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May 29, 2003
Contact: Robert Sanders
(510) 643-6998
rls@pa.urel.berkeley.edu
Transplanting genes from yeast into bacteria,
with an added pinch from wormwood,
yields cheap way to make antimalarial "miracle"
drug
Berkeley - By combining genes from three separate organisms into
a single bacterial factory, University of California, Berkeley,
chemical engineers have developed a simpler, less expensive way
to make an antimalaria "miracle" drug that is urgently
needed in Third World countries.
The drug, artemisinin, is one of the most promising next-generation
antimalarials because of its effectiveness against strains of the
malaria parasite now resistant to front-line drugs. It is now too
expensive for broad use in countries such as Africa where it is
most needed.
"By inserting these genes into bacteria, we've given them the
ability to make artemisinin quickly, efficiently and cheaply, and
in an environmentally friendly way," said Jay D. Keasling,
professor of chemical engineering at UC Berkeley. His research is
being published online June 1 in Nature Biotechnology and is scheduled
to run in the journal's printed edition in July.
Keasling's technique for transplanting yeast and plant genes to
construct an entirely new metabolic pathway inside bacteria can
be used generally to produce a broad family of so-called isoprenoids
-
chemical precursors to many plant-derived drugs and chemicals of
interest to industry, including the anticancer drug taxol and various
food additives. Isoprenoids, found widely in microbes, plants and
marine organisms, currently are very expensive for the chemical
industry to synthesize from scratch and nearly as expensive to extract
from plant material.
"This process could be of interest to everybody - drug companies
making cancer agents, the government producing antibiotics against
bioterror agents, or industries making flavors and fragrances,"
Keasling said. "A company could tweak the bacteria a bit, adding
any number of plant genes involved in making the chemical of interest,
to get pretty much any isoprenoid. It would be easy to do now."
Keasling's achievement is a big advance over the day-to-day practice
in today's biotechnology industry. There, protein drugs are produced
primarily through fermentation by recombinant yeast that seldom
have
more than one gene inserted in them, perhaps with an additional
piece of DNA fused to that gene to make the yeast spit out the protein.
Scientists have found it much harder to transplant entire gene systems
to build new chemical assembly lines. Keasling, however, assembled
10 genes, including control elements, from three different
organisms - bacteria, yeast and wormwood- and got them to work together
successfully.
The goal of Keasling's group was to create bacteria capable of producing
chemicals that can be used to make many kinds of isoprenoids, a
class of some 30,000 known compounds of immense
interest to the chemical and pharmaceutical industries. Isoprenoids
are expensive to synthesize, however, and natural isoprenoids like
taxol are costly to isolate from plant material. Often, too, these
plants are rare and endangered, so that harvesting causes environmental
damage.
Keasling's approach leapfrogs the bulk of the laborious synthesis
necessary today, leaving only a few additional chemical alterations
to obtain the desired drug or chemical. The development took more
than three years and involved numerous people, primarily Keasling's
UC Berkeley coauthors: post-doctoral fellows Vincent J. J. Martin
and Jack D. Newman and graduate students Douglas J. Pitera and
Sydnor T. Withers.
Other laboratories have tried to engineer the common intestinal
bacteria, E. coli, to make isoprenoid precursors that could be used
to produce drugs or industrial chemicals, but the methods involved
hijacking the cell's own production factory. E. coli produce chemicals
that can be used to make isoprenoid precursors, but diverting these
chemicals to make more of them entails overcoming control mechanisms
within the bacterial cell that are not fully understood.
Keaslings innovation was to leave E. coli's isoprenoid pathway alone,
but transplant a similar pathway from yeast. This pathway takes
in a common chemical in E. coli, mevalonate, and sends it down
a cascade of reactions resulting in isoprenoid precursors, primarily
isopentenyl pyrophospahate (IPP) and dimethylallyl pyrophospate
(DMAPP). In initial experiments, these isoprenoids accumulated in
the cells and threw then out of whack - the cells either stopped
growing or mutated to avoid the toxins - so he stuck in a wormwood
gene for an enzyme that converts them to amorphadiene, a chemical
precursor of artemisinin that the cells can deal with.
Artemisinin has been known to the Chinese for 2,000 years as an
herbal medicine, qinghaosu. Though highly effective at killing the
malaria parasite, currently it is expensive to manufacture because
of the costs of chemical extraction from wormwood (Artemisia annua,
a relative of the herb used to make absinthe) or total laboratory
synthesis. The expense stands in the way of its use in Africa, where
resistance is rapidly spreading to the first-line antimalarial drugs-
chloroquine and sulfadoxine-pyrimethamine.
Since their first success, Keasling and his laboratory colleagues
have improved yield from the bacteria 10,000 fold, nearly to the
level at which industrial production of the antimalarial drug would
be cost effective. Another order of magnitude is doable, he said.
Keasling noted, however, that it is feasible to insert another
chemical step into the bacteria to produce a compound, artemisinic
acid, that is even closer to artemisinin. And one possibility is
to let the bacteria grow and evolve in a petri dish and see if they
can produce derivatives of artemisinin that have similar or improved
effects on the malaria parasite.
"With the ability to produce taxol or amorphadiene in E. coli,
we can easily encourage the bacteria to evolve a molecule not found
in nature that could be more effective in human disease," he
said.
IPP and DMAPP are precursors to all isoprenoids, which means that
the bacterial strains Keasling's group produced "can serve
as platform hosts for the production of any terpenoid compound for
which the biosynthetic genes are available," they write in
their paper.
The family of isoprenoids includes chemicals called terpenoids,
which give plants their aroma and which also include taxol from
the Pacific yew tree, and carotenoids, such as the compounds that
give
plants their color. Aside from their importance in flavorings, colorings
and perfumes, isoprenoids from organisms as diverse as coral and
fungi are being identified as potential drugs.
"The ability to produce amorphadiene in a simple organism like
E. coli opens up a whole realm of possible molecular backbones that
can later be functionalized to make drugs," Keasling said.
Keasling's lab concentrates on metabolic engineering of microbes
to do complex chemical syntheses to replace current methods that
are expensive, polluting and wasteful of resources.
"Enzymes are very specific catalysts that can accomplish in
far fewer steps what takes us many complex steps in the laboratory,"
Keasling said. "We are trying to put enzymes inside cells to
create
a biosynthetic cascade using the cell's metabolites as starting
material, to provide essentially complete molecules in an aqueous
environment using no toxic reagents. We're taking an organism,
co-opting its metabolism, and using it for our benefit now."
"This is just a start," he emphasized. "I really
want to push the limits of the organism."
Keasling's work was supported by the National Science Foundation,
UC BioSTAR and Maxygen, Inc. of Redwood City, Calif.
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NOTE: Jay Keasling can be reached at (510) 642-4862
or
keasling@socrates.berkeley.edu.
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