways to do this. I will not go into the details
here.

The general process of moving genes between species is called
transformation, and the result is a transgenic organism. Lately,
transgenic organisms are being called genetically modified organisms, or
GMOs.



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Details of the Terminator technology

The key to Terminator is the ability to make a lot of a toxin that will
kill cells, and to confine that toxin to seeds.

To accomplish this, in the case of our cotton example, the plan is to
take the promoter from a gene normally activated late in seed
development in cotton, and to fuse that promoter to the coding sequence
for a protein that will kill an embryo going through the last stages of
development.

In the Terminator patent, the authors use a promoter from a cotton LEA
(Late Embryogenesis Abundant) gene. This gene is one of the last to be
activated. Its protein is not made until the seed is full-sized, has
accumulated most of its storage oil and protein and is drying down in
preparation for the dormant period in between leaving the parent plant
and germinating in the soil. If the engineered gene has the same pattern
of expression, LEA-promoter-directed proteins should be made in high
quantities, only in seeds, and late in development. It is important for
the cotton seeds to go through most of their growth before the toxin
acts, because the cotton fiber is an outgrowth of the seed coat and is
made as the cotton develops. Further, after the cotton fibers are
 removed (for human use), the seed is then crushed for oil and protein,
both of which are eaten by people and livestock. The cotton crop would
be of little use to a farmer if the seeds did not mature normally before
dying.

As for a toxin, there are several possibilities discussed in the patent,
but the patent authors recommend a ribosome inhibitor protein (RIP) from
the plant Saponaria officinalis. This protein works is small quantities
to stop the synthesis of all proteins. Since cells need proteins for
almost everything, they die fairly quickly when they can't make
proteins. According to the patent, the RIP is non-toxic to organisms
other than plants.

The manipulations of DNA required to engineer a seed-specific
promoter/toxin coding sequence gene are done in test-tubes and bacteria,
and then the altered gene is put into a cotton plant, using one of
several possible well-established methods.

However, this is not all there is to it. It this were all, then as soon
as the transgenic plant went through its life cycle and came around to
seed development, that would be the end of the project. There would soon
be no viable seeds to sell to farmers.

The Terminator patent offers an ingenious method for keeping the toxin
gene from being active until long after the farmers plant their crops.
The trick is accomplished by inserting a piece of DNA in between the
seed-specific promoter and the toxin coding sequence that blocks it from
being used to make protein.

At either end of the blocking DNA are put special DNA pieces that can be
recognized by a particular enzyme, such as the enzyme called
recombinase. Whenever the recombinase encounters these DNA pieces, the
DNA is cut precisely at the outside of each piece, and the cut ends of
the DNA fuse together, with the result that the blocking DNA is removed.
When this happens, the seed-specific promoter is right next to the toxin
coding sequence, and is able to function in making the toxin. But this
does not happen immediately. Toxin will not be produced until the end of
the next round of seed development, because that is when the LEA
promoter is active.

Thus, after the recombinase enzyme does its work, the plant grows
normally from germination, through growth of stems, leaves, roots, and
all the way through flower formation, pollination and most of seed
development. Then, on cue, the seeds die.

All this accomplished, there remains one more problem: How to grow
several generations of the genetically-engineered variety so that its
seed can be multiplied to sell to farmers?

The Terminator patent solves the dilemma by preventing recombinase from
acting until just before the farmers plant their seeds. The patent
holders give several possible ways to do this, but concentrate on the
following procedure: They propose putting a recombinase coding sequence
next to a promoter that is always active -- in all cells, at all times
-- but that is repressed. The promoter can be made active again --
derepressed -- by a chemical treatment. Therefore, the seed sellers can
treat the seeds right before planting, thus allowing the recombinase to
be made then, but not before.

One of the repressible promoter systems they discuss in detail is
controlled by the antibiotic tetracycline. A gene that makes a repressor
protein all of the time would be put into the cotton plant, along with a
recombinase gene that has a promoter engineered to be inactivated by the
repressor protein. Under most conditions, then, the repressor would
interact with the recombinase gene; no recombinase would be made; the
toxin gene would be blocked; and no toxin would be made, even during
seed development when the LEA promoter normally would be active.

To activate the toxin gene, seeds just starting to germinate would be
treated with tetracycline, right before they are sold to farmers. The
tetracycline would interact with the repressor protein, keeping it from
interfering with production of recombinase. Recombinase would be made,
cutting out the blocking DNA from the toxin gene. The toxin gene would
now be capable of making toxin, but would not actually do so until the
end of seed development. The next generation would thus be killed.

To accomplish the Terminator effect in cotton, then, three engineered
components must all be transferred into a cotton plant's DNA:

1. a toxin gene controlled by a seed-specific promoter, but blocked by a
piece of DNA in between the promoter and the coding sequence;

2. a repressor protein coding sequence with a promoter that is active
all of the time; and

3. a recombinase coding sequence, controlled by a promoter that would be
active at all times, except that it is also regulated by repressor
protein, which can be overridden with tetracycline.

The actual transfer of genes into the plant is not a very precise
operation. Any one of a variety of methods can be used: the
genetically-engineered DNA can be injected into the nucleus of a cotton
cell with a tiny needle, or plants cells can be soaked in the DNA and
electrically shocked, or the DNA can be attached to small metal
particles and shot into the cells with a gun, or viruses and bacteria
can be engineered to infect cells with the DNA. In all cases, the
genetically-engineered DNA has to find its way to the nucleus, and
become incorporated into the plant chromosomes. The number of copies of
the inserted genes and their locations on the plant chromosomes are
unpredictable, and how well the new genes will function hangs in the
balance.

It takes a lot of effort to locate cells that have incorporated DNA in
significant amounts and in locations that work. Basically, whole plants
have to be regenerated from the cells or tissues that were transformed
with the foreign DNA, and then each plant has to be tested for the
presence and function of the new genes.

After plants with well-functioning new genes are identified, they are
then mated in combinations that result in a line of cotton where both
sets of chromosomes (in all of the offspring) have all the components
necessary for Terminator to function. These plants are mated together to
make a large quantity of seed for sale.

In effect, Terminator Technology gives the seed producer the ability to
determine when to set Terminator in motion. Until the recombinase is
made, the cotton plants grow normally. After recombinase is made, the
second generation of seeds is killed, protecting the patented variety.



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Some problems that may crop up with the use of Terminator

The patent on this technology is complex. I have described only one of
many possible applications of the procedure. Clearly, one cannot
determine ahead of time all possible biological ramifications of
implementing the patent. However, potential problems have already been
noted (Ho 1998). I deal with some of them below.

Will the Terminator spread to other plants?

It is likely that Terminator will kill the seeds of neighboring plants
of the same species, under certain conditions. However, the effects will
be confined to the first generation, and will not be able to spread to
other generations. The scenario might go like this: when farmers plant
the Terminator seeds, the seeds already will have been treated with
tetracycline, and thus the recombinase will have acted, and the toxin
coding sequence will be next to the seed-specific promoter, and will be
ready to act when the end of seed development comes around. The seeds
will grow into plants, and make pollen. Every pollen grain will carry a
ready-to-act toxin gene. If the Terminator crop is next to a field
planted in a normal variety, and pollen is taken by insects or the wind
to that field, any eggs fertilized by the Terminator pollen will now
have one toxin gene. It will be activated late in that seed's
development, and the seed will die. However, it is unlikely that the
person growing the normal variety will be able to tell, because the seed
will probably look normal. Only when that seed is planted, and doesn't
germinate, will the change become apparent.

In most cases, the toxin gene will not be passed on any further, because
dead plants don't reproduce. However, under certain conditions I will
discuss later, it is possible for the toxin gene to be inherited.

In any case, dead seeds, where they occur, would be a serious problem
for the farmer whose fields are close to the Terminator crop. How many
seeds die will depend on the degree of cross-pollination, and that is
influenced by the species of plant, the variety of crop, weather
conditions, how close the fields are to each other, and so on. If many
seeds die, it will make saving seed untenable for the adjacent farmer.
Even if only a few seeds die, they will contain the toxin and any other
proteins engineered into the Terminator-protected variety. These new
"components" may make the seed unusable for certain purposes.



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Will seeds containing the toxin made by Terminator be safe to eat?

In fact, the effects of the toxin on the uses of the seed are a serious
question. This issue is discussed in the patent at the end of page 8.
There the authors say that "[i]n cotton that would be grown commercially
only selected lethal genes could be used since these proteins could
impact the final quality of seeds....If the seed is not a factor in the
commercial value of a crop (e.g., in forage crops, ornamentals or plants
grown for the floral industry) any lethal gene should be acceptable."

This is dangerously reductionist thinking, because people are not the
only organisms that interact with seeds. In forage crops, for example,
not all of the forage is always harvested before seeds are mature,
depending on conditions. How will a particular toxin affect birds,
insects, fungi and bacteria that eat or infect the seeds? If a forage
crop with toxin-laden seeds is left in the field, and the seeds come in
contact with the soil, how will that affect the ecology of soil
organisms? These are important questions because a variety of specific
organisms are necessary for the healthy growth of plants. Further, a
floral or ornamental crop with Terminator may happen to grow near a
related crop where the seeds are used, and if pollination occurs, the
seeds will contain toxin without that farmer knowing. The toxin could
end up in products without anyone's knowledge. For example, an
ornamental sunflower could spread Terminator to an oilseed variety, and
then the toxin could end up in edible oil or in sunflower seed meal.

Other potential problems with making novel toxins in edible seeds have
to do with allergenicity. The RIP toxin described earlier may not be
directly poisonous to animals, but may cause allergic reactions. If the
seeds are being mixed with the general food supply, it will be difficult
to trace this sort of effect.



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Will dead seeds have different properties than living seeds?

Although Terminator is supposed to kill seeds very late in development,
it is not known what other effects, if any, Terminator may have. Will
the dead seeds be more or less easy to store? Perhaps they will respond
differently to changes in humidity, or to infection with bacteria and
fungi. If dead seeds do behave differently, even a few "bad apples may
spoil the barrel", and the problem of partial killing of neighbors'
crops may be even more of an issue.

There also may be nutritional changes in seeds that are killed late in
development. Although most of their oils and proteins are present, it is
possible that seeds will start to deteriorate or will lack some minor
component that is important. The functional properties of specific
molecules in foods, for example, are just beginning to be appreciated
and are likely to play important roles in preventing diseases. These
possibilities require further study.



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Will the use of an antibiotic to treat seeds before planting be a
problem?

If seed companies do indeed use tetracycline to set the cascade of
toxin-gene activation in motion, then they will have to soak a very
large amount of seed in the antibiotic. Basically, every seed planted by
the farmer will have to be so treated. How many pounds of cotton seed or
wheat seed are needed to plant an acre, and how many acres will be put
in? In fact, I am having trouble visualizing exactly how this will work,
because the seeds must be treated with tetracycline after they have
matured completely (so that the toxin won't be made in the first
generation), but before planting (otherwise, the farmer would have to
apply antibiotic to the plants). Handling seed that has been soaked
seems like a tricky process to me, but perhaps there are viable methods.
At any rate, even at low concentrations there will be a lot of
tetracycline to handle and dispose of, and large-scale agricultural uses
of antibiotics are already seen as a threat to their medical uses.
Further, the increased tolerance of bacteria, residual or waste
antibiotics may also have a harmful effect on soil ecology.

Again, I am dismayed by the reductionist tone of the discussion of these
issues in the patent. On page 7, line 30, the authors state that "since
tetracycline has no harmful effects on plants or animals, its presence
would not otherwise impede normal development of the plant, and residual
amounts left on the seed or plant after treatment would have no
significant environmental impact." Although it is true that tetracycline
has no direct effect on animals, such as humans, the indirect effects
can be severe. This is because we depend on a myriad of interactions
with microorganisms for our daily functioning, from proper digestion to
protection from pathogens. The patient information sheet that comes with
any prescription for tetracycline is convincing evidence that
 tetracycline is not harmless to use.

Plants too depend on microorganisms. They do not function normally
without a web of interactions, and indirect effects from substances like
tetracycline may prove to be important.



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Will Terminator prevent genetically modified organisms from escaping?

Clearly, farmers would not want plants genetically modified with
Terminator to spread into surrounding areas or to grow from seed as
unexpected "volunteers" in another season. They also would not want the
Terminator plants to exchange genes with other varieties or related
species. Interestingly, Terminator has been proposed as a method to
prevent just such escapes of GMOs and their genes. However, Terminator
is not likely to function well for such purposes.

First, it is unlikely that any tetracycline treatment will be 100%
effective. For various reasons, some seeds may not respond, or take up
enough tetracycline to activate recombinase. In such cases, the plants
growing from the unaffected seeds would look just like all the others,
but would grow up to make pollen carrying a non-functional toxin gene.
The pollen would also carry the genetically-engineered protein
supposedly being protected by Terminator, such as herbicide-tolerance.
If this pollen fertilized a normal plant, the seed would not die,
because no toxin would be made, but the seed would now have the
herbicide-tolerance gene and could pass that on. Thus a trait from the
GMO would have escaped through the pollen.

Of course, self-fertilized seeds of the Terminator line would also
survive in the second generation, if the tetracycline treatment failed,
and could be carried off by birds, or grow as "volunteers" the next
season.

Another possibility is that even successfully activated Terminator genes
may fail to make toxin because of a phenomenon called gene silencing. In
experiments with other GMOs, it was discovered - quite unexpectedly -
that in some cases, previously active (introduced) genes can suddenly
stop working. If this phenomenon occurred with seeds containing the
Terminator gene, plants containing the silenced toxin gene could grow
and reproduce, perhaps for several generations. Thus, Terminator and
other engineered genes could be carried into the future, to be expressed
-- perhaps still unexpectedly -- at some later time.

Depending on Terminator to prevent GMOs or their traits from spreading
unintentionally is unrealistic. "Escapes" are even more likely to occur
in some of the other patent applications, where the genetic components
of Terminator will reshuffle during sexual reproduction, and a portion
of the seeds will lack the toxin altogether, and thus be viable.



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Organisms are always changing; will Terminator mutate and change
characteristics is some dangerous way?

If plants were to carry silenced toxin genes, as described above, those
genes might suddenly be activated again, causing seeds to die
unpredictably in subsequent generations. By the time the phenomenon
occured, however, it might be difficult to ascribe the cause to
Terminator.

Another possibility is that the Terminator may be activated at a
different time or place in the plant. Fortunately, such events will be
self-limiting, because the plants will die. However, for farmers, the
instability and unpredictability of GMOs has already been an economic
problem. Genes have an ecology--a complex way of interacting with
themselves and the environment--that can interfere with the simple
linear logic of genetic engineering. A recent article in the Ecologist
discussed this problem in detail (Ho et al. 1998).



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Final thoughts

These are a few of the potential snags that I see in the use of
Terminator Technology. My analysis was based on the details of only one
of the applications described in the Terminator patent. I am confident
that some of the particular problems I have discussed will be addressed
by the seed industry before they implement the technology. However, I am
also sure that there will be other problems noone yet foresees or
imagines. There will be surprises. But whatever the potential biological
problems presented by Terminator, in my view they are small in
comparison to Terminator's economic, social, and political ramifications
(See RAFI 1998).





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References

Ho, Mae-Wan, 1998. Genetic Engineering: Dream or Nightmare? The Brave
New World of Bad Science and Big Business. Gateway Books, Bath, UK.

Ho, Mae-Wan, Hartmut Meyer and Joe Cummins, 1998. The biotechnology
bubble. The Ecologist 28, pp. 146-153.

Horstmeier, Greg D., 1998. Lessons from year one: experience changes how
farmers will grow Roundup Ready beans in '98. Farm Journal, January
1998, p. 16.

Monsanto Advertisement, 1997. Farm Journal, November 1997, B-25.

RAFI-Rural Advancement Foundation International, 1998. This organization
has written several press releases, communiques, and articles on
Terminator Technology. These can be accessed at RAFI's web site at
http://www.rafi.ca, or by writing to RAFI, 110 Osborne St., Suite 202,
Winnipeg MB R3L 1Y5, Canada.

Rissler, Jane and Margaret Mellon, 1996. The Ecological Risks of
Engineered Crops. The MIT Press, Cambridge, Massachusetts, US.

Rosenfield, Israel, Edward Ziff and Borin Van Loon, 1983. DNA for
Beginners. Writers and Readers, US.

United States Patent Number 5,723,765: Control of Plant Gene Expression,
issued on March 3, 1998 to Delta and Pine Land Co. and The United States
Department of Agriculture. Inventors: M.J. Oliver, J.E. Quisenberry,
N.L.G. Trolinder, and D.L. Keim.




-----
Aloha, He'Ping,
Om, Shalom, Salaam.
Em Hotep, Peace Be,
Omnia Bona Bonis,
All My Relations.
Adieu, Adios, Aloha.
Amen.
Roads End
Kris

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CTRL is a discussion and informational exchange list. Proselyzting propagandic
screeds are not allowed. Substance—not soapboxing!  These are sordid matters
and 'conspiracy theory', with its many half-truths, misdirections and outright
frauds is used politically  by different groups with major and minor effects
spread throughout the spectrum of time and thought. That being said, CTRL
gives no endorsement to the validity of posts, and always suggests to readers;
be wary of what you read. CTRL gives no credeence to Holocaust denial and
nazi's need not apply.

Let us please be civil and as always, Caveat Lector.

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