Vaginal bacterium triggers recurrent E. coli infection in the mouse bladder

March 30, 2017

In mice, exposure of the bladder to a common vaginal bacterium awakened dormant Escherichia coli and triggered recurrent urinary tract infections (UTIs). Published in PLOS Pathogens, these findings could help improve understanding of recurrent UTIs in women.

Millions of women around the world experience recurrent bladder infections. Many recurrent UTIs are thought to occur when dormant E. coli present in the lining of the bladder are reactivated, causing a new infection. However, potential triggers of this reactivation have remained unclear.

Nicole Gilbert , Valerie O'Brien, and Amanda Lewis of Washington University School of Medicine, St. Louis considered the idea that certain vaginal bacteria, which are mechanically transferred to the urinary tract during sexual activity, may damage bladder tissue and lead to reactivation of E. coli infection.

To test this hypothesis, Lewis's team raised mice with dormant E. coli reservoirs in their bladders and exposed their urinary tracts to two vaginal bacteria species commonly found in women. Lactobacillus crispatus, found in high proportions in the healthy vagina, had no effects. However, Gardnerella vaginalis, which can cause problems in the reproductive tract when it grows excessively, damaged the cells lining the bladder and activated the dormant E. coli, which emerged to cause a new infection.

Mice exposed to G. vaginalis, which was eliminated rapidly from the bladder, were also more likely to experience life-threatening consequences of the recurrent E. coli UTI, including severe kidney damage and systemic infection. The effects of G. vaginalis persisted after the bacterium was no longer present in the urinary tract.

These results indicate the first plausible trigger of recurrent UTIs from dormant E. coli in the bladder. They could also help explain previously found links between vaginal bacteria species, sexual activity, and risk of recurrent UTIs in women.

Recurrent UTIs are usually treated with antibiotics to kill the E. coli. If occasional exposure to G. vaginalis does, indeed, cause recurrent infection in some women, then it could serve as a potential new target of treatments to prevent recurrent UTIs. In light of the rise of multi-drug resistant E. coli, such a strategy could prove especially appealing.

"One of the important findings of this study is that Gardnerella can cause damage to organs of the urinary tract even in the absence of E. coli.," explains Dr. Lewis. "This has exciting implications, suggesting that Gardnerella exposures to the bladder could be important for urologic diseases beyond recurrent UTI that we don't fully understand."
In your coverage please use this URL to provide access to the freely available article in PLOS Pathogens:

Citation: Gilbert NM, O'Brien VP, Lewis AL (2017) Transient microbiota exposures activate dormant Escherichia coli infection in the bladder and drive severe outcomes of recurrent disease. PLoS Pathog 13(3): e1006238. doi:10.1371/journal.ppat.1006238

Funding: This work was supported by the Center for Women's Infectious Disease Research at Washington University School of Medicine (Pilot Research Award to NMG), by the American Heart Association: #12POST12050583 (NMG) and #14POST20020011 (NMG), by the National Science Foundation (Graduate Research Fellowship to VPO#DGE - 1143954), and by the National Institutes of Health, NIAID: R01 AI114635 (ALL) and NIDDK: R21 DK092586 (ALL) and P50 DK064540-11 (SJH, project II PI:ALL). Some of the animal studies were performed in a facility supported by NCRR grant C06 RR015502. Initial SEM studies were performed by the Research Center for Auditory and Vestibular Studies, supported by the NIH NIDCD Grant. Additional SEM was performed at the Washington University Center for Cellular Imaging (WUCCI) supported by Washington University School of Medicine, The Children's Discovery Institute of Washington University and St. Louis Children's Hospital, the Foundation for Barnes-Jewish Hospital and the National Institute for Neurological Disorders and Stroke (NS086741). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing Interests: The authors have declared that no competing interests exist


Related Bacterium Articles from Brightsurf:

Root bacterium to fight Alzheimer's
A bacterium found among the soil close to roots of ginseng plants could provide a new approach for the treatment of Alzheimer's.

Tuberculosis bacterium uses sluice to import vitamins
A transport protein that is used by the human pathogen Mycobacterium tuberculosis to import vitamin B12 turns out to be very different from other transport proteins.

Bacterium makes complex loops
A scientific team from the Biosciences and Biotechnology Institute of Aix-Marseille in Saint-Paul lez Durance, in collaboration with researchers from the Max Planck Institute of Colloids and Interfaces in Potsdam and the University of Göttingen, determined the trajectory and swimming speed of the magnetotactic bacterium Magnetococcus marinus, known to move rapidly.

Researchers show how opportunistic bacterium defeats competitors
The researchers discovered that Stenotrophomonas maltophilia uses a secretion system that produces a cocktail of toxins and injects them into other microorganisms with which it competes for space and food.

Genetic typing of a bacterium with biotechnological potential
Researchers at Kanazawa University describe in Scientific Reports the genetic typing of the bacterium Pseudomonas putida.

How the strep bacterium hides from the immune system
A bacterial pathogen that causes strep throat and other illnesses cloaks itself in fragments of red blood cells to evade detection by the host immune system, according to a study publishing December 3 in the journal Cell Reports.

The cholera bacterium can steal up to 150 genes in one go
EPFL scientists have discovered that predatory bacteria like the cholera pathogen can steal up to 150 genes in one go from their neighbors.

Exploiting green tides thanks to a marine bacterium
Ulvan is the principal component of Ulva or 'sea lettuce' which causes algal blooms (green tides).

The cholera bacterium's 3-in-1 toolkit for life in the ocean
The cholera bacterium uses a grappling hook-like appendage to take up DNA, bind to nutritious surfaces and recognize 'family' members, EPFL scientists have found.

Excellent catering: How a bacterium feeds an entire flatworm
In the sandy bottom of warm coastal waters lives Paracatenula -- a small worm that has neither mouth, nor gut.

Read More: Bacterium News and Bacterium Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to