mugwump
06-10-2006, 08:41
This is an offshoot of issues raised in the pandemic flu thread.
Most computer viruses nowadays are released by know-nothing little gits who download "starter kits" from the 'net. The make a few formulaic changes and release them into the wild. Are we headed the same way with bio agents? I say yes.
The ease with which RNA and DNA can be sequenced, shuffled, and reassembled nowadays is shocking. Most people don't realize the magnitude of the revolution that's taken place. If the same advances had taken place in transportation we'd all be flitting around wearing Jetsons backpacks running on water vapor.
In the not-too-distant future any whack-job with access to a University-grade molecular chemistry lab will be able to whip up a bio weapon. Hate Sephardic Jews? Blacks? Northern Europeans? If you can identify a genetic marker, the day isn't too far off when you can target that group with a bio agent.
Nice, eh? Note that the entire genetic sequences for smallpox, polio, etc. are already in the public domain.
Even well intentioned research has the potential for disaster. This is a matter of intense debate when we are talking about RNA and DNA vaccines (Kate or Cyrus).
Check out the following and then tell me, what do we do? And note that when the author states that these weapons will be within reach of states willing to invest "large sums" I think he's being a bit disingenuous. The costs would be a tiny fraction of a nuclear development program and would have the side benefit of being undetectable. :munchin
http://www.newscientist.com/channel/...d=NBADKCECMFKF
Biologists risk becoming accidental terrorists
* 10 June 2006
* From New Scientist Print Edition. Subscribe and get 4 free issues.
* Peter Aldhous
“In just a few years, designer bioweapons could be within reach of a rogue state”
FOR anyone who doubts that well-intentioned research can sometimes have potentially deadly consequences, Ron Jackson has a cautionary tale. Working for the wildlife division of Australia's national research agency, he set out to make a contraceptive vaccine to control plagues of mice. What he ended up with was a deadly mousepox virus that resists vaccination - and a recipe for doing the same for smallpox.
This story, revealed by New Scientist more than five years ago (13 January 2001, p 4), caught everyone off guard. Then came the 9/11 terrorist attacks and the anthrax letters. Bioterrorism was propelled to the top of official worry lists in the US, and it was clear that legitimate research could produce pathogens much nastier than anthrax.
Despite these fears, it seems to me from my reporting on these issues that many biologists remain ignorant of the "dual-use" dilemma - that biological advances can provide a bioweapons cookbook. Researchers trying to improve human health by, for example, altering specific immune responses rarely consider that the same technologies could be converted into horrifying weapons.
Thankfully, Al-Qaida is not thought to have the expertise to create designer bioweapons. In a few years, however, such capabilities may well be within reach of a rogue state willing to invest large sums in clandestine research. This does not mean that all data that could be turned to destructive ends should be declared a military secret - although a small proportion might need to be classified. It does mean that biologists should pay more attention to the sinister potential of their work and avoid lines of enquiry that pose more dangers than they promise benefits.
Scientific societies should be raising awareness of these issues among their members, and the American Society for Microbiology (ASM) points the way. Its website hosts a wealth of resources on bioterrorism and biosecurity. Other societies are still lagging behind. The American Association of Immunologists has yet to adopt relevant policies, even though manipulation of the immune system is central to this debate. Jackson's deadly mousepox owed its pathogenicity to an unexpected effect of IL-4, an immune-signalling molecule. He engineered a strain of mousepox to produce proteins carried by mouse eggs, and reasoned that adding the gene for IL-4 would stimulate antibodies against these proteins, sterilising the mice. Instead, it shut down the cellular arm of the immune system, needed to fight viral infection.
Journals also have a role to play. Many now scrutinise the papers they receive to avoid publishing information that poses serious security concerns, though few papers merit censorship. Much more useful is the promotion of debate around dual-use research. This has happened in obvious cases such as the recreation of the virus that caused the 1918 flu pandemic, but other papers with bioweapons potential continue to appear without comment.
Take a paper on a new vector for gene therapy, published in February by Nature Biotechnology (vol 24, p 198). Researchers at the University of California, Berkeley, used "gene shuffling" technology, a form of accelerated evolution, to create harmless viruses that are able to evade "neutralising" antibodies. It is a valuable project, because these antibodies can wipe out viral vectors before they deliver their therapeutic genes. The danger is that the same approach could help deadly viruses slip under the immune system's radar. Lead researcher David Schaffer told me that he would never attempt anything similar with a human pathogen, but neither his paper, nor the commentary on the work published with it, mentioned the dual-use potential.
“In just a few years, designer bioweapons could be within reach of a rogue state”
Even when researchers address the implications of their work for biowarfare, some of their ideas on tackling the problem are naive. At the heart of synthetic biology lies the ability to build large sequences of DNA, and even entire viruses, from scratch. It may be possible to obtain DNA to build a bioweapon from companies that synthesise genes to order (New Scientist, 12 November 2005, p 8). At the Synthetic Biology 2.0 meeting in Berkeley last month, researchers pledged to develop better methods of identifying suspect orders, yet in the online debate that preceded it one graduate student suggested placing "malicious orders" to test the effectiveness of companies' screening procedures. Although some sort of verification may be useful, posing as a terrorist would be seriously misguided, and depending on the sequences requested could breach US anti-terror law.
This incident points to perhaps the most urgent need: better education of graduate students. Few universities offer classes in biosecurity, and given the dearth of experts in the field, they have some excuse. But not for much longer: within the next month, the Federation of American Scientists will be releasing a biosecurity curriculum, complete with dual-use case studies, including an interview with Jackson. It should be a required option for anyone planning a career in biomedical research.
From issue 2555 of New Scientist magazine, 10 June 2006, page 24
Most computer viruses nowadays are released by know-nothing little gits who download "starter kits" from the 'net. The make a few formulaic changes and release them into the wild. Are we headed the same way with bio agents? I say yes.
The ease with which RNA and DNA can be sequenced, shuffled, and reassembled nowadays is shocking. Most people don't realize the magnitude of the revolution that's taken place. If the same advances had taken place in transportation we'd all be flitting around wearing Jetsons backpacks running on water vapor.
In the not-too-distant future any whack-job with access to a University-grade molecular chemistry lab will be able to whip up a bio weapon. Hate Sephardic Jews? Blacks? Northern Europeans? If you can identify a genetic marker, the day isn't too far off when you can target that group with a bio agent.
Nice, eh? Note that the entire genetic sequences for smallpox, polio, etc. are already in the public domain.
Even well intentioned research has the potential for disaster. This is a matter of intense debate when we are talking about RNA and DNA vaccines (Kate or Cyrus).
Check out the following and then tell me, what do we do? And note that when the author states that these weapons will be within reach of states willing to invest "large sums" I think he's being a bit disingenuous. The costs would be a tiny fraction of a nuclear development program and would have the side benefit of being undetectable. :munchin
http://www.newscientist.com/channel/...d=NBADKCECMFKF
Biologists risk becoming accidental terrorists
* 10 June 2006
* From New Scientist Print Edition. Subscribe and get 4 free issues.
* Peter Aldhous
“In just a few years, designer bioweapons could be within reach of a rogue state”
FOR anyone who doubts that well-intentioned research can sometimes have potentially deadly consequences, Ron Jackson has a cautionary tale. Working for the wildlife division of Australia's national research agency, he set out to make a contraceptive vaccine to control plagues of mice. What he ended up with was a deadly mousepox virus that resists vaccination - and a recipe for doing the same for smallpox.
This story, revealed by New Scientist more than five years ago (13 January 2001, p 4), caught everyone off guard. Then came the 9/11 terrorist attacks and the anthrax letters. Bioterrorism was propelled to the top of official worry lists in the US, and it was clear that legitimate research could produce pathogens much nastier than anthrax.
Despite these fears, it seems to me from my reporting on these issues that many biologists remain ignorant of the "dual-use" dilemma - that biological advances can provide a bioweapons cookbook. Researchers trying to improve human health by, for example, altering specific immune responses rarely consider that the same technologies could be converted into horrifying weapons.
Thankfully, Al-Qaida is not thought to have the expertise to create designer bioweapons. In a few years, however, such capabilities may well be within reach of a rogue state willing to invest large sums in clandestine research. This does not mean that all data that could be turned to destructive ends should be declared a military secret - although a small proportion might need to be classified. It does mean that biologists should pay more attention to the sinister potential of their work and avoid lines of enquiry that pose more dangers than they promise benefits.
Scientific societies should be raising awareness of these issues among their members, and the American Society for Microbiology (ASM) points the way. Its website hosts a wealth of resources on bioterrorism and biosecurity. Other societies are still lagging behind. The American Association of Immunologists has yet to adopt relevant policies, even though manipulation of the immune system is central to this debate. Jackson's deadly mousepox owed its pathogenicity to an unexpected effect of IL-4, an immune-signalling molecule. He engineered a strain of mousepox to produce proteins carried by mouse eggs, and reasoned that adding the gene for IL-4 would stimulate antibodies against these proteins, sterilising the mice. Instead, it shut down the cellular arm of the immune system, needed to fight viral infection.
Journals also have a role to play. Many now scrutinise the papers they receive to avoid publishing information that poses serious security concerns, though few papers merit censorship. Much more useful is the promotion of debate around dual-use research. This has happened in obvious cases such as the recreation of the virus that caused the 1918 flu pandemic, but other papers with bioweapons potential continue to appear without comment.
Take a paper on a new vector for gene therapy, published in February by Nature Biotechnology (vol 24, p 198). Researchers at the University of California, Berkeley, used "gene shuffling" technology, a form of accelerated evolution, to create harmless viruses that are able to evade "neutralising" antibodies. It is a valuable project, because these antibodies can wipe out viral vectors before they deliver their therapeutic genes. The danger is that the same approach could help deadly viruses slip under the immune system's radar. Lead researcher David Schaffer told me that he would never attempt anything similar with a human pathogen, but neither his paper, nor the commentary on the work published with it, mentioned the dual-use potential.
“In just a few years, designer bioweapons could be within reach of a rogue state”
Even when researchers address the implications of their work for biowarfare, some of their ideas on tackling the problem are naive. At the heart of synthetic biology lies the ability to build large sequences of DNA, and even entire viruses, from scratch. It may be possible to obtain DNA to build a bioweapon from companies that synthesise genes to order (New Scientist, 12 November 2005, p 8). At the Synthetic Biology 2.0 meeting in Berkeley last month, researchers pledged to develop better methods of identifying suspect orders, yet in the online debate that preceded it one graduate student suggested placing "malicious orders" to test the effectiveness of companies' screening procedures. Although some sort of verification may be useful, posing as a terrorist would be seriously misguided, and depending on the sequences requested could breach US anti-terror law.
This incident points to perhaps the most urgent need: better education of graduate students. Few universities offer classes in biosecurity, and given the dearth of experts in the field, they have some excuse. But not for much longer: within the next month, the Federation of American Scientists will be releasing a biosecurity curriculum, complete with dual-use case studies, including an interview with Jackson. It should be a required option for anyone planning a career in biomedical research.
From issue 2555 of New Scientist magazine, 10 June 2006, page 24