Echinocandin tolerance and persistence in vitro are regulated by calcineurin signaling in Candida glabrata

Upon exposure to echinocandins, growing yeast cells begin to accumulate cell wall damage and eventually die, resulting in therapeutic effects. While resistance to echinocandins is well studied, tolerance and persistence mechanisms that may also contribute to clinical failures and relapses remain understudied. In time-kill assays with micafungin in vitro , the opportunistic pathogen Candida glabrata exhibited biphasic kinetics of cell death. Modeling with exponential decay equations distinguished a fast-dying major population from a slow-dying minor population, indicative of persistence. A genome-wide forward-genetic screen revealed dozens of genes that appeared to regulate persistence and/or tolerance, but not resistance. Several of those genes encoded calcineurin and its upstream regulators. Using individual gene knockout mutants and FK506, we show that calcineurin signaling increases the lifespans of most C. glabrata cells through a process that is largely independent of Crz1, one of its downstream effectors. The formation of long-lived persister-like cells (i.e. persistence) was strongly dependent on calcineurin signaling, independent of Crz1. Pre-activation of calcineurin using genetic or chemical stressors, such as manogepix, strongly increased tolerance and persistence in C. glabrata , suggesting antagonism of echinocandin efficacy by this new antifungal. Calcineurin signaling was also necessary for induction of tolerance and persistence in Candida albicans . The findings suggest that short-term administration of FK506 during the earliest stages of echinocandin treatment may improve clinical outcomes while possibly avoiding long-term immunosuppression.