Single Bacterial Super-Clone Behind World Epidemic of Drug-Resistant E. Coli
Virulent, drug-resistant forms of E. coli that have recently spread around the world emerged from a single strain of the bacteria - not many different strains, as has been widely supposed. The strain causes millions of urinary, kidney and bloodstream infections a year. It could have a far greater clinical and economic impact than any other strain of bacteria, including the so-called MRSA superbug.
The research on drug-resistant E.coli was conducted by an international collaborative research team that included Dr. Evgeni V. Sokurenko, University of Washington professor of microbiology, as well as researchers at Group Health Clinical Laboratory, and their Research Institute, in Seattle and researchers in Germany and Denmark.
Unlike previously identified superbugs that are usually from multiple strains, these E. coli bacteria belong to just one closely related clone.
"We now know that we are dealing with a single enemy, and that by focusing on this super-clone we can have a substantial impact on this worldwide epidemic," Sokurenko said.
More recently, theses pathogens also acquired genes for extended-spectrum beta-lactamase.
This change rendered a broad spectrum of antibiotics, including highly-potent penicillin derivatives and cephalosporins, ineffective against these strains of bacteria. As a result, the infections are increasingly difficult to treat.
These various resistant strains were assumed to have emerged independently around the world in response to their exposure to antibiotics. But this was proven to be incorrect by the laboratories of Sokurenko and two other lead investigators on the study: Lance Price and James R. Johnson.
In the new study, researchers sequenced the genomes of scores of ST131 bacterial samples collected from patients and animals around the world. Then, using a technique called whole-genome-sequence-based phylogenomic analysis, the researchers constructed a family tree that revealed the bacteria's evolutionary history. That analysis indicated that almost all ST131 strains responsible for the notoriously resistant infections are very closely related to each other. They arise from a single clone that is termed H30-Rx for its resistance to treatment.
"Astoundingly, we found that all of the resistance could be traced back to a single ancestor," said Price "This superbug then took off, and now causes lots of drug-resistant infections."
In addition, the H30-Rx strain is fast-growing and can spread from person to person. It infects both the healthy and infirm, young and old, and is adept at invading the bloodstream, said Sokurenko.
"In some hospitals it is responsible for up to half of E. coli infections. It is the most common single strain causing sepsis, a deadly form of blood infection that kills 20 percent to 40 percent of patients who develop it," he said. "Due to its wide-spread resistance and virulence, the social and economic impact of H30-Rx clone could exceed that of any other bacterial strain known."
According to James Johnson, the study's findings may make it possible to develop "better tools to identify, stop or prevent its spread by finding better ways to block the transmission of the superbug, or by finding a
diagnostic test that would help doctors identify such an infection early on, before it might have the chance to turn lethal."
In addition to the United States team, researchers from the Universitatsklinikum Munster in Muenster, Germany and the Statens Serum Institute in Copenhagen, Denmark participated in the study.
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