Forward genetic screen in zebrafish identifies new fungal regulators that limit host-protective Candida-innate immune interaction.

Candida is one of the most frequent causes of bloodstream infections, and our first line of defense against these invasive infections is the innate immune system. The early immune response is critical in controlling Candida albicans infection, but C. albicans has several strategies to evade host immune attack. Phagocytosis of C. albicans blocks hyphal growth, limiting host damage and virulence, but how C. albicans limits early recruitment and phagocytosis in vertebrate infection is poorly understood. To study innate immune evasion by intravital imaging, we utilized the transparent larval zebrafish infection model to screen 131 C. albicans mutants for altered virulence and phagocyte response. Infections with each of the seven hypovirulent mutants led to altered phagocyte recruitment and/or phagocytosis, falling into four categories. Of particular interest among these is NMD5, a predicted β-importin and newly identified virulence factor. The nmd5∆/∆ mutant fails to limit phagocytosis, and its virulence defects are eliminated when phagocyte activity is compromised, suggesting that its role in virulence is limited to immune evasion. These quantitative intravital imaging experiments are the first to document altered Candida-phagocyte interactions for several additional mutants and clearly distinguish recruitment from phagocytic uptake, suggesting that Candida modulates both events. This initial large-scale screen of individual C. albicans mutants in a vertebrate, coupled with high-resolution imaging of Candida-phagocyte interactions, provides a more nuanced view of how diverse mutations can lead to more effective phagocytosis, a key immune process that blocks germination and drives anti-fungal immunity. IMPORTANCE: Candida albicans is part of the human microbial community and is a dangerous opportunistic pathogen, able to prevent its elimination by the host immune system. Although Candida avoids immune attack through several strategies, we still understand little about how it regulates when immune phagocytes get recruited to the infection site and when they engulf fungal cells. We tested over 130 selected Candida mutants for their ability to cause lethal infection and found several hypovirulent mutants, which provoked altered innate immune responses, resulting in lower overall inflammation and greater host survival. Of particular interest is NMD5, which acts to limit fungal phagocytosis and is predicted to regulate the activity of stress-associated transcription factors. Our high-content screening was enabled by modeling Candida infection in transparent vertebrate zebrafish larva. Our findings help us understand how Candida survives immune attack during commensal and pathogenic growth, and may eventually inform new strategies for controlling disease.