Calcineurin controls the cytokinesis machinery during thermal stress in Cryptococcus deneoformans.

Calcineurin is a highly conserved phosphatase that plays a central role in sensing calcium and governing transcriptional, posttranscriptional, and posttranslational signaling networks. Calcineurin is a heterodimer consisting of a catalytic A subunit and a regulatory B subunit. Through downstream effectors, calcineurin signaling drives myriad responses in different organisms. In the fungal pathogenic Cryptococcus species complex that infects humans, calcineurin governs thermotolerance and is essential for growth at high temperature and pathogenesis. In Cryptococcus deneoformans, the underlying molecular functions of this critical signaling cascade are not well understood. In this study, we conducted a genetic screen and identified genetic changes that suppress the requirement for calcineurin during high-temperature growth. Our results identified two mechanisms that bypass the requirement for calcineurin function. The first mechanism involves segmental aneuploidy via both amplification as well as loss of chromosome fragments. The second mechanism involves dominant amino acid substitution mutations in the genes encoding three proteins, Chs6, Imp2, and Cts1, orthologs of components of the Ingression Progression Complex required for septation and budding in Saccharomyces cerevisiae. Loss of calcineurin activity causes chitin and chitosan accumulation and severe budding defects, whereas suppressor mutations largely restore growth and cytokinesis in the absence of calcineurin. These findings reveal that the calcineurin signaling cascade controls a conserved cytokinesis machinery at the mitotic exit network during thermal stress.

Duke Scholars

Author Joseph Heitman Molecular Genetics and Microbiology

Author Rajendra Upadhya Molecular Genetics and Microbiology

Author Vikas Yadav