For Members
Antibiotics in Swine Feed Encourage Gene Exchange
CONTACT: Jim Sliwa
jsliwa@asmusa.org
WASHINGTON, DC –
November 28, 2011 – A study to be published in the online journal mBio® on November 29 shows that adding
antibiotics to swine feed causes microorganisms in the guts of these animals to
start sharing genes that could spread antibiotic resistance.
Livestock farms use antibiotic drugs regularly, and not just
for curing sick animals. Antimicrobial drugs are used as feed additives to
boost animal growth, a profitable but controversial practice that is now banned
in the European Union and under scrutiny here in the United States. Using
antibiotics in animal feed saves farms money, but opponents argue the practice
encourages antimicrobial resistance among bacteria that could well be consumed
by humans. Today, livestock producers in the U.S. use an estimated 24.6 million
pounds of antimicrobials for nontherapeutic purposes every year. The U.S. Government
Accountability Office recently urged the federal government to follow up on
plans to evaluate the impacts of the use of antibiotics as growth promoters.
The study by Heather Allen and her colleagues at the USDA
National Animal Disease Center (NaDC) in Ames, Iowa, adds to the sum of
knowledge about what happens to the microorganisms that populate animal
digestive tracts when they are exposed to low, persistent levels of antibiotics.
The researchers studied how two in-feed antibiotic formulations affect prophages,
segments of DNA found in bacteria that can encode antibiotic resistance genes
and other genes that bacteria may use.
Prophages can cut themselves out of the larger chromosome of
bacterial DNA in a process called induction, then replicate and package
themselves as viruses. These viruses explode the cell from the inside then move
on to infect other organisms and deliver their genes.
Allen, who is lead author on the study, says when pigs were fed antibiotics, the actual
numbers of antibiotic resistance genes carried by the phages remained steady,
but the microorganisms still reacted to the presence of antibiotics. Prophages
underwent a significant increase in induction when exposed to antibiotics,
indicating that medicating the animals led to increased movement of prophage
genes among gut bacteria.
“Induction of the prophages is showing us that antibiotics
are stimulating gene transfer,” says Allen. “This is significant because phages
have previously been shown to carry bacterial fitness genes such as antibiotic
resistance genes.”
Studies that explore the impacts of in-feed antibiotics most
often focus on the bacterial residents of the gut, according to Allen, but
phages and other viruses move a significant amount of genetic information
around the community. This makes changes in prophage induction an important
collateral effect of antibiotic treatment, she says. Resistance genes are the
unit of currency among microbes experiencing the duress of an antibiotic, so
following the movement of genes is arguably more important than following
certain changes in bacterial communities. And if bacteria in humans acquire
resistance genes from animals, there can be serious health consequences.
“What’s important is the transfer of a gene that could get
into the wrong place at the wrong time,” says Allen. “Increased gene transfer
is a critical event in the evolution of gut bacteria.”
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mBio® is an open
access online journal published by the American Society for Microbiology to
make microbiology research broadly accessible. The focus of the journal is on
rapid publication of cutting-edge research spanning the entire spectrum of
microbiology and related fields. It can be found online at http://www.mbio.asm.org.