Abstract
Candida albicans filamentation, the ability to convert from oval yeast cells to elongated hyphal cells, is a key factor in its pathogenesis. Previous work has shown that the integral membrane protein Dfi1 is required for filamentation in cells grown in contact with a semi-solid surface. Investigations into the downstream targets of the Dfi1 pathway revealed potential links to two transcription factors – Sef1 and Czf1. Sef1 regulates iron uptake and iron utilization genes in low iron conditions, leading us to hypothesize that there exists a link between iron availability and contact-dependent invasive filamentation. Here, we showed that Sef1 was not required for contact dependent filamentation, but it was required for WT expression levels of a number of genes during growth in contact conditions. Czf1 is required for contact-dependent filamentation and for WT levels of expression of several genes. Constitutive expression and activation of either Sef1 or Czf1 individually in a dfi1 null strain resulted in a complete rescue of the dfi1 null filamentation defect. Because Sef1 is normally activated in low-iron environments, we embedded WT and dfi1 null cells in iron-free agar medium supplemented with various concentrations of Ferrous Ammonium Sulfate (FAS). dfi1 null cells embedded in media with a low concentration of iron (20uM FAS) showed increased filamentation in comparison to mutant cells embedded in higher concentrations of iron (50-500uM). WT cells produced filamentous colonies in all concentrations. Together, this data indicates that Dfi1, Czf1, Sef1, and environmental iron regulate C. albicans contact-dependent filamentation.
Importance Candida albicans is an opportunistic pathogen responsible for a larger proportion of candidiasis and candidemia cases than any other Candida species (CDC). The ability of C. albicans cells to invade and cause disease is linked to their ability to filament and form hyphae. Despite this, there are gaps in our knowledge of the environmental cues and intracellular signaling that triggers the switch from commensal organism to filamentous pathogen. Here we identified a link between contact-dependent filamentation and iron availability. Over the course of tissue invasion, C. albicans cells encounter a number of different iron microenvironments, from the iron-rich gut to iron-poor tissues. Increased expression of Sef1-depndent iron uptake genes as a result of contact-dependent signaling will promote the adaptation of C. albicans cells to a low iron availability environment.