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| Scientists tested crow feces at Coes Pond in Worcester, Mass., and found antibiotic-resistance genes |
WORCESTER, Mass. – One afternoon
last winter, Julie Ellis unfurled a long, white tarp under a stand of trees
near Coes Pond where hundreds of crows roost. Her mission: to collect as much
bird poop as possible.
Back in the laboratory, Ellis’
colleagues combed through the feces. Testing its bacteria, they discovered
something unusual – genes that make the crows resistant to antibiotics.
Drug-resistant infections are a
fast-growing threat to human health, due largely to overuse of antibiotics in
human medicine and livestock production, according to the Centers for Disease
Control and Prevention. At least 2 million people each year in the United
States alone are sickened by infections resistant to drugs.
Now new research, including the crow
poop study conducted in four states,
provides evidence that antibiotic resistance has spread beyond hospitals and
farms to wildlife.
“We’ve documented human-derived drug resistance where it
shouldn’t be – in wildlife and the environment. But we know very little about
how this may impact public health.” –Julie Ellis, Tufts
University
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| Scientists collected crow feces from a site in Worcester MA |
“We've documented human-derived drug
resistance where it shouldn't be – in wildlife and the environment. But we know
very little about how this may impact public health. There just isn’t that
smoking gun,” said Ellis, a research scientist at Tufts University’s veterinary
school.
In addition to crows, resistance
genes have been detected in gulls, houseflies, moths, foxes,
frogs, sharks and whales,
as well as in sand and coastal water samples from California and Washington.
The spread to wildlife is “an
indicator of the wide-reaching scale of the problem. Microbes connect the
planet,” said Lance Price, a professor of environmental and occupational health
at George Washington University.
“The danger is that we enter a
post-antibiotic era in which even our last-line drugs won’t work and routine
infections become life-threatening,” he said.
While antibiotics have
revolutionized medicine in less than 100 years, antibiotic-producing bacteria
have existed in nature for millions of years. Natural antibiotics likely
evolved as weapons in a biological arms race between competing bacteria.
But the environmental drug
resistance that Ellis and others are now seeing is different – it’s man made.
“What has changed is that we've placed great selective pressure on bacteria with our use of antibiotics,” said
Ludek Zurek, a microbiologist at Kansas State University who participated in
the crow study.
Bacteria can swap genes with one
another, so those that survive can pass along the genetic equipment to
withstand an antibiotic assault to unrelated bacterial strains, spreading
resistance across the globe, microbe by microbe.
“The danger is that we enter a post-antibiotic era in which even
our last-line drugs won’t work and routine infections become life-threatening.”
–Lance Price, George Washington University
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| Antibiotic-resistant infections are common. |
In the crow research, scientists
collected nearly 600 fecal samples in four states – Massachusetts, Kansas, New
York and California.
Fifteen of the crows sampled, about 2.5 percent, harbored genes for resistance to vancomycin, a drug of last resort for hard-to-treat hospital-acquired infections. Crows with the resistance genes were found in all of the states except California.
Fifteen of the crows sampled, about 2.5 percent, harbored genes for resistance to vancomycin, a drug of last resort for hard-to-treat hospital-acquired infections. Crows with the resistance genes were found in all of the states except California.
“The vancomycin resistance gene is
rare [in environmental samples], so the fact that they readily found it in
crows is significant,” said Amy Pruden, an environmental engineer at Virginia
Tech who studies antibiotic resistance genes as emerging contaminants in water
bodies.
What’s alarming, say the
researchers, is that some of the vancomycin-resistant bacteria in the crows
were resistant to several other antibiotics widely used in human medicine and
livestock feed.
It’s very difficult to trace the
resistance back to a source.
“Because birds are so mobile, it’s
possible they may acquire resistance genes from multiple sources in their
travels,” said Ellis. “Maybe they visit a dumpster or sewage treatment plant
one day and later a farmer’s field.”
The source of antibiotic-resistance
cannot always be determined because many drugs are used both in human and
animal medicine. However, the vancomycin resistance in the wild crows bears the
signature of a human clinical source, the study authors concluded.
They speculate that waste sites may
be a potential source of the crows’ bacteria.
“Traditional wastewater treatment
approaches may not destroy genetic material,” Pruden said.
Much of the research on drug
resistance has focused on hospitals and healthcare settings. The CDC estimates
that 50 percent of all antibiotics prescribed to people are not needed.
More recently, researchers have
begun to turn their attention to the environment as a source of drug
resistance. Many more tons of antibiotics are used in U.S. livestock production
– to prevent and treat disease and to promote growth – than in human medicine.
An estimated 30,000 tons of antibiotics each year are sold for use in
food-producing animals. “People who consume these foods can develop
antibiotic-resistant infections,” according to a CDC report issued in September.
It’s unclear what role, if any,
crows and other wild animals may play in hastening the spread of these
infections or creating new ones.
“Wildlife may be an important piece
of the puzzle,” Pruden said. “It’s certainly an area that warrants more
research.”
