POISONS
may pass on their effect to other generations
Toxic chemicals that poisoned
your great-grandparents may also damage your health, US
research suggests. A team from Washington State
University has produced evidence that some inherited
diseases may be caused by poisons polluting the womb.
Research on rats indicates man-made environmental poisons
may alter genetic activity, giving rise to diseases that
pass down at least four generations. The research is
published in the journal Science.
The scientists exposed pregnant rats to
two agricultural chemicals during the period that the sex
of their offspring was being determined. The compounds
were vinclozolin, a fungicide commonly used in vineyards,
and the pesticide methoxychlor. Both are known as
endocrine disruptors - chemicals that interfere with the
normal functioning of reproductive hormones. Rats exposed
to the compounds produced male offspring with low sperm
counts and poor fertility. They were still able to
produce young, however. When these rats were then mated
with females that had not been exposed to the poisons,
their male offspring had the same problems. The effect
persisted through at least four generations, impairing
the fertility of more than 90% of male offspring in each
generation. The researchers found the damage was not
caused by alterations in the DNA code, but changes in the
way the genes work. These epigenetic changes, as they are
known, are caused by small chemicals that become attached
to the DNA, modifying its activity. Epigenetic changes
have been observed before - but were not previously known
to pass onto later generations. Cancer clue Lead
researcher Dr Michael Skinner believes they may
contribute to diseases such as breast cancer and prostate
cancer.
Both diseases are becoming more common,
and Dr Skinner says that cannot be down to genetic
mutations alone. The researchers believe their findings
suggest exposure to environmental toxins may play a key
role in the evolutionary process. Evolution may not be
driven entirely by genetic mutations, as commonly
thought. Dr Skinner said: "It is a new way to think
about disease. We believe this phenomenon will be
widespread and be a major factor in understanding how
disease develops." However, Dr Skinner stressed more
work was needed to corroborate the findings. The levels
of chemicals the rats were exposed to were very high -
much higher than people normally ever encounter.
Professor Alan Boobis, a toxicologist at Imperial College
London, UK, told the BBC News website the findings were
interesting, but he said there was no need for people to
be alarmed. "This effect is likely to be
concentration dependent, and these animals were exposed
to very high levels of chemicals," he said. "We
need to find out whether this trans-generational effect
is translated to much lower doses."
"Race is a vaguely defined biological, social and
political concept"
Scientists Find A DNA Change That Accounts For White
Skin
By Rick WeissWashington Post Staff
Writer
Friday, December 16, 2005; Page A01
Scientists said yesterday that they have discovered a
tiny genetic mutation that largely explains the first
appearance of white skin in humans tens of thousands of
years ago, a finding that helps solve one of biology's
most enduring mysteries and illuminates one of humanity's
greatest sources of strife.
The work suggests that the skin-whitening mutation
occurred by chance in a single individual after the first
human exodus from Africa, when all people were
brown-skinned. That person's offspring apparently thrived
as humans moved northward into what is now Europe,
helping to give rise to the lightest of the world's
races.
Leaders of the study, at Penn State University, warned
against interpreting the finding as a discovery of
"the race gene." Race is a vaguely defined
biological, social and political concept, they noted, and
skin color is only part of what race is -- and is not.
In fact, several scientists said, the new work shows
just how small a biological difference is reflected by
skin color. The newly found mutation involves a change of
just one letter of DNA code out of the 3.1 billion
letters in the human genome -- the complete instructions
for making a human being.
"It's a major finding in a very sensitive
area," said Stephen Oppenheimer, an expert in
anthropological genetics at Oxford University, who was
not involved in the work. "Almost all the
differences used to differentiate populations from around
the world really are skin deep."
The work raises a raft of new questions -- not least
of which is why white skin caught on so thoroughly in
northern climes once it arose. Some scientists suggest
that lighter skin offered a strong survival advantage for
people who migrated out of Africa by boosting their
levels of bone-strengthening vitamin D; others have
posited that its novelty and showiness simply made it
more attractive to those seeking mates.
The work also reveals for the first time that Asians
owe their relatively light skin to different mutations.
That means that light skin arose independently at least
twice in human evolution, in each case affecting
populations with the facial and other traits that today
are commonly regarded as the hallmarks of Caucasian and
Asian races.
Several sociologists and others said they feared that
such revelations might wrongly overshadow the prevailing
finding of genetics over the past 10 years: that the
number of DNA differences between races is tiny compared
with the range of genetic diversity found within any
single racial group.
Even study leader Keith Cheng said he was at first
uncomfortable talking about the new work, fearing that
the finding of such a clear genetic difference between
people of African and European ancestries might reawaken
discredited assertions of other purported inborn
differences between races -- the most long-standing and
inflammatory of those being intelligence.
"I think human beings are extremely insecure and
look to visual cues of sameness to feel better, and
people will do bad things to people who look
different," Cheng said.
The discovery, described in today's issue of the
journal Science, was an unexpected outgrowth of studies
Cheng and his colleagues were conducting on inch-long
zebra fish, which are popular research tools for
geneticists and developmental biologists. Having
identified a gene that, when mutated, interferes with its
ability to make its characteristic black stripes, the
team scanned human DNA databases to see if a similar gene
resides in people.
To their surprise, they found virtually identical
pigment-building genes in humans, chickens, dogs, cows
and many others species, an indication of its biological
value.
GM Contamination
Accelerating
No Co-Existence Possible
Untried and untested GM crops are out of
the bottle even in the UK where no GM crops are
commercially grown. Rhea Gala
A fully
referenced version of this article is
posted on ISIS members’ website. Details here
GM crops, the vast majority engineered for
just two traits - herbicide tolerance and Bt
pesticide, or stacked with both - have been
released on five continents for up to nine years,
causing widespread contamination of food, feed,
seed and the environment across the globe.
Genetically modified DNA from any part of a GM
plant can enter the environment unobserved, for
example, through pollen transfer to a
conventional crop, through seed dispersal or
plant decomposition and persistence in soil
ecology. The toxins encoded in the DNA also
kill wildlife and contaminate soil and water, as
do herbicides such as glyphosate and glufosinate
ammonium that are an essential component of the
herbicide tolerant crop system.
Outcrossing between a GM crop plant and
a wild relative and over dependence of the GM
crop on herbicides to which the crop is tolerant,
are causing a wave of “superweeds” to
emerge in the US and elsewhere; the UK has
reported a potential candidate earlier this
year.
UK’s herbicide tolerant weed hybrids
The UK government reported genetically
modified herbicide tolerant (GMHT) hybrid weed
seedlings at field trial sites earlier this year.
One was a cross between Bayer’s GMHT oilseed
rape (Brassica napus) and its distant
relative the common arable weed, charlock (Sinapis
arvensis), and two were hybrids of Brassica
napus and B. rapa.
The findings, which were not announced, were
nevertheless widely reported and somewhat
exaggerated in the press [1] because many
politicians and government scientists had
repeatedly downplayed the possibility of GM gene
transfer to wild relatives, the emergence of GM
superweeds, or any other adverse effects of GM
crops. For example, in 2000 the EU
Environment agency concluded, “ There
appears to be general agreement that natural gene
flow is not likely to occur between B. napus
and S. arvensis”. The EU has an
industry-sponsored forward plan for
‘coexistence’ in European countries for
GM, conventional and organic crops to 2025
(“Beware the New Biotech Eurovision” SiS
24).
The report to DEFRA from the Centre for
Ecology and Hydrology, Dorset, found that
[2], “The commercial growing of
genetically modified, herbicide- tolerant oilseed
rape is seen to result in the potential for the
inserted gene to escape from the crop and become
incorporated in the genomes of one or more
related wild crucifer species, potentially giving
a competitive advantage to the recipients.”
The “virtually impossible” already
happened
The emergence of two GMHT B. napus and B.
rapa hybrids was inevitable as B. rapa
is a parent of the commercial variety B. napus
and spontaneous hybrids are well known to
occur. Although the two plants generally do
not share the same distribution, B. rapa
may be overlooked because of its similarity to
feral oilseed rape. The finding of these
hybrids and the GMHT charlock hybrid show that
the difficulties of coexistence between GM and
conventional crops will be insuperable. Despite
that, the authors still concluded, “The
risks of transfer of herbicide tolerance to wild
relatives of oilseed rape appear to be
minimal.” But Dr Brian Johnson, an
ecological geneticist and head of the Biotech
Advisory Unit at English Nature, said that the
charlock superweed would be fertile through its
pollen to neighbouring plants [1]; and that
charlock seeds can remain in the soil for 20 to
30 years before they germinate.
Huge problems of cross- contamination and
herbicide resistance have arisen in countries
like Canada and the US (see for example “GM
sugar beet turned sour”, SiS
25; “Roundup Ready sudden death”, SiS28).
Herbicide tolerant volunteers
Herbicide tolerant volunteers were found in
the two years following the Farm Scale
Evaluations, and they tend to persist, requiring
control with toxic herbicides other than
glufosinate ammonium. The authors thought
that volunteers may pose a greater risk for gene
flow of the bar gene into the environment,
than hybridization with wild relatives,
especially if the same gene construct is
introduced into other crop species. They
also pointed out that these problems
“highlight implications for the EU threshold
limits of GM content in oilseed rape crops set at
0.1 percent, 0.3 percent and 0.9 percent for
organic seed, certified seed and food & feed,
respectively” [2].
GM contamination lasts at least 15 years in
soil
The BRIGHT report [3] on a study in the UK
begun in 1998 with funding from Monsanto, Bayer
CropScience, BASF, and Agrovista UK Ltd, among
others, tried to underplay problems to wildlife
from GM crops; but found that when HTGM sugar
beet followed HTGM winter oilseed rape,
additional herbicides were needed to control
volunteer rape.
There were also problems with crossbreeding
between herbicide tolerant varieties of rape,
producing seeds resistant to more than one
herbicide, and making management of minimal
herbicide regimes very tricky even for
experienced practitioners.
The authors of BRIGHT have since looked
further into the problem of persistence of GM
seeds in seedbanks in a new study on the
population dynamics of volunteer rape, Brassica
napus, comparing two GMHT winter oilseed rape
cultivars and two conventional cultivars
[4].
They found that seed remaining in the field
after harvest averaged 3 575 seeds per square
metre but ranged from less than 2 000 up to more
than 10 000 seeds. There was a rapid decline in
seed number during the first few months after
harvest; a mean loss of 60 percent of seeds
thought to be removed by wildlife. But in
subsequent seasons, the seedbank declined much
more slowly at four of the five sites, at about
20 percent per year. The models predicted a
95 percent seed loss after approximately nine
years, resulting in nearly 200 seeds per square
metre, which would give rise to at least two HT
rape volunteers nine years after the original
crop was sown. This predicts the emergence of an
average of one plant per square metre after 15
years.
Although there was no difference between the
four cultivars in either the number of seeds shed
at harvest or in their subsequent persistence,
the importance of the persistence of GM rape
seeds, simply in the context of the coexistence
of GM and non-GM crops is a clear cause for
concern. The researchers concluded that the
density of more than two volunteers per square
metre would exceed the European Union threshold
of 0.9 percent adventitious presence of GM seeds
in a non-GM crop, if the subsequent crop were
conventional.
These results come in the same week as
DEFRA’s report showing that the harmful
effects on wildlife from GMHT crops in the Farm
Scale Evaluations (see “GM crop fails final
test” SiS
26) persist for at least two years [5].
Results showed that weed seedbanks following
GMHT spring oilseed rape were significantly lower
than following conventional crops over this
period as was the case with winter oilseed rape
[6]. Seedbanks following GMHT beet were also
smaller providing empirical evidence for
longer-term effects of GMHT cropping on farmland
biodiversity [5]. Seedbanks for GMHT maize were
higher than conventional, mostly probably due to
the use of the now banned herbicide atrazine on
the conventional crop.
Illegal contamination with GM material
These cases of environmental contamination
with GM material have been detected in the UK
where there is as yet no commercial planting of
GM crops; emphasising that contamination in
countries such as Canada, the US and Argentina -
where GM monocultures are becoming, or are
already the norm – is far more extensive
(“Soya disaster in Latin America”, SiS28).
Though hardly reported in the mainstream
press, well over 60 incidents of illegal or
unlabelled GM contamination have been documented
in 27 countries on five continents; eight of
which occurred in the UK. And those are
only the recorded incidents [7]. The worst single
contamination incident was of StarLink Maize, a
GM variety approved only for animal feed which
entered the human food chain in seven countries,
the US, Canada, Egypt, Bolivia, Nicaragua, Japan
and South Korea.
Moreover GM DNA is in the European human food
chain via GM animal feed (“DNA in food and
feed” SiS
23), but milk and meat are not labelled as
such, and are considered safe by the UK Food
Standards Agency.
Recent GM contamination in Europe
UK Member of Parliament Michael Meacher
recently condemned seven years of secrecy over GM
food and feed safety [8]. “On the
seventh anniversary of the first disclosure of
scientific concern about GM food safety I am
supporting calls for freedom of access to the
data used by the Government to approve GM
foods.” Meacher said, “ Since the issue
is the launching of GM products into the
nation’s food supply that have never been
independently tested, this is a public scandal of
huge proportions.”
Next year the EU will decide how member
countries will draft ‘coexistence laws’
for GM, conventional and organic crops to be
grown together. But at a conference in
Bologna, Italy, in September, experts maintained
such ‘co-existence’ to be biologically
impossible. Angelika Hilbeck of the Swiss
Federal Institute of Technology Zurich said that
[9], “[trying to prevent GMO contamination]
starts with the seeds; you want to make sure you
get uncontaminated seeds. This is the origin of
everything, from there on the contamination
multiplies. For example, in Canada it is
hardly possible to get GM-free canola
seeds.”
News emerged in October about Monsanto’s
massive illegal GM contamination of
Romania. The country has the largest GM
cultivated landscape in Europe; officially half
the 140 000 hectares of soya planted in 2005 is
registered to be GM. However, according to
representatives of farmers’ associations and
even biotech giant Monsanto’s former
Romanian manager, up to 90 percent of soya is GM.
The core of the problem is due to genetically
engineered crops contaminating the traditional
cultures, as well as the illegal selling of GM
soya seeds. GM potatoes and plums were also
found [10].
Greenpeace protesters stopped the 125 000
tonne bulk-carrier Étoile’s huge
consignment of GM animal feed from the US from
being unloaded in Bristol. The feed was
destined for British dairy cows to produce milk
for the UK’s biggest supermarkets.
Sainsbury's, Tesco, Asda, Waitrose and Morrisons
all sell own-brand milk from cows fed on American
GM feed. The GM varieties were banned in
Europe, but were found by expert laboratory
analysts in samples taken from ships over the
last two years.
Campaigners believe that only strict rules
with liability regulations applied by governments
can stop the unauthorised spread of GM seeds and
products, which seems to be increasingly out of
control all around the world. Doreen
Stabinsky of Greenpeace International says,
“If states do not act and set strict rules
now GM crops will further contaminate lands,
seeds and food around the world.” But
no Government or international agency has
established a public record of contamination
incidents or other problems associated with GM
crops. GeneWatch UK and Greenpeace
International are launching the first on-line
register of genetically modified contamination
incidents. The on-line, searchable web site gives
details of all the known cases of GM
contamination of food, feed, seed and wild plants
that have taken place worldwide [11]. This
article can be found on the I-SIS website at http://www.i-sis
General Enquiries sam@i-sis.org.uk
- Website/Mailing List press-release@i-sis.org.uk
- ISIS Director m.w.ho@i-
sis.org.uk
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