A Mechanistic and Functional Study of White-opaque Phenotypic Switching in Candida Albicans
Author | : Mathew Gregory Miller |
Publisher | : |
Total Pages | : 730 |
Release | : 2005 |
ISBN-10 | : UCAL:X85608 |
ISBN-13 | : |
Rating | : 4/5 (08 Downloads) |
Download or read book A Mechanistic and Functional Study of White-opaque Phenotypic Switching in Candida Albicans written by Mathew Gregory Miller and published by . This book was released on 2005 with total page 730 pages. Available in PDF, EPUB and Kindle. Book excerpt: Candida albicans is a major fungal pathogen of humans. It is a harmless commensal in healthy individuals, but it can cause serious infections in immune-compromised hosts. C. albicans undergoes a meta-stable and reversible switch between two distinct cell types known as white and opaque. The role of white-opaque switching in the biology of C. albicans was originally not well understood. We discovered an unexpected relationship between white-opaque switching and the sexual cycle of C. albicans . The mating type locus of C. albicans (MTL) encodes transcriptional regulatory proteins that regulate mating. We demonstrated that two MTL -encoded homeodomain proteins, a 1 and alpha2, work together to repress white-opaque switching in C. albicans . The observations that the MTL locus controlled both mating and white-opaque switching led us to hypothesize that opaque cells played a role in mating. Indeed, we found that opaque cells mate one million times more efficiently than do white cells. Additionally, opaque cells, but not white cells, developed specialized mating projections when exposed to mating pheromone. Thus, opaque cells are a specialized mating form of C. albicans . As white cells are generally more robust in a mammalian host than opaque cells, this strategy allows the organism to survive the rigors of life within a mammalian host, while generating a small population of mating-competent cells. The mechanism that controls white-opaque switching is not well understood. To better understand the mechanism, we investigated the regulation of white-opaque switching by a 1-alpha2. We demonstrated that a 1-alpha2 regulates white-opaque switching by destabilizing opaque cells, and we monitored gene expression during the transition from opaque to white using DNA microarrays. We used a candidate approach to identify additional regulators of white-opaque switching among genes enriched for their expression in the opaque phase. We identified two potent positive regulators of white-opaque switching: the opaque-specific transcriptional regulatory proteins Czf1 and Naf1. We also further investigated the role of Efg1, a previously identified regulator of white-opaque switching, and found that efg1/efg1 mutants were unable to bypass a 1-alpha2 repression of switching. Finally, we determined the epistatic and regulatory relationships between Efg1, Czf1 and Naf1.