Three sex phenotypes in a haploid algal species give insights into the evolutionary transition to a self-compatible mating system

Mating systems of haploid species such as fungi, algae, and bryophytes are either heterothallic (self-incompatible) with two sex phenotypes (male and female, or mating type minus and plus in isogamous species) or homothallic (self-compatible) with only a bisexual phenotype producing zygotes within a clone. The anisogamous volvocine green alga Pleodorina starrii is a haploid species previously reported to have a heterothallic mating system. Here, we found that two additional culture strains originating from the same water system of P. starrii were taxonomically identified as P. starrii and produced male and female gametes and zygotes within a clone (bisexual). Sequences of rapidly evolving plastid genome regions were identical between the bisexual and unisexual (male or female) P. starrii strains. Intercrossings between the bisexual and unisexual strains demonstrated normal thick-walled zygotes and high survivability of F1 strains. Thus, these strains belong to the same biological species. Pleodorina starrii has a new haploid mating system that is unique in having three sex phenotypes, namely, male, female, and bisexual. Genetic analyses suggested the existence of autosomal bisexual factor locus independent of volvocine male and female determining regions. The present findings increase our understanding of the initial evolutionary step of transition from heterothallism to homothallism.

Automated summary

The study revealed a new haploid mating system in Pleodorina starrii with three sex phenotypes: male, female, and bisexual. Genetic analyses suggested the presence of a autosomal bisexual factor locus independent of volvocine male and female determining regions, providing insight into the initial evolutionary step from heterothallism to homothallism. The findings indicated that the strains belong to the same biological species, with intercrossings demonstrating normal zygote formation and high survivability of F1 strains.