Abstract
While sexual reproduction is pervasive in eukaryotic cells, the strategies employed by fungal species to achieve and complete sexual cycles is highly diverse and complex. Many fungi, including Saccharomyces cerevisiae and Schizosaccharomyces pombe, are homothallic (able to mate with their own mitotic descendants) because of homothallic switching (HO) endonuclease-mediated mating-type switching. Under laboratory conditions, the human fungal pathogen Candida albicans can undergo both heterothallic and homothallic (opposite- and same-sex) mating. However, both mating modes require the presence of cells with two opposite mating types (MTLa/a and α/α) in close proximity. Given the predominant clonal feature of this yeast in the human host, both opposite- and same-sex mating would be rare in nature. In this study, we report that glucose starvation and oxidative stress, common environmental stresses encountered by the pathogen, induce the development of mating projections and efficiently permit same-sex mating in C. albicans with an “a” mating type (MTLa/a). This induction bypasses the requirement for the presence of cells with an opposite mating type and allows efficient sexual mating between cells derived from a single progenitor. Glucose starvation causes an increase in intracellular oxidative species, overwhelming the Heat Shock transcription Factor 1 (Hsf1)- and Heat shock protein (Hsp)90-mediated stress-response pathway. We further demonstrate that Candida TransActivating protein 4 (Cta4) and Cell Wall Transcription factor 1 (Cwt1), downstream effectors of the Hsf1–Hsp90 pathway, regulate same-sex mating in C. albicans through the transcriptional control of the master regulator of a-type mating, MTLa2, and the pheromone precursor-encoding gene Mating α factor precursor (MFα). Our results suggest that mating could occur much more frequently in nature than was originally appreciated and that same-sex mating could be an important mode of sexual reproduction in C. albicans.
Highlights
Sexual reproduction is a driving force for evolution and is prominent in eukaryotic organisms, with fungi adopting highly diverse strategies for sexual mating and reproduction [1, 2]
Sexual reproduction plays a pivotal role in the biology and survival of pathogenic fungal pathogens
We report that environmental stresses induce the development of mating projections and efficient same-sex mating in C. albicans
Summary
Sexual reproduction is a driving force for evolution and is prominent in eukaryotic organisms, with fungi adopting highly diverse strategies for sexual mating and reproduction [1, 2]. In C. albicans, heterothallic (opposite-sex) mating between diploid a and α cells occurs to generate tetraploid a/α intermediates [4, 5]. These tetraploid mating products undergo a parasexual process of concerted chromosome loss to generate diploid and aneuploid progeny rather than adopting a more traditional meiotic cycle [6, 7]. As an additional layer of complexity, an epigenetic switch from the white cell type to the opaque cell type is required for efficient mating to occur [8]. Besides differences in mating competency, white and opaque cells differ in a number of aspects, including metabolic profiles, filamentation ability, susceptibility to antifungals, interactions with host immune cells, and virulence in different infection models [10,11,12]
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