Microbiological analysis of hemodialysis tunneled cuffed catheter tips

Abstract:

Catheter-related bloodstream infections create a significant challenge in healthcare system, often complicated by antibiotic resistance and biofilm formation of multi-drug resistance and virulent bacterial pathogens. This study focused on biofilm-forming efficiency, and underlying genetic mechanisms in Micrococcus luteus HL_Chru_C3, isolated from a hemodialysis catheter tip. The isolate exhibited resistance to multiple antibiotic classes, including beta-lactams and glycopeptides. Biofilm assays revealed that M. luteus HL_Chru_C3 formed optimum biofilms at high concentration of carbohydrates (500 mM), and pH 5 but there was no significant role of mineral salts. Whole-genome sequencing and bioinformatic analysis using CARD, KAAS, and KEGG databases identified genes associated with antibiotic resistance (ftsI, pbp1a/2, vanY, alr, ddl, murF, mraY, and murG), quorum sensing (genes from the opp family, sec, cylA, ccfA, phnA, phnB, phzC, rpfB, clp, and toxE), and biofilm formation (phnA, phnB, cyaB, vfr, vps, glgC, wecB, wecC, and cysE). The predicted mechanisms of action for these genes, based on homology to other organisms, suggest complex interactions contributing to the observed phenotypes. This study provides an insight into the genetic basis of antibiotic resistance and biofilm formation in M. luteus HL_Chru_C3 isolated from a hemodialysis catheter, highlighting the need for effective infection control strategies to combat CRBSIs.

Adhikary R, Sarkar I, Patel D, Gang S, Nath UK, Hazra S. Deciphering antibiotic resistance, quorum sensing, and biofilm forming genes of Micrococcus luteus from hemodialysis tunneled cuffed catheter tips of renal failure patients. Arch Microbiol. 2025 Apr 5;207(5):114. doi: 10.1007/s00203-025-04310-6. PMID: 40186781.