Abstract
Sex in fungi is governed by the mating-type (MAT) locus, which exists as bipolar, pseudobipolar, or tetrapolar systems. The significance and impact of MAT on sexual reproduction, however, remain understudied. Furthermore, the evolution of fungal MAT loci shares features with the evolution of sex chromosomes in plants and animals. Pathogenic Cryptococcus species harbor a bipolar system with a large contiguous MAT locus, whereas closely related species, such as the non-pathogen C. amylolentus possess a tetrapolar system with unlinked P/R and HD loci. The HD locus encodes homeobox domain containing proteins that play an important and evolutionarily conserved role in sexual reproduction. Here, we explored the roles of HD genes in sexual reproduction and determined the implications of a tetrapolar to bipolar MAT transition. With a CRISPR-Cas9 system we developed for C. amylolentus, we generated gene deletion mutants and demonstrated that a single compatible Sxi1-Sxi2 pair is necessary and sufficient for mating. By relocating the HD genes to the P/R locus, we found that the artificially generated bipolar configuration led to defective sexual development, which could be partially restored through additional rounds of sexual reproduction. Transcriptomic profiling further revealed that a Sxi1-Sxi2 heterodimeric complex drives expression of genes required for DNA replication and ergosterol biosynthesis during sexual reproduction. These findings provide the first experimental demonstration of a tetrapolar-to-bipolar transition in a tetrapolar mating species, illuminating MAT locus evolution and homeodomain protein functions in Cryptococcus.