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Para peneliti menyusun strategi untuk mengakali bakteri
Date:
August 4, 2015
Source:
Rice University
Summary:
Para ilmuwan telah menemukan mekanisme dimana bakteri dapat menjadi resisten terhadap pengobatan dengan antibiotik . Mereka berharap untuk mengembangkan strategi untuk melestarikan efektivitas antibiotik
.............. The Rice laboratorium biokimia Yousif Shampo mengidentifikasi mekanisme genetik yang memungkinkan bakteri untuk mengembangkan resistensi sekaligus dan cepat menyebar kemampuan untuk orang lain dalam suatu populasi .....more
Researchers
strategize to outsmart bacteria
Mutations that allow bacteria to resist antibiotics identified
Date:
August 4, 2015
Source:
Rice University
Summary:
Scientists have found a mechanism by which bacteria can become resistant to
treatment with antibiotics. They hope to develop strategies to preserve the
effectiveness of antibiotics.
...................
Rice University scientists are developing strategies to keep germs from
evolving resistance to antibiotics by heading them off at the pass.
The Rice lab of biochemist Yousif Shamoo identified a genetic mechanism
that allows bacteria to develop resistance while simultaneously and quickly
spreading the capability to others in a population.
"This is really a double whammy," Shamoo said. "Our finding
that these bacteria become more antibiotic-resistant while at the same time
spreading their resistance more efficiently was really surprising and
worrying."
The researchers hope this knowledge will help predict when and how
bacterial strains are likely to develop resistance to future antibiotics and
perhaps act to halt -- or at least slow -- the process. The research appeared
in the journal Molecular Biology and Evolution.
Antibiotic resistance is responsible for hundreds of thousands of
infections acquired in American hospitals, according to the Centers for Disease
Control and Prevention. These infections kill thousands of patients. While
progress is being made to control microbes that spread infection, the
overriding concern remains that drugs developed to kill germs will ultimately
stop working.
Until now, the only effective way to keep antibiotics from losing their
potency has been to use them sparingly, said Kathryn Beabout, a Rice graduate
student and lead author of the new paper.
"The best you can do is try to manage when you use the
antibiotic," she said. "But our idea is that if we can predict how
resistance is going to emerge, we can come up with strategies to use
antibiotics in a more intelligent way."
The lab used experimental evolution to study a specific combination of
bacteria and an antibiotic that had not been in common contact. The bacteria of
interest was Enterococcus faecalis, found in the gastrointestinal tract. The
antibiotic was tigecycline, a highly effective but sparingly used derivative of
tetracycline. The goal was to see how horizontal gene transfer -- the means by
which cells pass along favorable mutations -- would work in the presence of the
antibiotic.
It worked quite well, they found.
That was due mostly to a chunk of mutant DNA known as Tn916, a transposon
that can change its position along the genome, duplicate itself and pass to
other cells in a process known as parasexuality, the exchange of genetic
material between cells. Tn916 carries the tetracycline-resistance gene called tetM,
which has been found in many pathogens, according to the researchers.
Without tigecycline, Tn916 moves only infrequently, as about one in 120,000
bacteria transfer their resistance to another bacteria. But in the presence of
the antibiotic, Tn916 movement rose to one in 50 bacteria, due to a mutation
that also causes overproduction of tetM. The resistance mechanism required the
presence of two mutations, to Tn916 and to a gene that encodes the ribosomal
S10 protein, both of which could be easily identified through pre- and
post-experiment gene sequencing.
"Tetracyclines bind to the cell's ribosome and prevent it from making
proteins," Beabout said. "TetM is a protein that comes in and kicks
tetracyclines off and frees the ribosome, but it doesn't usually work against
tigecycline. We didn't expect to see it emerge."
In their experiments, the researchers discovered the mutations led to the
production of large amounts of tetM proteins. "When you have an abundance
of tetM, they're able to have an effect against tigecycline," Beabout
said. "What's really interesting is that tetM is on a conjugative
transposon (Tn916), which is a DNA element that's able to move around the
genome and can be transferred to other cells.
"An additional effect of this tetM overexpression is that the Tn916
transposon moves more," she said. "It passes from cell to cell more.
So we are seeing both resistance and an increase in the frequency at which
resistance is able to transfer from cell to cell and move around genomes.
That's definitely worrisome."
The lab allowed colonies of E. faecalis to grow rapidly in bioreactors for
19 and 24 days. The results showed the bacteria were remarkably proficient at
picking up the resistance gene. "All the cells at the beginning had one
copy of the transposon, and throughout the experiment they started acquiring
additional copies. The copy number of the transposon was increasing very
rapidly."
Shamoo hopes the research leads to drugs that inhibit resistance mechanisms
and preserve the effectiveness of new antibiotics.
"Our lab does a form of evolutionary reconnaissance into how bacteria
will become resistant in the future," Shamoo said. "The
pharmaceutical industry and other labs can use this information to develop
drugs to stay ahead of the pathogens."
Story Source:
The above post is reprinted from materials provided
by Rice University. Note: Materials may be edited
for content and length.
Journal Reference:
1.
K. Beabout, T. G. Hammerstrom, T. T. Wang, M. Bhatty, P. J. Christie, G.
Saxer, Y. Shamoo. Rampant Parasexuality Evolves in a Hospital Pathogen
during Antibiotic Selection. Molecular Biology and Evolution,
2015; DOI:10.1093/molbev/msv133