Inhibiting host-protein deposition on urinary catheters reduces associated urinary tract infections.
Marissa Jeme AndersenChunKi FongAlyssa Ann La BellaJonathan Jesus MolinaAlex MolesanMatthew M ChampionCaitlin HowellAna Lidia Flores-MirelesPublished in: eLife (2022)
Microbial adhesion to medical devices is common for hospital-acquired infections, particularly for urinary catheters. If not properly treated these infections cause complications and exacerbate antimicrobial resistance. Catheter use elicits bladder inflammation, releasing host serum proteins, including fibrinogen (Fg), into the bladder, which deposit on the urinary catheter. Enterococcus faecalis uses Fg as a scaffold to bind and persist in the bladder despite antibiotic treatments. Inhibition of Fg-pathogen interaction significantly reduces infection. Here, we show deposited Fg is advantageous for uropathogens E. faecalis , Escherichia coli , Pseudomonas aeruginosa , K. pneumoniae , A. baumannii , and C. albicans , suggesting that targeting catheter protein deposition may reduce colonization creating an effective intervention for catheter-associated urinary tract infections (CAUTIs). In a mouse model of CAUTI, host-protein deposition was reduced, using liquid-infused silicone catheters, resulting in decreased colonization on catheters, in bladders, and dissemination in vivo. Furthermore, proteomics revealed a significant decrease in deposition of host-secreted proteins on liquid-infused catheter surfaces. Our findings suggest targeting microbial-binding scaffolds may be an effective antibiotic-sparing intervention for use against CAUTIs and other medical device infections.
Keyphrases
- urinary tract infection
- antimicrobial resistance
- pseudomonas aeruginosa
- ultrasound guided
- escherichia coli
- spinal cord injury
- biofilm formation
- randomized controlled trial
- mouse model
- protein protein
- microbial community
- binding protein
- candida albicans
- oxidative stress
- mass spectrometry
- ionic liquid
- cancer therapy
- signaling pathway
- tissue engineering
- robot assisted
- small molecule
- acinetobacter baumannii
- electronic health record
- newly diagnosed
- dna binding