Thursday, February 10, 2005

BBC, New York Times on open source practices in biotechnology

In a paper in the journal Nature, out on Feb. 10, Dr. Richard Jefferson of Australia offers a method of transferring foreign genes into plants that may be outside the scope of patent claims employing Agrobacterium tumifaciens. The properties of Agrobacterium tumifaciens allow scientists to engineer any desired genes into the bacterial DNA and then insert them into plant genomes.

Some of the policy issues surrounding this development are not unrelated to policy issues in the case Merck v. Integra, now pending before the US Supreme Court.

from Paul Rincon of the BBC (Feb. 10, 2005):

In a paper published in the British journal Nature, Dr Richard Jefferson of Cambia in Canberra, Australia and his colleagues describe how they engineered benign bacteria capable of transferring genes into plants.

By introducing "disarmed" plasmids together with a helper molecule into bacteria, they were able to transfer genes into tobacco, rice and Arabidopsis plants.

The open-source method is not bound by the patent system. So scientists are free to use the technique without commercial restrictions, but must share any improvements they make to this scientific "toolkit".

"It isn't about making it cost-free or busting patents. It's about harnessing the latent creativity of a very large number of people who are out of the loop right now," said Dr Jefferson, a descendent of Thomas Jefferson, the third president of the US and also the country's first patent commissioner.

"I see this as unfinished family business," he told the BBC News website.

The team hopes this approach to managing intellectual property could jumpstart research into agricultural biotechnology in developing countries, addressing issues of hunger and poverty.

Markus Payer, a spokesperson for Syngenta, said the company would look carefully at the research but that it had no current business implications for the company.

"There are already other technologies around [for researchers to use]. This is not the first and only alternative to Agrobacterium," said Mr Payer.

"We are contributing investment to agriculture and opening scientific findings for public and academic use."

Dr Jefferson said initiatives like his own would benefit the marketplace, encouraging more competition and innovation. He cited IBM as a company that had made money out of the open-source model in software.

Praising the work, Dr Jeff Dangl, a plant scientist at the University of North Carolina in Chapel Hill, US, said the science was "very tight".

"This group's most important contribution...may well be to open up facile transformation of legumes, and other important crops for which Agrobacterium or expensive tissue culture-based methods are either inefficient or simply not possible," he commented.

Dr Wendy Harwood of the John Innes Centre in Norwich, UK, said the work "may open up more efficient ways of carrying out gene transfer".

The team behind the Nature paper has also launched a collaborative research platform on the internet called BioForge, which will allow scientists to develop new technology within a protected "commons".








from Andrew Pollack of the New York Times (Feb. 10, 2005):

In a paper, being published today in the journal Nature, Australian researchers said that they had modified three types of bacteria so they could be used for transferring desirable genes into plants and that they had inserted genes into three plants - rice, tobacco and Arabidopsis, a weed often used in lab experiments.

The new technology-sharing initiative, called the Biological Innovation for Open Society, or BIOS, is the brainchild of Richard A. Jefferson, chief executive of Cambia, a nonprofit Australian research institute. Both Cambia and BIOS are supported by the Rockefeller Foundation.

The people behind the initiative say that patents covering the basic tools for genetically engineering plants - which are controlled by companies like Monsanto, Syngenta and Bayer CropScience - have impeded the use of biotechnology in developing countries and also in smaller-acreage crops, like vegetables, in the United States.

The issue has become a larger one in recent years as agricultural research has increasingly shifted from a public-sector activity involving governments and universities to a private-sector one led by companies.

Gary Toenniessen, director of food security at the Rockefeller Foundation in New York, said Dr. Jefferson "has come up with two technologies that basically engineer around two of the tools that the companies really have control of and that are a major constraint to applying biotechnology to crop improvement."

Spokesmen for Monsanto and for Syngenta, a European company, said they welcomed public innovation and had made contributions of data and technology to help improve crops in developing countries.

But Dr. Toenniessen said there was often red tape involved and the process did not always work. He said, for instance, that specialists in some Asian countries want to grow varieties of insect-resistant rice developed at American universities. But that cannot be done yet, he said, because the universities were granted rights by the patent holders to use the technology only for research, not for commercial purposes.

The main technique now used to splice non-native genes into plants relies on Agrobacterium tumefaciens, a soil-dwelling microbe that in its natural form causes crown gall disease by inserting its own genes into plant cells. Biotechnologists remove some of the disease-causing genes from the bacterium and insert the genes they want added to the plant, such as those providing resistance to insects or herbicides. That technique is covered by various companies' patents.

Dr. Jefferson and other researchers at Cambia have modified other types of bacteria so they can also ferry genes into plants. They did this by transferring the necessary DNA from the Agrobacterium into the other bacteria through a natural mechanism that microbes use to exchange genes.

Whether this technique, called TransBacter, would withstand a patent challenge is still unclear, although Dr. Jefferson, who has compiled a database of life-science patents, says he is confident that it would.

There are limits to the usefulness of the new technique, because it is not yet highly efficient, and measures beyond gene transfer are required in making biotechnology crops. But one of those measures, a marker system so scientists can tell which plant cells take up the foreign genes, is also being made available by BIOS.

Dr. Jefferson said that if scientists worldwide get behind a collective research effort, the new genetic engineering technique would be quickly improved and new tools developed, just as programmers everywhere are constantly sending fixes and upgrades to Linux and other open-source software programs.

He said that while he wanted to provide competition for Monsanto and other companies just as open-source software did with Microsoft, he hoped that some companies might use the technology. The more corporate participation, the more likely is corporate sponsorship of his foundation.

Dr. Jefferson said that while users of the gene-splicing technology would be required to put any improvements they made into the common pool, companies and universities would be allowed to patent any products they made using the technology, like a genetically modified crop.

BIOS is one of several efforts aimed at more open biotechnology development. Software used for biological analysis has been developed using open-source methods, and certain databases, including the one containing the human genetic code, are freely available. Scientists at the Massachusetts Institute of Technology have been trying to create a catalog of biological components that others could use to impart novel functions into cells. But BIOS seems to be the first instance of applying the model to a laboratory technique.

There are factors that could make it more difficult for the open-source approach to catch on in biology than in software. Writing software usually requires just a computer and a desk, while biological research requires advanced equipment and can be much more expensive.

Patents also seem more important in spurring innovation in biotechnology than in software, said Arti Rai, a professor of law at Duke University. For that reason, Professor Rai said, it was probably wise of Dr. Jefferson to allow crops developed using the tools from BIOS to be patented.

"It's a creative way of thinking how to maintain a commons in the biological research space," she said.



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