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Bacterial
'Battle For Survival' Leads To New Antibiotic
Tuesday, February 26, 2008
Holds promise for
treating stomach ulcers
MIT biologists have provoked
soil-dwelling bacteria into producing a new type of antibiotic by
pitting them against another strain of bacteria in a battle for
survival.
The antibiotic holds promise
for treatment of Helicobacter pylori, which causes stomach ulcers
in humans. Also, figuring out the still murky explanation for how
the new antibiotic was produced could help scientists develop
strategies for finding other new antibiotics.
The work is reported in the
February issue of the Journal of the American Chemical Society.
A combination of luck, patience
and good detective work contributed to the discovery of the new
antibiotic, according to Philip Lessard, research scientist in
Professor Anthony Sinskey's laboratory at MIT.
Rhodococcus Fascians
Bacteria
A
Gram positive bacterial phytopathogen that causes leafy gall
disease.[1] R. fascians the only phytopathogenic member of
the Rhodococcus genus; its host range includes both
dicotyledonous and monocotyledonous hosts. Because it
commonly afflicts tobacco (Nicotiana) plants, it is an
agriculturally significant pathogen.
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Sinskey's lab has been
studying Rhodococcus, a type of soil-dwelling bacteria, for many
years. While sequencing the genome of one Rhodococcus species,
the researchers noticed that a large number of genes seemed to
code for secondary metabolic products, which are compounds such
as antibiotics, toxins and pigments.
However, Rhodococcus does not
normally produce antibiotics. Many bacteria have genes for
antibiotics that are only activated when the bacteria are
threatened in some way, so the researchers suspected that might
be true of Rhodococcus.
Kazuhiko Kurosawa, a
postdoctoral associate in the Department of Biology, decided to
try to provoke the bacteria into synthesizing antibiotics by
placing them in stressful environments. He tried turning the
temperature up and down, then altered the bacteria's growth
medium, but nothing worked.
Kurosawa then decided to stress
the Rhodococcus bacteria by forcing them to grow in the presence
of a competing bacteria, a strain of Streptomyces. Streptomyces
produces an antibiotic that normally kills other bacteria, but in
one of the experimental test tubes, Rhodococcus started producing
its own antibiotic, which wiped out the Streptomyces.
The researchers isolated the
antibiotic, dubbed it rhodostreptomycin, and started testing it
to see what else it would kill. It proved effective against many
other strains of bacteria, most notably Helicobacter pylori.
Rhodostreptomycin is a promising candidate to treat H. pylori
because it can survive in very acidic environments such as the
stomach.
The antibiotic turned out to be
a type of molecule called an aminoglycoside, composed of peculiar
sugars, one of which has a ring structure that has not been seen
before. The ring structure could offer chemists a new target for
modification, allowing them to synthesize antibiotics that are
more effective and/or stable.
"Even if
(rhodostreptomycin) is not the best antibiotic, it provides new
structures to make chemical derivatives of," said Lessard.
"This may be a starting point for new antibiotics."
One mystery still to be solved
is why Rhodococcus started producing this antibiotic. One theory
is that the presence of the competing strain of bacteria caused
Rhodococcus to "raise the alarm" and turn on new genes.
The version of Rhodococcus that
produces the antibiotic has a "megaplasmid," or large
segment of extra DNA, that it received from Streptomyces. A
logical conclusion is that the plasmid carries the gene for
rhodostreptomycin, but the researchers have sequenced more than
half of the plasmid and found no genes that correlate to the
antibiotic.
Another theory is that the
plasmid itself served as the "insult" that provoked
Rhodococcus into producing the antibiotic. Alternatively, it is
possible that some kind of interaction of the two bacterial
genomes produced the new antibiotic.
"Somehow the genes in the
megaplasmid combined with the genes in Rhodococcus and together
they produced something that neither parent could make alone,"
said Lessard.
If scientists could figure out
how that happens, they could start to manipulate bacterial
genomes in a more methodical fashion to design new antibiotics.
Other authors of the paper are
T.G. Sambandan, research scientist in MIT's Department of
Biology, MIT professors Anthony Sinskey of biology and ChoKyun
Rha of the Biomaterials Science and Engineering Laboratory, and
Ion Ghiviriga and Joanna Barbara of the University of Florida.
The research was funded by the
Cambridge-MIT Institute and the Malaysia-MIT Biotechnology
Partnership Program.
Source:
MIT / Anne Trafton
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