Bacteria’s Shapeshifting Behavior is a Clue to New Treatments for UTIs

UPEC filaments expressing Green Fluorecent Protein (GFP) after exfoliation from bladder cells, captured using epi fluorescence microscopy. Courtesy of Australian Institute for Microbiology and Infection, University of Technology Sydney

Urinary tract infections (UTIs) are both very common and potentially very dangerous. More than half of all Australian women will suffer from a UTI in their lifetime, and nearly 1 in 3 women will have an infection requiring treatment with antibiotics before the age of 24.

Around 80 percent of UTIs are caused by uropathogenic E. coli (UPEC), which is increasingly resistant to antibiotics. E. coli-related death due to antimicrobial resistance is the leading cause of bacterial fatalities worldwide.

In a bid to aid discovery of new treatment options, researchers at the University of Technology Sydney (UTS) are using state-of-the-art microscopy to pinpoint how these bacteria spread and multiply.

Dr. Bill Söderström and associate professor Iain Duggin, of the Australian Institute for Microbiology and Infection at UTS, said their latest research examined the shapeshifting behavior of UPEC. During a UTI infection cycle, the bacteria form spaghetti-like filaments hundreds of times their normal lengths before reverting to their original form.

The study, which is published in Nature Communications, used a human bladder cell infection model to generate the filaments, and look at their reversal back to rod shape.

“While we don’t fully understand why they do this extreme lifestyle make-over, we know they must revert to their original size before they can re-infect new bladder cells,” Söderström said.

“We used advanced microscopy to follow two key cell division proteins and their localization dynamics during reversal. We found that the normal rules for regulation of cell division in bacteria does not fully apply in filaments,” Söderström said. “By giving the first clues into how the reversal of filamentation is regulated during infection, we may be laying the foundation for identifying new ways to combat UTIs.”

Duggin said the long filaments formed by the bacteria appeared to break open the infected human cells, through a previously unknown mechanism called infection-related filamentation (IRF).

“The devastating eruption of these bacteria from the cells of the bladder that they invade probably contributes to the extensive damage and pain experienced during a UTI,” Duggin said. “Our goal is to identify why and how the bacteria do this remarkable feat in the hope of enabling alternative treatments or preventions.”