Fungal infections are an escalating global health concern, with rare Candida species posing an urgent threat due to emerging multidrug resistance. Clavispora (Candida) lusitaniae is an uncommon pathogen in which multidrug resistance has been documented during antifungal therapy, yet the selective forces driving this phenotype remain unclear. Here, we show that exposure to the echinocandin micafungin (MCF) alone can select for multidrug resistance in C. lusitaniae. Through controlled evolution experiments we identified individual point mutations in genes encoding ergosterol biosynthesis enzymes (ERGs), sterol trafficking proteins (OSH2), and the echinocandin drug target (FKS1) that confer a significant fitness benefit to one or more classes of antifungals. We find that ERG loss-of-function is the primary and independent driver of pan-antifungal resistance to echinocandins, azoles and polyenes. The ERG mutants have <1% ergosterol, increased levels of non-toxic sterol intermediates, and increased chitin content, consistent with both cell membrane and cell wall remodeling that enables the fungal pathogen to evade all three drug classes. The convergence of sterol reprogramming and compensatory cell wall remodeling that occurs during adaptation to echinocandin monotherapy can evolve through a single point mutation and parallels our recent case study of acquired multidrug resistance.
Wash, E., Scott, N. E., Metzner, K., Zhou, X., Dasilva, D., Pereira de Sa, N., Usmani, S. A., Vieira de Sa, N. F., Del Poeta, M., Selmecki, A.
Advertisement
Stats
- Recommendations n/a n/a positive of 0 vote(s)
- Views 0
- Comments 0
