Colorized scanning electron micrograph showing carbapenem-resistant Klebsiella pneumoniae interacting with a human neutrophil.

Colorized scanning electron micrograph showing carbapenem-resistant Klebsiella pneumoniae interacting with a human neutrophil. Photo: NIAID

Russo Study Identifies Likely Culprit That Turns Classical Klebsiella Pneumoniae Into Raging, Drug-Resistant Killer

Release Date: September 18, 2024

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Thomas Russo MD; Professor and Chief, Infectious Disease; Department of Medicine; Jacobs School of Medicine and Biomedical Sciences at the University at Buffalo; 2021.
“Our goal with this study was to decipher how several genetic factors contribute to this hypervirulence in order to guide the development of preventive therapies, treatments, and control strategies for hypervirulent Klebsiella pneumoniae. ”
Professor of medicine and chief of the Division of Infectious Diseases

BUFFALO, N.Y. — More than a decade ago, physicians around the world began reporting cases due to a new hypervirulent strain of Klebsiella pneumoniae, which could infect and severely sicken otherwise healthy people.

Thomas A. Russo, MD, at the University at Buffalo and the VA Western New York Healthcare System (VAWNYHS), was one of them. In 2011, he treated his first case in Buffalo, a young person with no other comorbidities who was hospitalized for months with this hypervirulent bacterium.

The patient fully recovered, but Russo became curious about this hypervirulent bacterium — and alarmed, given the fact that it was able to infect otherwise healthy individuals from the community and, over time, could become drug-resistant.

More Cases Reported and They Are Drug-Resistant

That alarm was well-founded. The hypervirulent bacteria has spread throughout the world. It can cause tissue-invasive infections that are organ- and life-threatening in healthy people. Some strains have acquired resistance to antimicrobial agents; these strains have been dubbed “true and dreaded superbugs.”

Earlier this year, the European Centre for Disease Control and Prevention of the European Union reported a significant increase in the number of cases of hypervirulent Klebsiella pneumoniae and that these cases were resistant to the class of antibiotics called carbapenems, which are often a “last resort” treatment for bacterial infections.

Now, with numerous publications on the bacterium, Russo has identified the genetic elements responsible for turning classical Klebsiella pneumoniae, which generally infects only sick and/or immunocompromised people in the health care setting, into hypervirulent Klebsiella pneumoniae, which can also infect otherwise healthy people in the community.

Published in August in eBioMedicine, the research is the first to determine the relative contribution of several key genetic elements to the hypervirulence of this bacterium.

Deciphering Hypervirulence

“Our goal with this study was to decipher how several genetic factors contribute to this hypervirulence in order to guide the development of preventive therapies, treatments and control strategies for hypervirulent Klebsiella pneumoniae,” says Russo, senior author and SUNY Distinguished Professor of medicine and chief of the Division of Infectious Diseases in the Jacobs School of Medicine and Biomedical Sciences. He sees patients at UBMD Internal Medicine and the VAWNYHS.

To accomplish this, the researchers conducted a systematic investigation of four representative clinical strains of hypervirulent Klebsiella pneumoniae. They did this by constructing and testing mutants in which pVir, the large plasmid possessed by hypervirulent Klebsiella pneumoniae strains, and other virulence factors alone or in combination were removed.

Russo explains that plasmids are genetic elements separate from the chromosome. They contain multiple genes, some of which may enhance virulence and/or confer resistance to selected antimicrobial agents.

“While the plasmid was known to contribute to hypervirulence in Klebsiella pneumoniae, its relative role and the relative role of selected virulence factors encoded on the plasmid or the chromosome were not well-defined,” says Russo.

The findings strongly supported that pVir is the primary genetic determinant that transforms the baseline virulence potential of classical K. pneumoniae strains to that observed for hypervirulent Klebsiella pneumoniae strains. Data also supports the existence of additional virulence factors encoded by pVir that have yet to be identified.

“The genetic factors defined as being the most quantitively important could be potential therapeutic targets for the development of counter measures,” says Russo.

Previous work published by his group in mBio found that a strain is likely to be hypervirulent if it contains five specific genes located on the plasmid. That work may be critical to developing a diagnostic test for hypervirulent Klebsiella pneumoniae. Presently, clinical microbiology laboratories are unable to differentiate classical from hypervirulent Klebsiella pneumoniae.

Co-authors with Russo are Ulrike Carlino-MacDonald, Connor J. Davies and Cassandra L. Alvarado, all of whom are with the VA and the Department of Medicine in the Jacobs School; Zachary J. Drayer of the Department of Medicine; Alan Hutson of Roswell Park Comprehensive Cancer Center; and Ting L. Luo, Melissa J. Martin, Patrick T. McGann and Francois Lebreton, all of the Multidrug-Resistant Organism Repository and Surveillance Network, Walter Reed Army Institute of Research. Russo is also with the Witebsky Center for Microbial Pathogenesis in the Jacobs School.

This work was supported by the National Institutes of Health and the Department of Veterans Affairs, and was partially funded by the U.S. Defense Health Program.

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Ellen Goldbaum
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goldbaum@buffalo.edu