Activation of the Cph1-dependent MAP kinase signaling pathway induces white-opaque switching in Candida albicans.

Depending on the environmental conditions, the pathogenic yeast Candida albicans can undergo different developmental programs, which are controlled by dedicated transcription factors and upstream signaling pathways. C. albicans strains that are homozygous at the mating type locus can switch from the normal yeast form (white) to an elongated cell type (opaque), which is the mating-competent form of this fungus. Both white and opaque cells use the Ste11-Hst7-Cek1/Cek2 MAP kinase signaling pathway to react to the presence of mating pheromone. However, while opaque cells employ the transcription factor Cph1 to induce the mating response, white cells recruit a different downstream transcription factor, Tec1, to promote the formation of a biofilm that facilitates mating of opaque cells in the population. The switch from the white to the opaque cell form is itself induced by environmental signals that result in the upregulation of the transcription factor Wor1, the master regulator of white-opaque switching. To get insight into the upstream signaling pathways controlling the switch, we expressed all C. albicans protein kinases from a tetracycline-inducible promoter in a switching-competent strain. Screening of this library of strains showed that a hyperactive form of Ste11 lacking its N-terminal domain (Ste11(ΔN467)) efficiently stimulated white cells to switch to the opaque phase, a behavior that did not occur in response to pheromone. Ste11(ΔN467)-induced switching specifically required the downstream MAP kinase Cek1 and its target transcription factor Cph1, but not Cek2 and Tec1, and forced expression of Cph1 also promoted white-opaque switching in a Wor1-dependent manner. Therefore, depending on the activation mechanism, components of the pheromone-responsive MAP kinase pathway can be reconnected to stimulate an alternative developmental program, switching of white cells to the mating-competent opaque phase.

White-opaque switching of Candida albicans allows immune evasion in an environment-dependent fashion.

Candida albicans strains that are homozygous at the mating type locus can spontaneously and reversibly switch from the normal yeast morphology (white) to an elongated cell type (opaque), which is the mating-competent form of the fungus. White-opaque switching also influences the ability of C. albicans to colonize and proliferate in specific host niches and its susceptibility to host defense mechanisms. We used live imaging to observe the interaction of white and opaque cells with host phagocytic cells. For this purpose, we generated derivatives of the switching-competent strain WO-1 that express green fluorescent protein from a white-specific promoter and red fluorescent protein from an opaque-specific promoter or vice versa. When mixed populations of these differentially labeled white and opaque cells were incubated with human polymorphonuclear neutrophils (PMNs) on a glass slide, the neutrophils selectively phagocytosed and killed white cells, despite frequent physical interaction with opaque cells. White cells were attacked only after they started to form a germ tube, indicating that the suppression of filamentation in opaque cells saved them from recognition by the PMNs. In contrast to neutrophils, dendritic cells internalized white as well as opaque cells. However, when embedded in a collagen matrix, the PMNs also phagocytosed both white and opaque cells with similar efficiency. These results suggest that, depending on the environment, white-opaque switching enables C. albicans to escape from specific host defense mechanisms.

Tetracycline-inducible gene expression in Candida albicans.

In addition to gene inactivation, the manipulation of gene expression is another highly useful tool for the analysis of gene function. Several regulatable promoters are available that enable researchers to shut off or turn on the expression of a target gene in Candida albicans, usually by growing the cells in inducing or repressing media. In this chapter, we describe a tetracycline-inducible gene expression system (Tet-On) that allows forced expression of endogenous or heterologous genes in C. albicans by the addition of the small-molecule inducer doxycycline in a growth medium-independent manner. The system is based on a cassette in which a gene of interest can be placed under the control of a Tet-inducible promoter in a single cloning step and integrated into the C. albicans genome with the help of a dominant selection marker. As the cassette contains all necessary components for Tet-inducible gene expression, it can be used to study the effect of forced gene expression on the phenotype of C. albicans cells in any strain without a requirement of additional genetic manipulations.

The transcription factor Ndt80 does not contribute to Mrr1-, Tac1-, and Upc2-mediated fluconazole resistance in Candida albicans.

The pathogenic yeast Candida albicans can develop resistance to the widely used antifungal agent fluconazole, which inhibits ergosterol biosynthesis, by the overexpression of genes encoding multidrug efflux pumps or ergosterol biosynthesis enzymes. Zinc cluster transcription factors play a central role in the transcriptional regulation of drug resistance. Mrr1 regulates the expression of the major facilitator MDR1, Tac1 controls the expression of the ABC transporters CDR1 and CDR2, and Upc2 regulates ergosterol biosynthesis (ERG) genes. Gain-of-function mutations in these transcription factors result in constitutive overexpression of their target genes and are responsible for fluconazole resistance in many clinical C. albicans isolates. The transcription factor Ndt80 contributes to the drug-induced upregulation of CDR1 and ERG genes and also binds to the MDR1 and CDR2 promoters, suggesting that it is an important component of all major transcriptional mechanisms of fluconazole resistance. However, we found that Ndt80 is not required for the induction of MDR1 and CDR2 expression by inducing chemicals. CDR2 was even partially derepressed in ndt80Δ mutants, indicating that Ndt80 is a repressor of CDR2 expression. Hyperactive forms of Mrr1, Tac1, and Upc2 promoted overexpression of MDR1, CDR1/CDR2, and ERG11, respectively, with the same efficiency in the presence and absence of Ndt80. Mrr1- and Tac1-mediated fluconazole resistance was even slightly enhanced in ndt80Δ mutants compared to wild-type cells. These results demonstrate that Ndt80 is dispensable for the constitutive overexpression of Mrr1, Tac1, and Upc2 target genes and the increased fluconazole resistance of strains that have acquired activating mutations in these transcription factors.

Modulation of transcription affects mRNP quality.

Cotranscriptional loading of proteins onto nascent transcripts contributes to the formation of messenger ribonucleoprotein particles (mRNPs) competent for nuclear export. The transcription machinery is believed to play a pivotal role in mRNP assembly, which is at least partially linked to the function of the THO/TREX complex and the mRNA termination/polyadenylation apparatus. Here we demonstrate a prominent role for the rate of transcription in the production of export-competent mRNPs. We show that a transcription-defective allele of the Rad3p helicase, a component of the TFIIH transcription initiation factor, suppresses several phenotypes associated with defective mRNA processing and export. Strikingly, the effects of compromised Rad3p activity can be phenocopied by a transcription elongation drug as well as by other mutations affecting transcription. Our results suggest that efficient mRNP assembly is under a kinetic control that is influenced by the rate of transcription.