1 Department of Medicine, Infectious Diseases Section, Baylor College of Medicine, Houston, TX, USA; 2 Department of Molecular Virology and Microbiology, Baylor College of Medicine, Houston, TX, USA; 3 Department of Physical Medicine and Rehabilitation, Baylor College of Medicine, Houston, TX, USA; 4 Center for Prostheses Infection, Baylor College of Medicine, Houstor, TX, USA; 5 Michael E. DeBakey Veterans Affairs Medical Center, Houston, TX, USA
Received 16 March 2005; returned 19 May 2005; revised 27 May 2005; accepted 2 June 2005
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Abstract |
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Methods: Segments of urinary catheter were inoculated with colicin-producing E. coli K-12 and then exposed to either colicin-susceptible E. coli (a uropathogenic clinical isolate) or colicin-resistant E. coli (derived from the susceptible clinical isolate). Catheters were then incubated overnight, rinsed and sonicated.
Results: The presence of colicin-producing E. coli K-12 on the catheter surface completely prevented catheter colonization by colicin-susceptible E. coli but not by resistant E. coli. The colicin-susceptible strain but not the colicin-resistant strain also disappeared from broth cultures in the presence of colicin-producing E. coli K-12.
Conclusions: The observed inhibition of catheter colonization by the uropathogenic clinical isolate of E. coli can be attributed to the presence of a colicin-producing strain of E. coli on the catheter surface. Bacteriocin production by a non-pathogenic organism may have clinical applicability as a means to prevent catheter-associated urinary tract infection.
Keywords: bacteriocins , UTIs , uropathogens
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Introduction |
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The lack of effective strategies to prevent catheter-associated urinary tract infection has led to interest in novel approaches. Bacteriocins are highly specific, natural antibiotics produced by bacteria and are toxic only to bacteria closely related to the producing strain.4 Bacteriocins produced by Escherichia coli are termed colicins and are encoded in stable plasmids. Colicin proteins have three domains: a translocation domain (which moves the protein into the target cell), a receptor binding domain (which binds specific receptors on the target cell) and a killing domain (methods include pore-formation and nuclease activity). When initially synthesized by the producing cell, the killing domain is bound to an immunity protein that acts as a safety cap until removed. Killing specificities are determined by the receptor-binding domain.5 Since E. coli is one of the most common urinary tract pathogens, we investigated in vitro whether we could use a colicin-expressing strain of E. coli to prevent urinary catheter colonization by a colicin-susceptible strain of E. coli. We chose to work with colicin E2, in which the killing protein is a DNA endonuclease.6
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Materials and methods |
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Four bacterial strains were used in these experiments: E. coli K-12 producing colicin E2 (K-12 Col+), E. coli K-12 that does not make colicins (K-12 Col), a pathogenic clinical isolate of E. coli susceptible to colicin E2 (ColS) and a spontaneous mutant of ColS that was resistant to colicin E2 (ColR).7 The K-12 strains (from R. A. Hull's collection) were lactose-negative, while the ColS and ColR strains were lactose-positive.
Colicin production by the K-12 Col+ strain was verified by stab plate experiments.7 Briefly, an agar plate was stabbed with a colony of E. coli K-12 Col+, incubated overnight at 37°C, exposed to chloroform to kill the K-12 Col+ bacteria, overlain with 108 cfu/mL of the test strain in soft agar (either ColS or ColR), then incubated again overnight.
Experimental protocol
Step 1. Trypticase soy broth (TSB; Becton Dickinson, Sparks, MD, USA) that contained two pieces of urinary catheter (Bardex, Lubricath Covington, GA, USA) was inoculated with 105 cfu/mL K-12 Col+ and then incubated overnight under static conditions at 37°C.
Step 2. One catheter piece was transferred to a tube containing ColS 105 cfu/mL in TSB for 30 min. The other catheter piece was transferred to a tube containing ColR 105 cfu/mL in TSB for 30 min.
Step 3. Both catheter pieces were transferred to separate 50 mL tubes of sterile TSB, and a broth sample from each tube was diluted and spread onto MacConkey agar (BBL, Cockeysville, MD, USA), which permitted ready discrimination of strains by colour. Tubes were incubated overnight under static conditions at 37°C.
Step 4. Catheters were removed from the tubes, rinsed in three separate baths of 50 mL of phosphate-buffered saline (PBS) and then flushed with PBS. Three 1 cm segments were cut from each catheter. Each 1 cm segment was placed in 1 mL of PBS with 0.01% SDS and sonicated at 55 000 Hz for 10 min in a water bath sonicator (Buehler Scientific, Evanston, IL, USA) at room temperature.8 The sonication fluid was diluted and spread onto MacConkey agar. Broth from each tube in Step 4 was also diluted and spread onto MacConkey agar in order to evaluate the growth of the strains in mixed cultures. The experiment was repeated four times as above.
In two additional experiments, six catheters were used in Step 1. Two were exposed to K-12 Col+ (as before), two were exposed to K-12 Col, and two were kept in sterile broth in Step 1. The purpose of incorporating the K-12 Col-coated catheters and the uncoated catheters was to differentiate the effect of a pre-existing biofilm of E. coli K-12 from the effect of colicins produced by the E. coli K-12 on subsequent catheter colonization. Steps 24 were the same as in the preceding experiments. In all experiments, the median value of the three 1 cm catheter segments was used as the cfu/cm for that catheter.
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Results |
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A clear zone >10 mm in diameter appeared in the lawn of ColS around the stab of K-12 Col+. No zone appeared in ColS around K-12 Col, and ColR did not form zones around either K-12 Col+ or K-12 Col. These findings suggest that ColS was killed or inhibited by cell-free colicin which had diffused into the agar.
Catheter results
In all six trials, the presence of colicin-producing E. coli on the catheter surface completely blocked catheter colonization by the colicin-susceptible E. coli; no susceptible E. coli was recovered from any catheter pre-coated with K-12 Col+ in six experiments (Figure 1). Colicin-resistant E. coli was able to colonize urinary catheters pre-coated with K-12 Col+; the median of ColR recovered from such catheters was 1900 cfu/cm (range 53011 000 cfu/cm). This difference between ColS and ColR recovered from catheters pre-coated with colicin-producing E. coli K-12 was statistically significant (P = 0.009, Wilcoxon Rank Sum test, SAS® software version 8e). When the pre-coating strain did not produce colicin, or when no pre-coating strain was applied, catheter colonization by the colicin-susceptible and -resistant strains was similar (Figure 1). These results indicate that the inhibition of colicin-susceptible E. coli in the presence of K-12 Col+ was caused by the production of colicin.
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In Step 3, catheters coated with K-12 Col+ that had been exposed to either ColS or ColR were transferred to sterile broth. Immediately after transfer, 205 cfu/mL of ColS and 440 cfu/mL of ColR (median values) were present in the broth (P = 0.10 for ColS compared with ColR, Wilcoxon Rank Sum test). After overnight incubation in the presence of K-12 Col+, 0 cfu/mL of ColS and 6 x 107 cfu/mL of ColR (median values) were recovered from the broth (P = 0.009, Wilcoxon Rank Sum test). These results represent six repetitions of the experiment.
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Conclusions |
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A second limitation is that we used broth rather than urine as the growth medium. We chose broth for these experiments because the composition of human urine is more variable than broth, and artificial urine does not fully replicate the composition of human urine.
Currently the only bacteriocin in practical use is nisin, a Gram-positive bacteriocin with a broad killing range. Nisin is widely used in the food industry as a preservative.4 However, under controlled research conditions, colicins effectively cleared E. coli from the urine of rats,9 and colicins inhibited the growth of two strains of E. coli that cause swine diarrhoea.10 Our goal is to create a non-pathogenic strain of E. coli that simultaneously expresses bacteriocins active against a variety of uropathogens. We are currently investigating the use of urinary catheters coated with non-pathogenic E. coli to colonize the bladders of persons with spinal cord injury who suffer from recurrent urinary tract infections. Modifying our non-pathogenic strain to produce a spectrum of bacteriocins would have potential clinical applicability.
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Acknowledgements |
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References |
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2. Denstedt JD, Wollin TA, Reid G. Biomaterials used in urology: current issues of biocompatibility, infection, and encrustation. J Endourol 1998; 12: 493500.[ISI][Medline]
3. Nicolle LE. The chronic indwelling catheter and urinary infection in long-term-care facility residents. Infect Control Hosp Epidemiol 2001; 22: 31621.[ISI][Medline]
4. Riley MA, Wertz JE. Bacteriocins: evolution, ecology, and application. Annu Rev Microbiol 2002; 56: 11737.[CrossRef][ISI][Medline]
5.
Kageyama M, Kobayashi M, Sano Y et al. Construction and characterization of pyocin-colicin chimeric proteins. J Bacteriol 1996; 178: 103110.
6.
Schaller K, Nomura M. Colicin E2 is a DNA endonuclease. Proc Natl Acad Sci 1976; 73: 398993.
7. Fredericq P. Colicins. Ann Rev Microbiol 1957; 11: 722.[CrossRef][ISI][Medline]
8. Sherertz RJ, Raad II, Belani A et al. Three-year experience with sonicated vascular catheter cultures in a clinical microbiology laboratory. J Clin Microbiol 1990; 28: 7682.[ISI][Medline]
9. Braude AI, Siemienski JS. The influence of bacteriocins on resistance to infection by gram-negative bacteria. II. Colicin action, transfer of colicinogeny, and transfer of antibiotic resistance in urinary infections. J Clin Invest 1968; 47: 176373.[ISI][Medline]
10.
Stahl CH, Callaway TR, Lincoln LM et al. Inhibitory activity of colicins against Escherichia coli strains responsible for postweaning diarrhea and edema disease in swine. Antimicrob Agents Chemother 2004; 48: 311921.
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