Biomedical scientists collaborating on translational research at two
Buffalo institutions are reporting the discovery of a novel, and
heretofore unrecognized, set of genes essential for the growth of
potentially lethal, drug-resistant bacteria. The study not only reveals
multiple, new drug targets for this human infection, it also suggests
that the typical methods of studying bacteria in rich laboratory media
may not be the best way to identify much-needed antimicrobial drug
targets.
The paper focuses on a Gram-negative bacteria called A. baumannii. It is published in the current issue of mBio, as an 'editor's choice' paper. The findings may be relevant to other Gram-negative bacteria as well.
A. baumannii is responsible for a growing number of
hospital-acquired infections around the world. It can be fatal to
patients with serious illnesses, the elderly and those who have had
surgeries. Infections also have been seen in soldiers returning from
Iraq and Afghanistan with battlefield injuries.
"Generally, healthy people don't get infected," explains lead author
Timothy C. Umland, PhD, research scientist at Hauptman-Woodward Medical
Research Institute (HWI) and professor of structural biology in the
University at Buffalo School of Medicine and Biomedical Sciences. "But
what's challenging about A. baumannii is that it can survive in
the hospital environment and is very hard to eradicate with common
disinfectants, leading to healthcare-associated infections."
Typically, the way that essential genes for microbial pathogens are
found is by growing the bacteria under optimal conditions, says
co-author Thomas A. Russo, MD, professor in the UB departments of
medicine and microbiology and immunology. Genes found to be essential
for growth are then entered into the Database of Essential Genes (DEG),
which contains genes considered essential for the sustenance of each
organism.
The researchers at HWI and UB decided to try to better understand what A. baumannii needs in order to grow when infecting patients.
"Laboratory conditions create a different type of environment from
what happens in patients," Umland says, "where certain nutrients the
bacteria need will be present in very low amounts and where the bacteria
encounter immune and inflammatory responses. We were purposely trying
to test for genes that are important for growth in these more realistic
environments."
The team performed a genetic screen designed to identify bacterial genes absolutely required for the growth and survival of A. baumannii in human ascites, a peritoneal fluid that accumulates under a variety of pathologic conditions.
"We found that nearly all of these 18 genes had not been identified
as essential in the DEG because they weren't necessary for growth in an
ideal laboratory environment," explains Russo. "This is a large set of
genes that has been flying under the radar."
He adds: "The biggest concern is that quite a few strains of A. baumannii
are resistant to nearly all anti-microbial drugs and some strains are
resistant to all of them. To make things worse, there are no new agents
being tested for human use in the drug pipeline that are active against A. baumannii. This is a huge problem."
Not only do the new genes suggest brand new, high-value drug targets for A. baumannii infections, but the genes that have been identified may be relevant to other Gram-negative infections.
"So far, our computational models show that these genes seem to be
conserved across Gram-negative infections, meaning that they may lead to
new drugs that would be effective for other drug-resistant infections
as well," says Umland.
The researchers who collaborated on the study are now pursuing
antibacterial drug discovery efforts focused on the newly identified
bacterial targets.
The research was funded by grants from the Telemedicine and Advance
Technical Research Center of the U.S. Army Medical Research and Materiel
Command, an interdisciplinary grant from UB and a VA Merit Review grant
from the U.S. Department of Veterans Affairs.
Other co-authors are: L. Wayne Schultz, PhD, of HWI and UB, and
Ulrike MacDonald, Janet M. Beanan and Ruth Olson of the UB Department of
Medicine, the Department of Microbiology and Immunology and UB's
Witebsky Center for Microbial Pathogenesis.
Journal Reference:
- T. C. Umland, L. W. Schultz, U. MacDonald, J. M. Beanan, R. Olson, T. A. Russo. In Vivo-Validated Essential Genes Identified in Acinetobacter baumannii by Using Human Ascites Overlap Poorly with Essential Genes Detected on Laboratory Media. mBio, 2012; 3 (4): e00113-12 DOI: 10.1128/mBio.00113-12
Courtesy: ScienceDaily
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