Genomic rearrangements at the MAT locus suggest reproductive shifts in Rhodotorula yeasts

Rhodotorula, a red yeast genus inhabiting diverse environmental and clinical niches, is a promising microbial source for carotenoid and lipid production. Despite the coexistence of sexual and asexual species, the evolutionary mechanisms underlying their reproductive diversity remain poorly understood. Here, we present a global genomic survey of 249 Rhodotorula strains using Oxford Nanopore, PacBio, and Illumina sequencing. Phylogenomic analysis resolved a robust species tree, delineating three major clades with substantial cryptic species diversity. Chromosome-level assemblies revealed a constrained tetrapolar mating system characterized by unlinked pheromone/receptor (P/R) and homeodomain (HD) mating-type (MAT) loci but displaying infrequent recombination. This genomic architecture is widely conserved, even in species lacking observed sexual cycles, suggesting widespread sexual potential. The P/R locus functions as a supergene, exhibiting conserved gene content and order within mating types but variable configurations between compatible types. Clade-specific biases in mating-type allele distributions indicates asymmetric evolutionary pressures. Structural rearrangements and trans-specific polymorphism of mating-specific allele at the P/R locus, may drive sequence divergence, potentially generating novel mating compatibility within the same mating type. The intermediate P/R genomic states retaining pheromone genes from the opposite mating type may preserve residual functions or facilitate transitions in mating-type architecture. Together with the presence of homozygous hybrid strains, these genomic signatures suggest a potential shift toward same-sex-like mating. Our findings elucidate how mating-type architecture and allele dynamics underpin the evolution of reproductive strategies in fungi and suggest that innovations in MAT system may be a key evolutionary lever in fungal adaptation across environments.