ABSTRACT
Candida auris causes life-threatening, drug-resistant infections. In addition to drug resistance, therapeutic innovation is hindered by our limited knowledge of the mechanisms used by C. auris to evade immunity and establish infection. Here we show that C. auris escapes phagocytic containment and kills macrophages, and demonstrate that the mechanisms rely on metabolic regulation. We found that C. auris-infected macrophages undergo immunometabolic reprogramming and increase glycolysis but this does not lead to the expected antimicrobial responses, as macrophages fail to activate IL-1β cytokine and curb C. auris growth. Further analysis showed that C. auris relies on its own metabolic capacity to egress from macrophages, cause macrophage metabolic stress and cell death, and establish infection in vivo. We identified a transcriptional regulator of C. auris metabolism and macrophage evasion, and further show that, contrary to several other pathogens, C. auris-induced macrophage metabolic dysfunction and death fail to activate the NLRP3 inflammasome. Consequently, inflammasome-dependent antimicrobial responses remain inhibited throughout infection. Our findings establish a pivotal role for metabolic regulation in enabling C. auris to eliminate macrophages while remaining immunologically silent to ensure its own survival.
Competing Interest Statement
The authors have declared no competing interest.
