No Biosecurity without Biosafety

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16 Mar 2005 15:17:04 -0000

 

No Biosecurity without Biosafety

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ISIS Press Release 16/03/05

 

No Biosecurity without Biosafety

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Biodefence Research Endangers the Public

 

Ensuring the safe use of genetic engineering is much more

important than preventing or defending the nation from

bioterrorist attacks Dr. Mae-Wan Ho

 

A fully referenced version is posted on ISIS Members'

website

http://www.i-sis.org.uk/full/BiosecurityBiosafetyFull.php.

Details here

http://www.i-sis.org.uk/membership.php

 

 

Biosecurity & biosafety

 

`Biosecurity' originated from a small group of scientists

who met in 2001 to discuss how to keep diseases affecting

crops and livestock from crossing national boundaries. Then,

came the anthrax attacks post September 11, and the term

came to be used for measures aimed at countering terrorist

attacks involving biological agents or toxins. Suddenly,

thousands of US scientists are caught in a web of new rules

for keeping dangerous agents and substances, and even

scientific knowledge, out of reach of bioterrorists.

Biosecurity should come under the Biological Weapons

Convention (BWC) to which the US is signatory; but the US

has rejected the Convention's remit to establish a procedure

to verify compliance with the Convention ( " Bioweapons

Convention –no progress in sight " , SiS 13/14

http://www.i-sis.org.uk/isisnews/sis13.php).

 

`Biosafety' refers to a set of measures aimed at regulating

and ensuring the safe use of genetic engineering and

transnational movements of genetically modified organisms.

It falls within the scope of the Cartagena Biosafety

Protocol under the Convention of Biological Diversity. The

US is not a party to the Biosafety Protocol and has

steadfastly refused to acknowledge it. The US position is

that genetic engineering biotechnology is inherently safe,

and only its misuse needs to be prevented.

 

It is clear that the BWC and Cartagena Biosafety Protocol

overlap, and are both needed for effective control of

genetic engineering and biological weapons. Of the two,

biosafety is the more critical, although most of the

attention is focussed on biosecurity.

 

Biosecurity and biotechnology research

 

A report from the National Academy of Sciences,

Biotechnology Research in an Age of Terrorism: Confronting

the Dual Use Dilemma, grew out of a meeting in January 2003

chaired by Gerald Fink, Professor of Genetics at the

Whitehead Institute for Biomedical Research at Massachusetts

Institute of Technology.

 

The Fink Report recommends a review process both at the

research stage and at the stage of publication. Its stated

aim was to " safeguard the integrity of science " , and not " to

censor research or research publications " . It proposes " a

system of filters " to help determine whether a particular

study should be done, and if so, how the finding might best

be published to avoid potential misuse. It emphasizes

" voluntary self-governance by the scientific community " . The

editors of Cell, Science, Nature and PNAS have already

agreed to review and " filter " out " sensitive " papers or

information.

 

The Bush administration has adopted the Fink Report, but its

implementation is mired in difficulty. The system relies on

Institutional Biosafety Committees that frequently fail to

comply with federal rules and on a National Science Advisory

Board on Biosecurity announced a year ago, but has yet no

members.

 

Biodefence is bad for biosecurity and biosafety

 

The US has been caught in a dilemma of its own making

because the government has been pouring billions into

`biodefence' research on biological weapons agents. It sets

up some 40 new and upgraded `hot zones' across the country

with hundreds of biosafety level 3 or 4 labs, designed to

research the most dangerous pathogens such as Ebola, plus at

least 11 doing classified, secretive research, 6 major

aerosol facilities and 3 open-air testing facilities. These

labs and facilities include not just established bio-weapons

research institutions, but also former nuclear weapons

installations and top universities, like Boston, Harvard,

John Hopkins, California, Illinois, Texas and New York; many

situated in the middle of densely populated areas, or in

some cases, deliberately sited in remote regions where they

can operate in secrecy (e.g., Dugway Proving Ground, Utah or

Rocky Mountain Labs, Montana).

 

Critics call attention to accidental releases of dangerous

pathogens and failures of biosafety containment that could

spell disaster for residents ( " Bio-defence mania grips

United States " , and " Biodefence contravenes biosafety " , SiS

19 http://www.i-sis.org.uk/isisnews/sis19.php). It is

difficult to distinguish bio-defence research from bio-

weapons research. In order to make vaccines against deadly

biological agents, the deadly biological agents have to be

created. The US programme, particularly in the Departments

of Defense and Homeland Security, is increasingly focussed

on " threat assessment " studies where researchers

deliberately create the " threat " , i.e., the weapon, claiming

they are learning to defend against it.

 

There is also the danger that researchers will be trained in

precisely the techniques needed for bio-terrorism. The post-

September 11 anthrax attacks have been traced to the federal

bio-defence lab in Fort Detrick Maryland.

 

Under the newly formed Department of Homeland Security

(DHS), much defence-related research and development will be

exempt from the Freedom of Information Act, and hence there

will be little or no mandatory public disclosure.

 

Biodefence is bad for science

 

Nevertheless, the Sunshine Project (www.sunshine-

project.org), a bioweapons watchdog, has developed and

released a new webtool (CRISPER) to search and organize

research grant data from the National Institutes of Health

(NIH). It revealed that the decision of NIH National

Institute for Allergy and Infectious Diseases (NIAID) to

give priority to research of high biodenfence but low public

health significance resulted in 1500% increase in the number

of grants awarded for biological weapons agents, while the

number of grants for model microorganisms and non-bioweapons

pathogens decreased by 41% and 27% respectively.

 

More than 750 prominent scientists signed an open letter,

published in Science, to the director of NIH to express

their concern. Richard Ebright of Rutgers University, who

initiated the letter, points out that prioritising research

on poorly known agents could backfire, not least because of

the need for strict containment and new experimental tools.

The biodefence money would be better spent researching

related, but less pathogenic organisms. He also believes

that increasing the number of labs and people working on

bioterror agents would increase the risk of an accidental

release or deliberate attack.

 

NIAID's biodefence budget shot up from $42m in 2001 to

$1.5bn in 2004, with $1.6 projected for 2005. The government

wide total spending on biodefence before 2001 was less than

$1 billion/year; between 2001 and 2005, the total spending

comes to $22 billion, and the projected total spending

between 2001 and 2006 is $30 billion.

 

There is no effective biodefence One should not

underestimate the increased possibilities of creating

powerful biological weapons in the post-genomics era ( " GM &

bioweapons in the post-genomics era " , SiS15

http://www.i-sis.org.uk/isisnews/sis15.php) (see Box 1).

But that's precisely also why there can be no effective

biodefence ( " Biodefence in tatter " , SiS 15

http://www.i-sis.org.uk/isisnews/sis15.php) (see Box 2).

The agents are unknown and unpredictable. They can target

the immune system directly to undermine the body's defence.

Vaccines will be ineffective, or worse than useless as the

smallpox vaccine may prove to be; and there is no way to

adequately test for efficacy or safety. Theoretical studies

indicate that partially effective vaccines may increase the

virulence of pathogens. There is no known defence against

agents that target buildings or structures.

 

Box 1 Post genomics possibilities for bioweapons Stealth

viruses targeting specific populations Designer diseases

Agents targeting the immune system Non-lethal agents

targeting agriculture Non-lethal agents targeting buildings

and structure Interfering RNAs that turn genes off

Completely novel disease agents made in the lab

 

 

 

 

 

Box 2 Futility of biodefence Agents unknown Immune system

targeted Vaccines ineffective or worse than useless and

there is no way to test for efficacy or safety Partially

effective vaccines may increase virulence of pathogens No

known defence against agents that target buildings or

structures

 

 

 

Biodefence unsafe

 

The dangers of biodefence were highlighted in January 2005

when three lab workers in Boston University were reported to

have fallen ill from being infected with tularaemia. The

infections happened between May and September 2004, but did

not become public knowledge until a week after Boston's

Zoning Commission approved the construction of a biosafety

level 4 laboratory in the University.

 

The workers had handled a live strain of the tularemia

bacterium instead of the non-infectious one typically used.

They were trying to find a vaccine for `rabbit fever'.

 

Before that, there were three lab accidents involving the

SARS virus. The Washington Post (29 May 2004) commented:

" Scientists still do not fully understand exactly where or

how SARS emerged 18 months ago. But it is now clear that the

most threatening source of the deadly virus today may be

places they know intimately – their own laboratories. "

 

The three lab outbreaks of the disease since September 2003

- in Singapore, Taiwan, followed by the 9 cases linked to

China's National Institute of Virology - have wider

implications. They " highlighted the unique hazards to public

health that arise from accidental releases of germs that no

longer exist – or barely exist – in the wild. "

 

The article described the notorious release of smallpox in

Birmingham, England, in August 1978, 10 months after the

last infection occurred in Somalia.

 

Henry S. Bedson, head of the microbiology department at a

medical school, was rushing to finish his experiments before

the deadline to turn in or destroy his stocks of smallpox,

as his lab had been judged unsatisfactory by the World

Health Organisation inspectors. The smallpox virus

apparently became airborne, and transported up one floor

through air ducts to a photographic studio and darkroom to

infect a 40-year-old photographer who died, even though she

had been vaccinated 12 years earlier. But not before she

transmitted the virus to her mother, who also became ill but

survived. Her father did not become infected but died from a

heart attack. Bedson slashed his throat, leaving a note that

said, " I am sorry to have misplaced the trust which so many

of my friends have placed in me and my work. "

 

The Council for Responsible Genetics listed numerous

breaches of bio-containment of disease agents in the US:

involving accidental and deliberate environmental releases,

failures of containment, loss of samples and 13 cases of

exposures and infections of personnel between 1994 and 2004.

The agents included AIDS, Ebola virus, West Nile virus,

glanders, plague, anthrax and tularemia.

 

Genetic engineering could be worse than bioweapons

 

I have stressed that the control of bioweapons and genetic

engineering must go together (SiS 13/14

http://www.i-sis.org.uk/isisnews/sis13.php),

and that the hazards from genetic engineering could be worse

than bioweapons: The basic tools and materials for making

bioweapons are the same as those used in `legitimate'

genetic engineering applications. But while bio-weapons are

made under strictly contained conditions, many dangerous

experiments are being done without adequate safety

precautions, and hazardous gene products are released into

the environment as if they were safe. More and more

scientists are voicing concerns over genetically modified

crops (The Case for a GM-free Sustainable World

http://www.indsp.org/A%20GM-Free%20Sustainable%20World.pdf

and " ISP letter to FDA "

http://www.indsp.org/USFDALetter190105.php): the potential

toxicity and allergenicity of transgenic products and their

negative impacts on biodiversity, as well as the horizontal

transfer of transgenic DNA and antibiotic resistance marker

genes. The more serious and insidious hazards, however, are

associated with contained uses of genetic engineering

biotechnology.

 

The Fink Report dismissed the risks of genetic engineering:

" The initial fears about the inadvertent creation of

virulent microbes by gene splicing techniques have abated

because of overwhelming scientific evidence to the contrary.

There have been no reported cases of disease caused by

recombinant microorganisms despite the widespread use of

gene splicing techniques in academic laboratories and in the

production of pharmaceuticals. "

 

I co-authored a paper with six scientists entitled, " Gene

technology and gene ecology of infectious diseases " ,

published in 1998, summarising all the evidence suggesting

that genetic engineering may have contributed to the

resurgence of infectious diseases since commercial scale

genetic engineering began, calling for an independent public

enquiry.

 

I sent a preprint to the World Health Organisation and the

UK Health and Safety Executive. Eventually, the HSE wrote

and said it would commission its own review, and nothing

more was heard. But the question we raised in the paper

remains as alive as ever ( " SARS virus genetically

engineers? " SiS 19

http://www.i-sis.org.uk/isisnews/sis19.php).

 

The Fink Committeee identified seven kinds of " experiments

of concern " as those having " a greater likelihood for

potential misuse " , and hence would be subject to further

examination (Box 3).

 

Box 3 Experiments of concern from Fink Report Demonstrate

how to render a vaccine ineffective Confer resistance to

therapeutically useful antibiotics or antiviral agents

Enhance the virulence of a pathogen or render a nonpathogen

virulent Increase transmissibility of a pathogen Alter the

host range of a pathogen Enable the evasion of

diagnostic/detection modalities Enable the weaponization of

a biological agent or toxin

 

 

 

Practically all seven classes of experiments are being done

in genetic engineering, in the course of genetic

modification of bacteria, plants and animals or human beings

in `gene therapy'.

 

Antibiotic resistance marker genes have been released into

the environment with GM crops in field trials or for

commercial growing. Bacteria and viruses are routinely

mutated and recombined in the laboratory, which could change

their host range, increase their virulence or

transmissibility or render existing vaccines ineffective. In

fact, simply strip off the coat from a virus, and the naked

genome would be taken up by non-host cells to generate

infectious viruses. Researchers have been culturing human

viruses in animal cells for decades, which would certainly

alter their host range. They also culture viruses in

mixtures of cells from different species deliberately to

obtain mutants that infect both species, the latest

involving the SARS virus. Similarly, gene therapists have

been wrapping gene transfer vectors in liposomes and other

material to escape immune detection, which is a major

problem with gene therapy vectors. These vectors, though

disarmed, have the potential to regenerate live viruses or

to cause insertion mutagenesis. A third case of leukemia has

surfaced among the children given gene therapy for X-linked

SCID in Paris. Finally, almost any bacterium can be

`weaponised' by transferring into it whole sets of virulence

genes in mobile `pathogenicity islands' or phage coding for

toxins; in experiments that are routinely done in genetic

engineering.

 

Specific examples of dangerous experiments in genetic

engineering

 

A research team in the State University of New York at Stony

Brook made the poliovirus by joining up chemically

synthesized short DNA fragments into a complete sequence

that was then transcribed into the RNA viruses in a cell-

free system containing all the necessary enzymes and cell

parts. The synthetic viruses were capable of infecting

cells.

 

The researchers demonstrated that one could synthesize any

virus from chemical reagents that can be purchased in the

open market, using the public database for the genome

sequence. The experiment is not exactly new. David Baltimore

and colleague had shown in 1981 that a DNA copy of the RNA

genome of poliovirus could be taken up into living cells to

generate infectious virus.

 

Also in 2002, researchers in the University of Pennsylvania,

Philadelphia, showed that a gene in the smallpox variola

virus is more than 100 times more potent than the version in

vaccinia virus (used in vaccines against smallpox) in

inhibiting the human complement enzymes protecting the body

against viral attacks. And that could be why the smallpox

virus is so much more virulent than the vaccinia virus.

 

The gene from the variola virus, therefore, has the

potential to increase the transmissibility of other viruses;

but, as claimed, disabling it may be " therapeutically useful

if smallpox re-emerges " .

 

Should scientists do this kind of experiments and report the

results openly? One could argue that open knowledge is

always a good thing, because it alerts people to the

possibilities and encourages them to be vigilant and to find

means of overcoming the dangers. Whether they should do the

experiment in the first place is questionable.

 

The US is currently proposing to express variola genes in

related pox viruses, and to insert a reporter gene

(expressing green fluorescent protein) in variola itself.

The World Health Assembly is to consider these controversial

proposals in May 2005.

 

There are intentional creations of dangerous agents for

supposedly benign purposes that turned out not to be so

benign. For example, numerous vaccines against HIV/AIDS

based on the envelope glycoprotein gp120 of the HIV are

proving worse than useless ( " AIDS vaccines worse than

useless? " SiS 19

http://www.i-sis.org.uk/isisnews/sis19.php).

A fierce row broke out between leading AIDS researchers in

January 2004 over the continued Phase III trial in Thailand

of a vaccine made with a live-replicating canarypox vector

with a boost of gp120.

 

AIDS researchers have pointed out that the gp120 protein is

strongly immunogenic, but the antibodies fail to protect

against the virus. Instead, it ends up over-stimulating the

immune system, leaving it less able to cope with new

infections. Moreover, the part of the gp120 molecule that

plays the dominant role in provoking an immune response is

the V3 loop. The V3 loop and flanking regions are similar in

base sequence and structure to the antigen-binding region of

the human immunoglobulin (Ig). It has been suggested since

the early 1990s that this immunoglobulin-like domain in

gp120 may interfere with the immune regulatory network. The

V3 loop and its flanking regions are, moreover, located

between recombination signals similar to those found in

human immunoglobulins, and to the Chi recombination hotpots

found in many viruses and bacteria. Consequently, the

immunologically dominant region of gp120 may be involved in

recombining with human immunoglobulin genes resulting in

autoimmune responses, and may also recombine with co-

infecting viruses and bacteria to generate new pathogens.

Evidence of recombination between gp120 and bacterial DNA

has subsequently been found in the sera of AIDS patients.

 

The gp120 gene, spliced into numerous bacterial and viral

vectors with Chi or Chi -like sequences as vaccines,

therefore multiply the odds for recombination to generate

new pathogens. The gp120 gene has been incorporated into GM

maize as a cheap edible vaccine against HIV; while the key

bioweapons institute in Russia has created an artificial

protein consisting of the env and gag antigens from HIV

fused with the hepatitis B virus protein HbsAg as a

HIV/hepatitis B combined vaccine. This is tantamount to

releasing slow bioweapons on the populations. The new

combinations of dangerous genes will have plenty of

opportunity for generating new pathogens through further

gene trafficking with bacteria and viruses in the

environment, of which less than 1% can be cultured and

identified.

 

Also in connection with AIDS, researchers have created a

hybrid simian and human immunodeficiency virus (SIV +HIV =

`SHIV') for testing vaccines, which kills victim primates in

weeks.

 

Some of us have been warning that genetic engineering is

inherently dangerous because it greatly multiplies the scope

and frequency of horizontal gene transfer and recombination,

the major route for creating new viruses and bacteria that

cause disease epidemics. This was brought home when

researchers in Australia `accidentally' transformed a

harmless mousepox virus into a lethal pathogen that killed

all the mice, even those that were supposed to be resistant

to the virus.

 

Headlines in the New Scientist editorial: " The Genie is out,

Biotech has just sprung a nasty surprise. Next time, it

could be catastrophic. " The lead article continued in the

same vein: " Disaster in the making. An engineered mouse

virus leaves us one step away from the ultimate bioweapon. "

 

The researchers added a gene coding for the immune

signalling molecule interleukin-4 to the virus, which they

thought would boost antibody production; instead, it

suppressed both primary antiviral immune responses as well

as adaptive immune responses. The same gene, spliced into a

vaccinia virus previously, delayed the clearance of virus

from the animals; so it may well have the same immune

suppressive effects for all viruses.

 

More surprisingly, a paper published in December 2003

described how disrupting a set of virulence genes in

Mycobacterium tuberculosis, the tuberculosis bacterium,

resulted in a hypervirulent mutant strain that killed all

the mice by 41 weeks, while all the control mice exposed to

the wild-type strain survived.

 

These two cases underscore the complexity of disease

generation by pathogens. They also leave us in no doubt that

apparently innocent experiments could end in nasty

surprises.

 

There have been previous cases that went unnoticed. A paper

published in 2001 described how a method established for

recovering infectious Ebola virus by reverse transcription

enabled the researchers to produce a mutant considerably

more toxic to the host cells than the wild-type.

 

Finally, Willem Stemmer of Maxygen Inc. based in California

invented a DNA shuffling technique in which genes, viral and

bacterial genomes, whatever, could be chopped up into

fragments, then made to join up at random into millions of

recombinants, out of which superior performing enzymes,

metabolically more efficient genomes or more infectious and

virulent pathogens could all be selected.

 

In one experiment, 6 mouse leukemia viruses (MLVs) were

recombined in a single round giving 5 million replicating

recombinant viruses in a matter of hours. Among them were

completely new viruses that infected Chinese Hamster Ovary

cells, which none of the original MLV was capable of. Some

recombinants were 30 to 100 times more stable than the

parental strains. There is no way to characterize all of the

5 million recombinants and they may well include new killer

viruses.

 

Researchers have given up trying to cope with the massive

complexity of the genome and gene function ( " Life after the

Central Dogma " series, SiS 24

http://www.i-sis.org.uk/isisnews/sis24.php).

Instead of rational design, they have resorted to random

genome shuffling to improve industrial microbes, and the

advantage is that the resultant microbes aren't even

classified as genetically engineered, and therefore not

subject to usual regulation and can even be used in the food

industry, we are told. They even suggest using environmental

libraries, containing the DNA of the 99% bacteria unknown to

science, in genome shuffling; but are at least aware of the

dangers involved: " New drug resistances " and emergence of

" accelerated or new pathogenic mechanisms

or diseases " .

 

It has been known for some time that bacterial and viral DNA

can cause immune reactions, because that's part of our

innate immune response that protects us from germs; and this

has become a major obstacle to gene therapy [20]. Any

fragment of double-stranded DNA or RNA down to 25bp is

immunogenic. There is now new evidence that certain

sequences of single stranded RNA also elicit specific immune

reactions.

 

Biotechnological processes and genetic engineering labs are

creating an increasing variety of naked/free nucleic acids

that are currently released unregulated into the

environment, where they can elicit immune reactions, as well

as undergo uncontrolled horizontal gene transfer and

recombination to generate new pathogens or trigger cancer,

should some of them jump into the genome of our cells.

 

Greater hazards of genetic engineering

 

Compare the list of " Dangerous experiments constructs and

deliberate releases in genetic engineering " (Box 4) with the

" Experiments of concern " in the Fink Report (Box 3). The

list for genetic engineering is more extensive and more

insidious; as the deadly biological agents generated cannot

be predicted, nor the millions of cancers that may result

from insertion of constructs with strong viral promoters.

 

 

Box 4 Dangerous experiments, constructs and deliberate

releases in genetic engineering Creating lethal pathogens by

accident, e.g., mousepox virus, `disarmed' tuberculosis

bacterium Making deadly viruses more lethal, e.g., ebola

Making hybrid SIV-HIV virus (for testing vaccines) that

kills monkeys in weeks Releasing AIDS vaccines that are

effectively `slow bioweapons' Releasing gene therapy vectors

that cause leukaemia Releasing antibiotic resistance genes

and potentially toxic or allergenic transgene products

Manipulating genes associated with cancer and immune

suppression on a routine basis Creating cross-species

viruses in cell cultures Generating millions of recombinant

agents in hours by genome shuffling Creating huge varieties

of vectors, DNA vaccines and endless species of rDNAs and

rRNAs that can generate new pathogens, cause immune

reactions, insertion mutations and cancers

 

 

 

Genetic engineering hazards preventable

 

The good news is that practically all the hazards of genetic

engineering can be prevented: by tightening the regulation

of contained use as has been done for deliberate release. I

wrote a report with three colleagues in 2001, Slipping

through the Regulatory Net: `Naked' and `Free' Nucleic Acids

http://www.i-sis.org.uk/onlinestore/books.php#17 . The

report was reprinted 2002 and 2004, because our message has

not yet got through to the regulators.

 

Current European regulation allows users to release directly

into the environment certain live transgenic microorganisms

considered nonpathogenic or otherwise safe in liquid waste,

although there is no agreement across European countries as

to which bacteria are pathogens.

 

Meanwhile, all killed microorganisms and cells containing

transgenic DNA are disposed of as solid waste, and are

either recycled as food, feed and fertilizer, or disposed of

in landfill.

 

There is an urgent need for validated procedures to ensure

that all kinds of transgenic nucleic acids from contained

use are thoroughly degraded before transgenic wastes are

released into the environment.

 

Meanwhile, there should be no environmental releases of GM

crops unless and until they can be proven safe beyond

reasonable doubt.

 

 

 

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