Last hope for the doomed? Thoughts on the importance of a parasexual cycle for the yeast Candida albicans.

The yeast Candida albicans, a commensal colonizer and occasional pathogen of humans, has a rudimentary mating ability. However, mating is a cumbersome process that has never been observed outside the laboratory, and the population structure of the species is predominantly clonal. Here we discuss recent findings that indicate that mating ability is under selection in C. albicans, i.e. that it is a biologically relevant process. C. albicans strains can only mate after they have sustained genetic damage. We propose that the rescue of such damaged strains by mating may be the primary reason why mating ability is under selection.

Selective Advantages of a Parasexual Cycle for the Yeast Candida albicans.

The yeast Candida albicans can mate. However, in the natural environment mating may generate progeny (fusants) fitter than clonal lineages too rarely to render mating biologically significant: C. albicans has never been observed to mate in its natural environment, the human host, and the population structure of the species is largely clonal. It seems incapable of meiosis, and most isolates are diploid and carry both mating-type-like (MTL) locus alleles, preventing mating. Only chromosome loss or localized loss of heterozygosity can generate mating-competent cells, and recombination of parental alleles is limited. To determine if mating is a biologically significant process, we investigated if mating is under selection. The ratio of nonsynonymous to synonymous mutations in mating genes and the frequency of mutations abolishing mating indicated that mating is under selection. The MTL locus is located on chromosome 5, and when we induced chromosome 5 loss in 10 clinical isolates, most of the resulting MTL-homozygotes could mate with each other, producing fusants. In laboratory culture, a novel environment favoring novel genotypes, some fusants grew faster than their parents, in which loss of heterozygosity had reduced growth rates, and also faster than their MTL-heterozygous ancestors-albeit often only after serial propagation. In a small number of experiments in which co-inoculation of an oral colonization model with MTL-homozygotes yielded small numbers of fusants, their numbers declined over time relative to those of the parents. Overall, our results indicate that mating generates genotypes superior to existing MTL-heterozygotes often enough to be under selection.

The enigma of the major repeat sequence of Candida albicans.

The major repeat sequence, discovered in the yeast Candida albicans, is a stretch of repeated DNA that occurs nine times in the haploid genome of this opportunistic fungal pathogen and probably a similar number of times in the genome of Candida dubliniensis. In C. albicans it constitutes 1-2% of the genome. Its occurrence is limited to those two species. Despite its major role as a genomic feature, its function, mode of expansion in size due to duplication of internal subunits, and its origin and mechanism of distribution throughout the genome are not understood, although it is associated with chromosome translocations, chromosome length polymorphisms and regulation of the yeast-hypha dimorphic transition. The polymorphism of the major repeat sequence has been exploited in epidemiology and taxonomic studies. This review describes its sequence, occurrence, use in epidemiology and examines the evidence for its role in chromosome dynamics.

Effect of the major repeat sequence on mitotic recombination in Candida albicans.

The major repeat sequence (MRS) is known to play a role in karyotypic variation in Candida albicans. The MRS affects karyotypic variation by expanding and contracting internal repeats, by altering the frequency of chromosome loss, and by serving as a hotspot for chromosome translocation. We proposed that the effects of the MRS on translocation could be better understood by examination of the effect of the MRS on a similar event, mitotic recombination between two chromosome homologs. We examined the frequency of mitotic recombination across an MRS of average size (approximately 50 kb) as well as the rate of recombination in a 325-kb stretch of DNA adjacent to the MRS. Our results indicate that mitotic recombination frequencies across the MRS were not enhanced compared to the frequencies measured across the 325-kb region adjacent to the MRS. Mitotic recombination events were found to occur throughout the 325-kb region analyzed as well as within the MRS itself. This analysis of mitotic recombination frequencies across a large portion of chromosome 5 is the first large-scale analysis of mitotic recombination done in C. albicans and indicates that mitotic recombination frequencies are similar to the rates found in Saccharomyces cerevisiae.

Effect of the major repeat sequence on chromosome loss in Candida albicans.

The major repeat sequence (MRS) is found at least once on all but one chromosome in Candida albicans, but as yet it has no known relation to the phenotype. The MRS affects karyotypic variation by serving as a hot spot for chromosome translocation and by expanding and contracting internal repeats, thereby changing chromosome length. Thus, MRSs on different chromosomes and those on chromosome homologues can differ in size. We proposed that the MRS's unique repeat structure and, more specifically, the size of the MRS could also affect karyotypic variation by altering the frequency of mitotic nondisjunction. Subsequent analysis shows that both natural and artificially induced differences in the size of the chromosome 5 MRS can affect chromosome segregation. Strains with chromosome 5 homologues that differ in the size of the naturally occurring MRSs show a preferential loss of the homologue with the larger MRS on sorbose, indicating that a larger MRS leads to a higher risk of mitotic nondisjunction for that homologue. While deletion of an MRS has no deleterious effect on the deletion chromosome under normal growth conditions and leads to no obvious phenotype, strains that have the MRS deleted from one chromosome 5 homologue preferentially lose the homologue with the MRS remaining. This effect on chromosome segregation is the first demonstration of a phenotype associated with the MRS.

Recent advances in the genomic analysis of Candida albicans.

The release of the diploid genomic sequence of Candida albicans and its recent community-based annotation have permitted a number of studies which have significantly advanced our understanding of the biology of this important human pathogen. These advances range from analysis of genomic changes to differential gene expression under a variety of conditions. A few general conclusions can be drawn from the data presently in hand; one can expect more and more new insights as the number and kind of experiments grows.

Chromosome translocation induced by the insertion of the URA blaster into the major repeat sequence (MRS) in Candida albicans.

Electrophoretic karyotype studies have shown that clinical isolates of Candida albicans have extensive chromosome length polymorphisms. Chromosome translocation is one of the causes of karyotypic variation. Chromosome translocation events have been shown to occur very frequently at or near the major repeat sequence (MRS) on chromosomes. The MRS consists of the repeated sequences RB2, RPS and HOK, and the repeated sequences are considered to be the template for recombination. To investigate which element of the MRS is important for chromosome translocation, we constructed three cassettes, each containing a URA blaster and sequences homologous to one of the repeats, for insertion into the MRS region on the chromosomes. The ura3 strain STN22u2, which shows a stable, standard karyotype, was transformed with each construct. Insertion events with each cassette occurred at almost all chromosomes. Insertion into the RB2 repeat, but not into the RPS repeat, was accompanied by chromosome translocation in some transformants: chromosome translocations between chromosomes R and 7 and chromosomes 1 and 7 were found, as well as deletions of 7A and 7C from chromosome 7. We conclude that the insertion at the RB2 region may initiate chromosome translocation in C. albicans.

MFalpha1, the gene encoding the alpha mating pheromone of Candida albicans.

Candida albicans, the single most frequently isolated human fungal pathogen, was thought to be asexual until the recent discovery of the mating-type-like locus (MTL). Homozygous MTL strains were constructed and shown to mate. Furthermore, it has been demonstrated that opaque-phase cells are more efficient in mating than white-phase cells. The similarity of the genes involved in the mating pathway in Saccharomyces cerevisiae and C. albicans includes at least one gene (KEX2) that is involved in the processing of the alpha mating pheromone in the two yeasts. Taking into account this similarity, we searched the C. albicans genome for sequences that would encode the alpha pheromone gene. Here we report the isolation and characterization of the gene MFalpha1, which codes for the precursor of the alpha mating pheromone in C. albicans. Two active alpha-peptides, 13 and 14 amino acids long, would be generated after the precursor molecule is processed in C. albicans. To examine the role of this gene in mating, we constructed an mfalpha1 null mutant of C. albicans. The mfalpha1 null mutant fails to mate as MTLalpha, while MTLa mfalpha1 cells are still mating competent. Experiments performed with the synthetic alpha-peptides show that they are capable of inducing growth arrest, as demonstrated by halo tests, and also induce shmooing in MTLa cells of C. albicans. These peptides are also able to complement the mating defect of an MTLalpha kex2 mutant strain when added exogenously, thereby confirming their roles as alpha mating pheromones.