Dry surface biofilm formation byCandida aurisfacilitates persistence and tolerance to sodium hypochlorite

ABSTRACT Candida auris is an enigmatic fungal pathogen, recently elevated to the critical priority group of pathogens by the World Health Organization. Of key concern is its ability to cause outbreaks within intensive and chronic care units, facilitated through its environmental persistence. We investigated the susceptibility of phenotypically distinct C. auris isolates to sodium hypochlorite (NaOCl) disinfection, and the subsequent role of biofilms in surviving disinfection using a dry-surface biofilm (DSB) model and transcriptomic profiling. Planktonic cells were tested for susceptibility to NaOCl in suspension, with biofilm formation using the DSB model consisting of consecutive 48 hr cycles with/without media across a 12-day period, assessed using viable counts, biomass assays, and microscopy. Disinfection efficacy was assessed using clinically relevant protocols of 500-1000ppm for 1-5min. RNA-sequencing was performed on untreated DSBs in comparison to planktonic cells. Isolates were found to be sensitive to NaOCl planktonically at concentrations ≤62.5 ppm, and grew robust biofilms using the DSB protocol. Biofilms developed tolerance to all NaOCl treatment parameters, with only 2-4 log 10 -reductions in viable cells observed at highest concentrations. Transcriptomics identified ABC transporters and iron acquisition pathways as strongly upregulated in DSBs relative to planktonic cells. Our novel findings have optimised a DSB protocol in which C. auris biofilms can mediate tolerance to adverse conditions such as NaOCl disinfection, suggesting a lifestyle through which this problematic yeast can environmentally persist and transmit. Mechanistically it has been shown for the first time that upregulation of small-molecule and iron transport pathways are potential facilitators of environmental survival. IMPORTANCE Candida auris is a pathogenic yeast that has been responsible for outbreaks in healthcare facilities across the globe, predominantly affecting vulnerable patients. This organism displays a concerning ability to persist within the healthcare environment that is likely facilitated by attaching onto surfaces and developing protective microbial communities knows as biofilms. These communities allow cells to survive and tolerate disinfection with bleach. In this study, we show that C. auris forms robust biofilms on surfaces which promote survival up to 12 days, even with prolonged drying periods. We also demonstrate that development of these biofilms over time significantly reduces the efficacy of hypochlorite disinfection. By investigating the molecular mechanisms of biofilms, we have shown that these biofilms express efflux pumps, which may actively remove hypochlorite molecules from cells, allowing them to tolerate disinfection, and that uptake of iron from the external environment is also important for survival of these communities.