The yeast, Saccharomyces cerevisiae, was used as a model to investigate theories of ploidy
evolution. Mutagenesis experiments using the alkylating agent EMS (ethane methyl sulphonate)
were conducted to assess the relative importance that masking of deleterious mutations has on
response to and recovery from DNA damage. In particular, we tested whether cells with higher
ploidy levels have relatively higher fitnesses after mutagenesis, whether the advantages of masking
are more pronounced in tetraploids than in diploids, and whether purging of mutations allows
more rapid recovery of haploid cells than cells with higher ploidy levels. Separate experiments were
performed on asexually propagating stationary phase cells using (1) prototrophic haploid (MATα)
and diploid (MATa/α) strains and (2) isogenic haploid, diploid and tetraploid strains lacking a
functional mating type locus. In both sets of experiments, haploids showed a more pronounced
decrease in apparent growth rate than diploids, but both haploids and diploids appeared to
recover very rapidly. Tetraploids did not show increased benefits of masking compared with
diploids but volume measurements and FACScan analyses on the auxotrophic strains indicated
that all treated tetraploid strains decreased in ploidy level and that some of the treated haploid
lines increased in ploidy level. Results from these experiments confirm that while masking
deleterious mutations provides an immediate advantage to higher ploidy levels in the presence of
mutagens, selection is extremely efficient at removing induced mutations, leading growth rates to
increase rapidly over time at all ploidy levels. Furthermore, ploidy level is itself a mutable trait in
the presence of EMS, with both haploids and tetraploids often evolving towards diploidy (the
ancestral state of S. cerevisiae) during the course of the experiment.