New Study Confirms Presence of Dangerous Bacteria in Florida’s Coastal Waters Following Hurricane Ian

Caption: Hurricane Ian is pictured from the International Space Station as it orbited 258 miles above the Caribbean Sea on September 26, 2022. At the time of this photograph, Ian was just south of Cuba gaining strength and heading toward Florida.

When Hurricane Ian struck southwest Florida in September 2022, it unleashed a variety of Vibrio bacteria that can cause illness and death in humans, according to a new study published in the journal mBio.

Using a combination of genome sequencing and satellite and environmental data, a team of researchers from the University of Maryland, the University of Florida and microbiome company EzBiome detected several pathogenic Vibrio species in water and oyster samples from Florida’s Lee County, a coastal region that was devastated by Hurricane Ian. The samples, which were collected in October 2022, revealed the presence of two particularly concerning species: Vibrio parahaemolyticus and Vibrio vulnificus.

“We were very surprised to be able to detect—without any difficulty—the presence of these pathogens,” said the study’s senior author Rita Colwell, a Distinguished University Professor in the University of Maryland Institute for Advanced Computer Studies (UMIACS) who has studied Vibrio for the last 50 years.

The study’s findings correspond with a reported increase in V. vulnificus cases in the state of Florida in October 2022. According to the Florida Department of Health, Lee County—which had the highest caseload in the state—reported 38 infections and 11 deaths linked to vibriosis.

Vibrio bacteria naturally occur in the ocean, where they live symbiotically with crustaceans, zooplankton and bivalves. When the bacteria encounter humans, some species can cause an infection known as vibriosis, but the side effects depend on the type of Vibrio and severity of the infection. V. parahaemolyticus can cause gastroenteritis and wound infections, while the V. vulnificus species can cause necrotizing fasciitis—a flesh-eating infection—and kills 1 in 5 infected people.

People can contract vibriosis by eating raw or undercooked seafood or by getting seawater in an open wound. Because Vibrio thrive in warm saltwater, hurricanes and floods can increase the chances of a person becoming exposed.

Several conditions during and after Hurricane Ian favored the growth of Vibrio bacteria, including the amount of rainfall, changes in sea surface temperature and concentrations of chlorophyll in the ocean, which can indicate densities of phytoplankton—and subsequently zooplankton—in an area. In places with plankton blooms, the researchers found an abundance of Vibrio bacteria.

With warming oceans expected to fuel wetter and more powerful storms like Ian, coastal communities could see more Vibrio infections in the future.

“These Vibrios generally grow well between 15 and 40 degrees Celsius [59–104 degrees Fahrenheit], so as the temperature warms, their generation time shortens and they divide faster and faster,” Colwell said. “The warming of seawater—which mixes with freshwater, creating optimal salinities—really enhances the growth of Vibrios, so it’s a very serious concern.”

While the environmental conditions in Florida following Hurricane Ian were ripe for vibriosis, these cases are not limited to southern climes. In August 2023, three people in New York and Connecticut died from V. vulnificus infections.

Colwell and her co-authors—which included Kyle Brumfield (Ph.D. ’23, marine estuarine environmental sciences) and UMD Cell Biology and Molecular Genetics Research Professor Anwar Huq—predicted this recent spike in vibriosis cases based on trending environmental conditions in the Northeast United States. As ocean temperatures continue to rise, Colwell said the rapidly warming Chesapeake Bay could also be affected.

“The waters are much warmer in Florida right now than they are in the Chesapeake Bay, but on a lot of the East Coast, the waters are warming,” Colwell said. “This is a threatening indication that we may be seeing more Vibrio vulnificus infections.

Colwell and her co-authors noted that while they analyzed only a limited number of samples, their findings illustrate the potential of genetic analysis, environmental data and remote sensing to improve public health by proactively detecting and characterizing Vibrio pathogens.

They also called for further investigation to quantify the prevalence of Vibrio bacteria in different locations, seasons and environmental conditions. Colwell said this research is not only vital to public health but also an important step in understanding our changing climate.

“On the positive side, knowing that these infections are associated with the increased variability of a changing climate, perhaps now is the time to develop mechanisms to understand and mitigate it,” Colwell said. “Climate change and flooding are clearly linked to infectious disease, and we need to take it seriously.”

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The paper “Genomic Diversity of Vibrio spp. and Metagenomic Analysis of Pathogens in Florida Gulf Coastal Waters Following Hurricane Ian” was published in mBio on October 16, 2023.

—Story by Emily Nunez, College of Computer, Mathematical, and Natural Sciences communications team