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Towards a New Ethic of Science
Mae-Wan Ho - Institute of Science in Society and Biology
Department, Open University, Walton Hall, Milton Keynes, MK7 6AA, UK
Introduction
Genetic engineering biotechnology is raising a whole range of ethical
issues, and a new breed of ‘bioethicists’ have been enlisted to
consider not only genetic engineered (GE) crops, but especially animal and
human cloning, genetic screening for diseases, pre-natal and
pre-implantation diagnosis, experiments on human embryos,
xenotransplantation, and gene replacement therapy. The public have
expressed deep concerns about ‘playing God’; about exploiting
human beings and animals, and the re-emergence of genetic discrimination
and eugenics which have blotted the history of much of the twentieth
century.
There are strong moral objections to the new patents that turn life and
life-necessities into commodities. Patents on genetic engineered seeds
prevent farmers from saving and replanting seeds, thereby intensifying the
corporate monopoly on food which has already marginalized and destroyed
the livelihoods of family farmers all over the world. Plants and knowledge
taken from indigenous communities are patented in flagrant acts of ‘biopiracy’.
Genetically engineered animals, gene sequences, and cell lines, including
those from human beings, and entire DNA database of human populations are
being patented and owned by corporations, in violation of basic human
rights and dignity. >
One major obstacle to an open democratic debate is that the scientists
developing the technology have been almost completely absorbed into the
commercial sector. The public are being uncritically informed by
scientists consciously or unconsciously serving commercial interest. The
social ethos is increasingly hostile to the ethical practice of science
itself.
Furthermore, there is a tendency in all debates on technology to leave
the science untouched, to consider it separate from technology and from
ethics, and to see it in isolation from society as a whole. These
separations are artificial and unwarranted, and have served to obscure the
most important issues. In this article, I shall put science itself in the
spotlight: to examine the social control of science, the nature of the
science driving the technology, and the relationship of science to
society. I shall argue that there is an urgent need to reinstate
independent science, and to define a new holistic ethic of science that
can guide us in the safe and sustainable use of increasingly powerful
technologies.
‘Science moves to centre stage’
Science is playing an increasing part in many decisions made by
governments. This is hardly surprising, as science has been affecting
every aspect of the daily lives of people all over the world ever since
the industrial revolution. A commentary published in Nature (1),
co-authored by UK Member of Parliament Ian Gibson, stresses the need for
parliamentarians to "obtain and use unbiased information on technical
matters", for "open and inclusive debates" to "deal
with the wider scepticism towards science and technology that has been
generated in part by commercial involvement" and "the loss of
trust in institutions that manage risk on behalf of the public (for
example, food safety)". It welcomes the prime minister’s
statement that ‘good’ science should drive the debate on genetic
engineering, but admits that after the experience of ‘good’
science in the BSE debate, when there was political suppression of data,
this criterion is not enough. It also calls on scientists themselves to
examine their political and public roles.
Commercialization and the demise of independent science
Western science has been instrumental in the growth of corporate
capitalism since the industrial revolution. World War II ushered in a
period of rapid expansion of science with generous funding from the state,
and increasingly thereafter, from industry (2). The commercialisation of
science, which has been happening earlier in physics and chemistry, caught
up with biology during the exponential growth of genetic engineering
biotechnology in the late 1970s and early 1980s (3). Basic molecular
biology research, which until then, had been funded exclusively by the
public purse, became transformed overnight into a haven for venture
capital. Scientists set up companies to patent and exploit their research
results. Hundreds of small biotech firms were founded, and the long
established companies soon got into the act.
Under the Reagan-Thatcher regime, policies were instituted to make
universities more fertile ground for corporate investors, and universities
were encouraged to work more closely with industry. Tax incentives were
granted to corporations, and legislation passed to provide special tax
shelters and high investment income to investors in the new biotechnology.
By 1987, US Federal funding for research and development in biotechnology
(both basic and applied) was $2.72 billion, compared to a total funding
for basic science of $6.8 billion (3). All major universities had
established links to biotech firms, and half of the active members of the
US National Academy of Sciences had industrial ties. In 1998, an entire
Department with 25 professors in the University of California at Berkeley
was effectively sold to the Swiss biotech giant Novartis for $50 million
(4). To-day, practically all major academic and research institutions in
Europe and the United States are dependent on industrial support. Yet,
much of the real financing comes ultimately from the public purse.
The expropriation of public finance for industrial research and
development is evident within the UK. The UK Government’s Technology
Foresight exercise in 1996 identified "building businesses from
biology and genetics" as a priority for science, engineering and
technology (5). This was adopted in the corporate plan of the major public
funding body, Biotechnology and Biological Sciences Research Council
(BBSRC). As a result, the BBSRC developed a strategy for integrating
scientific opportunity with the needs of industry and other users. The
BBSRC’s chairman, Peter Doyle, is the Executive Director of UK’s
leading biotech company, AstraZeneca, and many members of its various
committees have industrial ties (6).
John Sime, the chief executive of BioIndustry Association, whose mission
is to encourage and promote the biotechnology sector of the UK economy,
reported on a comprehensive series of "government initiatives to
encourage the manufacturing potential of biotechnology companies", "tax
incentives, technology transfer initiatives, and regional innovation
strategies" all being put into action to "boost start-up
activity" (7). And this was in May, 1999, when the world market for
GE crops was beginning to collapse.
It is clear that the biotech industry has been capturing large amounts
of public finance in both direct and indirect subsidies for research and
development, which they use to finance science that serves corporate aims.
The state has, in effect, brokered the transfer of power to control
science from scientists and civil society - where it legitimately belongs
- to business corporations whose sole imperative is monetary profit.
The demise of independent science is also the demise of science itself:
its intrinsic moral values of honesty, reliability and openness, its
ability to inspire, to work for the public good, and in the present
context, to respect the precautionary principle to prevent further damages
to health and the environment, to find the means to regenerate our planet
and make life sustainable for human beings and all the other inhabitants
on earth. Our survival depends upon those traditional ideals of science
which have been seriously eroded over the past fifty years. The
consequences have become all too apparent in the current genetic
engineering debate.
The genetic engineering debate
The scientific establishment is playing a key role in research and
development of genetic engineering biotechnology and in actively defending
the industry under the banner of ‘sound science’ and ‘scientific
progress’. Scientific advice to the government is heavily biased in
favour of the industry. Lord Sainsbury, current Minister for Science, was
formerly chairman of the Sainsbury family’s supermarket chain,
closely involved with the development of GE foods. He also owns a gene
patent in agricultural biotechnology, which was transferred to his "blind
trust" when he became Minister (8). Another prominent scientist,
Derek Burke, advisor to the Parliamentary Committee on Science and
Technology and formerly chair of the Advisory Committee on Novel Food
Products, was a key participant in the UK Government’s Technology
Foresight exercise, and in a follow-up group that determined the
pro-biotech funding policy of the BBSRC (6). Derek Burke is an outspoken
and staunch defender of the industry. The public are being informed
uncritically by scientists like Burke and others, consciously or
unconsciously serving commercial interests, and legitimate concerns about
safety are caricatured as irrational fear arising out of ignorance. The
relationship between the general public and the scientific establishment
has never been worse. In a 1990 Europe-wide survey (9), only 6% of the
people questioned trusted scientists in universities to tell the truth
about GE crops, well below environmental organizations (26%) and just
marginally better than politicians (4%).
The credibility of science and scientists has been steadily diminishing
over the years as science has become more and more absorbed into the
commercial sector. Science education at every level is being subverted to
corporate aims: its chief purpose is to provide skilled but uncritical
workers for industry. The UK Government has even run a competition for
science students on how to commercially exploit scientific research (10).
There has been no major open debate on genetic engineering within academic
institutions, that has been organized by the academic staff. With very few
exceptions, students are not encouraged to ask questions about the ethics
or the hazards of genetic engineering on either side of the Atlantic.
Instead, academic scientists have been engaged in the most comprehensive
social engineering exercise on behalf of industry over the past ten years.
So-called ‘public perception task forces’ have been set up at
the taxpayers’ expense, to appoint professors and build departments
and courses for the ‘public understanding of science’, one of
its main tasks being to overcome public resistance to the biotech industry
(11).
Scientific evidence of actual and potential hazards, which has been
steadily building up over the past ten years (12), is being ignored and
dismissed. More seriously, independent scientists reporting findings
damaging to the industry are gagged and victimised.
Dr. Chopra, a Health Canada government employee well-known for his
defence of human rights and public interest, was ordered not to appear at
public meetings without the authorization of Health Canada. He has spoken
out previously about Health Canada administrators who disregarded
scientists’ recommendations to withhold approval for drugs which
endanger public safety. Chopra and other scientists wrote an internal
Health Canada report about the hazards of genetically engineered bovine
growth hormone, rBGH (also known as bovine somatotropin, BST), which was
suppressed by the administration. The rBGH, produced by the biotech giant
Monsanto for injecting into cows to boost milk yield, was formally
approved in the US in 1993, but was actually marketed and used years
before. A subcommittee of the Canadian Senate investigating the safety of
rBGH requested a copy of the scientists’ report and was refused by
the administrators. The Senate subpoenaed the report in September 1998,
and a court hearing eventually banned rBGH from Canada. Nevertheless, Dr.
Chopra has been suspended from his job (13).
The approval of rBGH by the US FDA was itself an object lesson (14). An
80-page report entitled, Use of Bovine Somatotropin (BST) in the
United States: Its Potential Effects, was published by the Clinton
White House in 1994, which concluded, "There is no evidence that BST
poses a threat to humans or animals." Later that year, British
scientists revealed that their attempts to publish evidence that rBGH may
increase the cow’s susceptibility to mastitis (infection of the
udder) was blocked by Monsanto for three years. The scientists showed that
Monsanto’s submission to the FDA was based on selected data that
covered up what the experiments had actually revealed – more white
cells (pus) in rBGH-treated cows. Over 800 farmers using rBGH reported
health problems with the cows. Side effects included death, serious
mastitis, hoof and leg ailments and spontaneous abortions. Monsanto tried
to bribe Health Canada officials with several million dollars to get rBGH
approved. Two respected investigative journalists were fired from their
jobs over a TV documentary on Monsanto’s rBGH, and significant
scientific findings were suppressed. For example, insulin-growth factor
(IGF-1) was found to increase 10-fold in rBGH milk. Increased IGF-1 is
linked to breast, colon and prostate cancers in humans. Monsanto had also
withheld from the FDA data from studies on rats which showed that feeding
rBGH elicited antibodies to the hormone and the males developed cysts on
the thymus and abnormalities in the prostate gland. Despite all that, rBGH
milk is still being sold unlabelled in the US today.
Within the UK, Dr. Arpad Pusztai, senior scientist of the
publicly-funded Rowett Institute, and his collaborators were awarded a 1.6
million pound grant to carry out systematic safety testing of GE food.
They found that the GE potato lines tested were toxic to young rats, and
Pusztai informed the public in a brief interview which was part of a TV
documentary. A few days later, he was removed from his job, denied access
to his data, and forbidden to speak on the subject until an international
group of twenty-four scientists spoke up for him six months later. This
opened the floodgates of criticism and vilification against him and his
supporters from within the scientific community.
Among the most vociferous critics were government scientists, like Derek
Burke, who have been responsible for approving GEfoods for the market, and
also the hitherto most respected and prestigious association of top
scientists, The Royal Society. Fellows of the Royal Society accused
Pusztai of endangering ‘sound science’ in making public findings
which have not been peer-reviewed and published in a scientific journal.
An official review was set up by the Society to discredit Pusztai's work.
There are no plans to attempt to repeat the work, nor are there serious
efforts to support independent scientific research which would throw light
on the hazards.
Puztai and his colleagues eventually published part of their findings
amid a fresh storm of attack, and even reported threats to the Editor of
the Journal publishing the paper from a prominent figure within the
scientific establishment (15). The suppression of scientific findings is
nothing new; it has been happening more and more within the past decade.
What is new in Pusztai’s case is that it should come so blatantly
from within the established scientific community.
Sir David Weatherall, regis professor of medicine, Oxford, reported on
the treatment meted out to his long-standing collaborator in the
University of Toronto in Canada, who was removed from her post for
publishing data showing that the drug she was assessing for a Canadian
company was unsafe (16). Weatherall is critical, not only of the company
trying to gag scientists, but of the lack of support for the intimidated
scientists in their own academic institutions, and of the absence of open
debate. These complaints may be widespread.
The Institute of Professionals, Managers and Specialists (IPMS) is a
trade union recruiting largely from government research establishments and
similar organizations. The February 2000 issue of their Bulletin reports
that of the 500 IPMS members who responded to a questionnaire, 30% stated
they have been asked to ‘tailor’ their results.
Since the 1970s, scientific fraud has been increasing, as has the
proportion of peer-reviewed scientific papers retracted (17). We have
moved far away from the traditional ideals of science as science loses
innocence and independence.
The need for independent science and open debate
Independent, honest scientists are absolutely necessary in a present-day
democracy, whether they are working within the government, paid by the
taxpayer, or in the commercial sector. Important decisions impacting on
public health and safety, the environment, as well as the social and
economic benefit to civil society, all hinge on the honesty of scientists
and the reliability of the scientific advice given. All the more so as
technologies become increasingly powerful and uncontrollable. Wrong
decisions will literally cost the earth. Industry may be tempted to
prevent scientists from telling the truth for the sake of short-term
financial gain. But their long-term business strategy can only benefit
from scientists who are free to say what they know. More importantly,
there must be open debate when scientists disagree with one another. And
the debate must be conducted in terms comprehensible to the general public
so that the public can participate in making decisions.
Science is an active knowledge system, and uncertainty is its
hallmark. Judgements are invariably based on incomplete information, and
that is where precaution must be the guiding principle. One might argue
that had Monsanto received sound scientific advice, it might not have
invested so heavily in agricultural biotechnology and might have avoided
its recent debacle as the international market for GE crops has collapsed
(18).
A civil lawsuit was filed in May 1998 by a coalition of scientists and
religious leaders in the United States against the Food and Drug
Administration (FDA) over its approval of genetic engineered foods. Secret
documents have come to light indicating that the overwhelming majority of
the scientists consulted by the FDA did give genuinely sound
advice, which the agency suppressed and ignored (19). The scientists
insisted that genetic engineering is a new departure from conventional
breeding and introduces new risks. They were strongly opposed to the use
of antibiotic resistance genes as selectable markers, because the genes
may be taken up by bacteria that cause infectious diseases, making the
diseases untreatable. They warned that the process of genetic engineering
is unpredictable and uncontrollable, and that unintended effects are
unavoidable due to the random insertion of the artificial gene and
gene-constructs into the organism’s own genetic material. In the case
of crops used as food, these unintended effects may include new toxins,
allergens and carcinogens. The first GE crop to be commercialized, the
Flavr Savr tomato engineered to prolong shelf life, actually did not pass
the standard toxicological tests. The FDA approved the tomato in violation
of the US Food Drug and Cosmetic Act, which requires food additives to be
shown to be safe. Since then, no comprehensive scientific safety
testing of any GE foods has been attempted, until the work of Arpad
Pusztai and his collaborators.
The advice of the FDA scientists is remarkably similar to what some
other scientists have been saying in public over the years: the process
of genetic engineering itself is inherently hazardous (20).
The reason Pusztai has been so fiercely attacked, is the claim made in
the paper he published with Ewen (21): that the genetic transformation
process itself or the artificial gene-construct, or both, may not be safe.
If that is the case, all genetic engineered crops may not be safe.
What is genetic engineering? And why is it inherently hazardous?
Genetic engineering is a set of laboratory techniques for isolating,
multiplying, cutting and joining genetic material from different sources,
and most of all, for transferring genetic material between species that
can never interbreed in nature. So human genes are transferred into cows,
sheep, fish, mice and bacteria. Spider genes are transferred into the
goat.
There is no limit to the exotic genes that can be introduced in any
organism. Many are taken from viruses and from bacteria that cause
diseases, including antibiotic resistance marker genes. There is also no
limit to the new combinations of genes that can be created, which have
never existed in nature. Thus, gene switches from infectious viruses are
placed next to genes to make them over-express. These novel genes and
gene-constructs are introduced into organisms either by physical methods
such as ‘gene-guns’ which shoot them into cells, or the
constructs are spliced into artificial gene-carriers, or vectors which
smuggle them into cells. The artificial vectors themselves are made by
combining bits of the most infectious viruses and other genetic parasites
capable of getting into a cell and invading the cell’s genome,
the totality of its natural genetic material which is organized in precise
ways. The human genetic engineer has no control over where and in what
form the artificial genes and gene-constructs end up in the cell’s
genome, however; and this gives rise to many random, unpredictable
effects. Genetic engineering animals are acts of cruelty, there are high
failure rates and even the so-called successes are often monstrously
deformed (22). GE plants may well end up with unknown toxins and
allergens.
Finally, the artificial genes and gene-constructs created are unstable,
and have the potential to move out of the genome to infect and invade the
genomes of unrelated species in a process called ‘horizontal gene
transfer’. Horizontal gene transfer involves the genetic material
transferring directly from one organism to another. All cells, from
bacteria to those of our own species, are now known to readily take up
genetic material, which may then become incorporated into the cell’s
genome. Horizontal gene transfer is generally accompanied by
recombination, the creation of new and different combinations of genes.
The same kinds of techniques and gene-constructs are used in every
application of genetic engineering biotechnology, whether it is in
agriculture, industrial production or medicine, they involve the same
potential hazards: the spread of antibiotic resistance genes, the
creation of new viruses and bacteria that cause diseases, harmful
mutations due to the random insertion of the artificial genes and
gene-constructs into the genome, some of which are linked to cancers (23).
The following have already been demonstrated by experiments in the
laboratory: antibiotic resistance genes from genetic engineered plants
were transferred to soil fungi and bacteria; genetic engineered plants
containing viral genes recombined with infecting viruses to generate new
viruses; and partially degraded DNA was readily taken up by bacteria that
live in the human mouth and respiratory tract.
It is the burgeoning fields of gene therapy and new vaccines, however,
which reveal how readily genetic material can gain access to cells and
become incorporated into the cell’s genome (24). New evidence also
indicates that the constructs themselves can give acute toxic reactions,
severe delayed immune reactions as well as auto-immune reactions in which
the body’s immune system attacks its own cells and tissues.
There have been six deaths associated with clinical trials in gene
therapy in the US within the past two years, plus more than 650 adverse
reactions, all of which were concealed from the authorities, until the
most recent death of a teenager triggered a comprehensive public enquiry
(25).
Science and the precautionary principle
In short, there is sufficient evidence to warrant the withdrawal of all
genetic engineered crops and products from environmental release until and
unless they can be shown to be safe (26). Furthermore, there is an urgent
need to tighten the regulation over the release of genetic engineered
microorganisms, cell cultures and their genetic material from contained
laboratories and industrial use, and over all the artificial gene
constructs and vectors in medical applications. This is in accordance with
the precautionary principle, which can be stated as follows: when there is
reasonable suspicion of serious irreversible harm, lack of scientific
certainty or consensus should not be used as justification for not taking
preventative measures (27).
As it is in the nature of science that scientific certainty never
exists, the proper use of science and scientific findings is precisely to
enable us to act with precaution. This is the most important ethic of
science, which has been violated repeatedly for decades.
The attacks on Pusztai say more about the so-called ‘sound science’
his critics are defending, that lies behind current risk assessment,
whether it be for radioactive discharge, industrial chemicals, toxic
wastes or genetic engineered products. Pusztai does not regard his
research as definitive proof that GE potatoes, or GE food in general is
harmful. He has stressed the need for further research. However,
the results do throw into serious doubt the claim of the biotech industry
and regulatory authorities that genetic engineered food is safe.
And herein lies the crux of the appropriate burden of proof, which, for
the past 50 years, has persistently operated in favour of industry and
against the protection of health and safety, biodiversity and the
environment. In other words, the onus has been on regulators and civil
society to demonstrate that something is definitely harmful before it can
be refused approval, withdrawn or banned. This is simply a misuse and
abuse of science, which has been and still is being condoned by the
scientific mainstream.
In signing on to the International Biosafety Protocol in Montreal in
January 2000, more than 150 governments including the UK have agreed to
implement the precautionary principle. We must insist that they do so, for
this will change the whole complexion of regulation to genuinely protect
health and safety, biodiversity and the environment (28). It is time
scientists themselves insist on the precautionary approach.
The fallacy of scientific objectivity
There are deeper problems in the nature of the science itself and its
relationship to society, which must also be addressed before the ethical
implications are fully appreciated.
There is a general tendency for people to believe that scientific ‘progress’
is unstoppable, for better or for worse. This fatalistic faith in ‘scientific
progress’ is more dangerous than the runaway technologies that the
science inspires. It is why we have failed to avert the disasters time and
again.
Underlying the faith in scientific progress is the assumption that
science is about how nature really is, that the laws of nature are
there waiting to be discovered by the objective scientist, one who is
devoid of feelings, prejudices and misconceptions. In that ideal of ‘objectivity’
– which is seldom, if ever satisfied - science is morally neutral. In
other words, it offers no guidance as to what is good or bad, only what is
right or wrong. Wolpert, Fellow of the Royal Society and a prominent
member of its Committee of Public Understanding of Science, represents a
fairly extreme version of this ‘absolutist’ view (29). He makes
a categorical distinction between science and its application, i.e.,
technology. Thus, the science that went into making the atomic bomb, and
making the bomb were entirely separate. Science, he says, "has
nothing to contribute to moral and ethical issues" although these can
arise in relationship to the applications.
This distinction between science and technology is most often made.
However, it is artificial and unwarranted, even for an overwhelmingly
theoretical science such as high-energy physics. Without empirical tests,
the theory on paper that radioactive reactions could become critical is no
more than a mathematical exercise. So making the bomb can legitimately be
considered part and parcel of the science of the bomb.
For an experimental science such as molecular genetics, the separation
is even more tenuous. Where would molecular genetics be without the tools
that enable practitioners to recombine and manipulate genetic material
from different sources? And having done that, and noted the significant,
triumphant results, it is all too easy to see the world in genetic
determinist terms: that genes determine destiny, and by manipulating genes
including our own, we may also manipulate our destiny. It is the science,
therefore, that inspires the applications or the technology, that makes it
so compelling; except that the science is fundamentally flawed (see
later).
In reaction to the ‘absolutist’ conception of science, some
sociologists have claimed that the mere notions of right or wrong involve
value judgements embedded in particular social and political contexts. And
so, just as there is no unique cultural standard whereby one could judge
all other cultures, there is no absolute scientific truth that stands
above other truths. This is the ‘relativist’ view of science.
These opposing concepts of science give rise to different perspectives
on the moral responsibility of science and scientists, but paradoxically,
they converge with regard to the relativity of moral values. For
the absolutist, science is the corpus of the ‘laws of nature’,
and as such, stands above mere human morals. So ethics - moral rules of
conduct - will have to be negotiated around science. The moral
responsibility of science and scientists is to scientific truth, whether
it is morally palatable or not is irrelevant. By contrast, the relativist
puts science on a par with other kinds of human activity. The moral
responsibility of scientists is no different from that of everybody else.
It is a responsibility that is socially negotiated, just as morals are a
matter of social consensus and judgement.
Very few scientists who have really thought about their moral
responsibility will be extreme absolutists, although they would also
reject the relativist position, as I do. It is all too easy to forget that
there is a much wider context within which scientific knowledge is
negotiated, which is nature herself. Nature is definitely not subject to
our arbitrary whim and projection, but neither is she simply ‘out
there’ waiting to be discovered. I have made the case elsewhere that
the best scientific theories are works of imaginative construction - akin
to the most moving works of art. They arise out of a sensitive, intimate
communion with nature (30). Scientists, like everyone else, and in common
with all living beings, exist within nature. They participate
in knowing nature and more than anyone else, in shaping reality by that
very knowledge. And herein lies the moral responsibility of science
and scientists. Reality can be shaped for better or for worse, and it is
incumbent on us to make the choice: what to do or not to do.
Participatory knowledge predates the non-participatory Cartesian
framework of modern science, which sees mind distinct from matter, and
hence separate from nature. Participatory knowledge has been rediscovered
early in the 20th century within the foundations of quantum theory, which
shows that the ‘observer’ is inseparably entangled with the ‘observed’,
and that each act of ‘observation’ transforms both the observer
and the observed (31). That has overturned the most cherished assumptions
of the mechanistic framework of previous centuries. It also reinstates the
holistic, ecological knowledge system that many indigenous cultures across
the world have never lost touch with, that has enabled them to live
sustainably for millennia. If we take science to be reliable knowledge of
nature that enables us to live sustainably with her, then many indigenous
sciences are far superior to our own, and there is much that we can learn
from them.
The most important lesson for us is the interdependence and mutual
entanglement of all nature. This is the basis of a naturalistic ethic
reflecting the highest moral ideals shared by traditional indigenous
cultures all over the world. It is also integral to a holistic western
science of the organism emerging across the disciplines (32).
I agree with veterinarian and bioethicist Michael Fox (33): "There
are moral absolutes such as the reverence for life, compassion and ahimsa
(nonharmfulness) that can provide both a goal and a common ground for a
reasoned and scientific approach to resolving ethical issues. These
absolutes are the cornerstones of a monistic hierarchy of human values
that could effectively incorporate the plurality of interests of various
segments of society and of different culture." These moral absolutes
arise, not from indoctrination externally imposed, but out of our most
intimate experience of nature’s unity.
The two-way connection between science and society
There is a two-way connection between science and society. Science is
both shaped by the politics and the mores of society and it can
reinforce them. But science can also transcend the status quo
and bring about social change, if we consciously will to do so. In the
wake of the quantum revolution, it is clear that we are participants in
evolution and not merely subject to external forces over which we have no
control.
The mechanistic paradigm of western science grew under the legacy of
the Judaeo-Christian tradition beginning in sixteenth century Europe. It
inspired the search for eternal laws, ordained by God, which could make
the universe move in predictable, mechanical ways. Through Copernicus,
Galileo and Descartes, this strand of thought eventually culminated in
Isaac Newton’s mathematical laws of mechanics. So successful was the
mechanistic framework that every event in nature came to be seen in this
perspective.
Another strand in the legacy of the Judaeo-Christian tradition is that
human beings are considered to be created in the image of God and have
immortal souls, while animals and the rest of nature are there to be used
by human beings. Descartes established the dualistic separation of human
beings from nature, of mind from body and matter from spirit. And that has
plagued western philosophy ever since. He maintained that only human
beings can reason, that animals are unfeeling machines; and condoned cruel
experiments on dogs and cats. Francis Bacon, similarly, urged that we "vex
Nature of her secrets" that it was our right to extend our power and
dominion over the universe. In The Island of Dr. Moreau, he
described animal parks used for public viewing and for "dissection
and trials, that thereby we may take light what may be wrought upon the
body of man…" (34).
Thomas Hobbes went further. He maintained that nothing exists except
body, matter and motion, that not only the universe but man himself can be
explained mechanically. He argued that humans are determined purely by
their appetites and aversions, and without the rule of a powerful king to
restrain and channel those animalistic impulses, our lives would be "poor,
nasty, brutish and short". In other words, absolute government is
necessary to prevent the war of each against all to which natural
selfishness inevitably leads (35). Hobbes was writing when mercantilism
reached its high point in Europe, and brought great power to those princes
and merchants who successfully accumulated vast quantities of gold and
other precious metals.
Hobbes’ influence has passed down to us via Charles Darwin in an
age that saw the birth of capitalism and the expansion of the ‘free’
market under the military might of the British Empire. Nature became
ultimately reduced to isolated atoms jostling and competing in the
struggle for survival of the fittest. In its present-day form,
neo-Darwinian sociobiology has changed very little from social Darwinism.
It is based on denying and explaining away every good there is – such
as love, moral feelings and altruisim - as different forms of disguised
selfishness (36). Neo-liberal economic theory is in many ways much more
pernicious than Adam Smith’s laissez-faire economics, which
is based on competition tempered by moral restraint (37). And so, through
the self-fulfilling prophecy, mechanistic science has created a
dysfunctional social milieu and a globalized economy which is
destroying our planet and failing to serve the physical and spiritual
needs of the vast majority of humanity (38). That was the main
reason fifty thousand people took to the streets at the World Trade
Organization conference in Seattle in December, 1999.
It is clear that the mechanistic paradigm has spectacularly failed the
reality test in life. What is not generally recognized is that it has
also failed within science itself. It has been thoroughly discredited
by scientific findings. But the discredited paradigm is still perpetrated
by the mainstream academic institutions, if only because it serves so well
to promote the engineering of life itself.
‘Frankenstein science’
Mechanistic biology has reached its logical, nightmarish conclusion,
when organisms including human beings are to be genetically manipulated
and cloned. The first ‘human’ clone has already been created, by
injecting the genetic material of a human being into a cow's egg (39). It
is all too reminiscent of Mary Shelley's prophetic parable of Frankenstein.
Dr. Frankenstein is the scientist obsessed with mastery over nature; so
much so that he attempts to create the perfect human being, only to
realise too late that he has created a monster. Mary Shelley's classic is
as much a parable of the mechanistic science that inspires the deed as it
is of the scientist ‘playing God’.
All species of animals are being genetically manipulated. Millions of
genetically engineered mice are created to serve as dubious models of
human diseases, and an increasing number have to be sacrificed to make
room for more. Livestock are ‘humanized’ to provide spare organs
for transplanting into human beings, or engineered and cloned as ‘bioreactors’
to produce pharmaceuticals and industrial chemicals in their milk, blood,
urine and semen (40), and with tens of thousands of failures and
abnormalities.
Apart from the potential hazards of creating new viruses that cross
species barriers, the excessive suffering inflicted on the animals
violates the most basic moral code of our society. Michael Fox strongly
questions the right of human beings to interfere so profoundly with the
inherent nature or telos of other species (41). Indeed, each
species has its own intrinsic value, its own purpose in the scheme of
nature, which we violate at our own peril. This is also the most abiding
ecological wisdom which western science has lost touch with, and is only
now rediscovering.
The organic revolution and the new ethic of science
Genetic determinism has ruled biology and the popular culture at large
before genetic engineering really got underway 25 years ago. It offers a
simplistic, reductionist description which is a travesty of the
interdependence and complexity of organic reality. It has no concept of
the organism as a whole, nor of societies or ecosystems. Instead, it sees
only selfish individuals, each competing against all and all against
nature. The organism, similarly, is regarded as nothing more than a
collection of ‘traits’, each mechanically tied to specific
genes. The genes are supposed to pass on unchanged to the next generation,
except for very rare random mutations. If all that were true, genetic
engineering would be as precise and effective as is claimed: identify the
gene that determines the desired trait, isolate it, and transfer it to
another organism, and you transfer the desired trait, once and for all.
Unfortunately, scientific findings over the past 25 years reveal an
immense amount of cross-talk between genes, which function in complex,
entangled networks. Genes are nothing if not sensitive, dynamic and
responsive, to other genes, to the cell or organism in which they find
themselves and to the external environment. Genes are active, or not,
depending on the environment. Not only that, they can mutate, multiply,
rearrange and jump around. Genes may even jump out of one organism to
infect another in horizontal gene transfer. The genetic material is so
flexible and dynamic that geneticists have coined the phrase, "the
fluid genome", to describe the situation back in the 1980s.
Genetics has changed out of all recognition. Genes have to be seen as
having a very complicated ecology, and that for genes and genomes to
remain constant, we need a balanced ecology. The new genetics is
radically ecological, organic and holistic, it is diametrically opposed to
the mechanical conception of nature that has dominated the west for
hundreds, if not thousands of years. The transition between classical
genetics and the new genetics is analogous of the transition between
classical and quantum physics (42). That is the reason why genetic
engineering, at least in its current form, can never work. It is based on
misconceptions that organisms are machines, and on a denial of the
complexity and flexibility of the organic whole.
Biologist Tasios Melis and his colleagues in the University of
California in Berkeley have just discovered how to ‘grow’
hydrogen, the cleanest, most environmentally friendly fuel that generates
pure water when it burns. They simply change the medium in which the
microscopic alga Chlamydomonas reinhardtii lives (43). The alga
makes its living normally by photosynthesis, a process in which the energy
of sunlight is captured to make carbohydrates and other macromolecules.
However, when starved of sulphur and deprived of oxygen, the organism
switches over to another metabolic state in sunlight, to recycle sulphur
by breaking down its proteins and release hydrogen at the same time. The
hydrogen is made by recombining electrons in the electron-transport chain
with the protons, both normally generated by photosynthesis, with the help
of an enzyme, hydrogenase. Hydrogen is produced at an average hourly rate
of 2 milliter per litre of culture. The scientists believe they could
increase the yield 10-fold. No genetic engineering has achieved that, and
none was required.
This brings us to a problem in the ethics of science which has never
been seriously addressed: the kind of science appropriate to society,
which can transcend the existing dominant ethos, to support the necessary
transition to sustainable ways of life, and to connect with the organic
uprising that is coming from the grassroots all over the world.
Many remarkable individuals and local communities are indeed changing
their own lives and the world around them for the better. They all do so
by learning from nature and recognizing that it is the symbiotic,
mutualistic relationships which sustain ecosystems and make all
life prosper, including the human beings who are active, sensitive
participants in the ecosystem as a whole (44).
The same organic revolution has been happening in western science over
the past thirty years. Jim Lovelock’s Gaia theory, for example,
invites us to see the earth as one super-organism (45). Even more
remarkable is the message from quantum theory: that we are inseparably
entangled with one another and with all nature, which we participate in
co-creating (46). It is this holistic, organic perspective that can enable
us to negotiate our path out of the moral maze of genetic engineering
biotechnology. It provides the basis of a new ethic of science that can
reshape society and transform the very texture and meaning of our lives.
Seattle has shown us that things can be different. Society does not have
to be ruled by the dominant culture. Science can transcend the dominant
status quo to reshape society for the public good, which is also
the private good. We begin to appreciate how the purpose of each organism
and species is entangled with that of every other. Our humanity is a
function of this entangled whole, and we cannot do arbitrary violence to
one another, nor to the nature of other species without violating our own.
The ethic of science is no different from that of being human.
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46. Ho, 1993, 1998 (note 30).
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