CONICET | Buscador de Institutos y Recursos Humanos

Microbes establish very diverse but still poorly understood associations with other microscopic or macroscopic organisms that do not follow the more conventional modes of competition or mutualism. Phaffia rhodozyma, an orange-coloured yeast that produces the biotechnologically relevant carotenoid astaxanthin and grows in sugar-rich tree exudates, exhibits an Holarctic association with birch trees in temperate forests that contrasts with the more recent finding of a South American population associated with Nothofagus (southern beech) and with stromata of its biotrophic fungal parasite Cyttaria spp. Here we first investigated if the association of Phaffia with Nothofagus-Cyttaria could be expanded to Australasia, the other region of the world where Nothofagus are endemic, and then studied the genetic structure of populations representing the known worldwide distribution of Phaffia and analyzed the evolution of the association with tree hosts. The phylogenetic analysis of concatenated partial sequences of seven genes from forty strains revealed that Phaffia diversity in Australasia is much higher than in other regions of the globe and that two endemic and markedly divergent lineages seem to represent new species. Moreover, the observed genetic diversity correlates with host tree genera rather than with geography, which suggests that adaptation to the different niches is driving population structure in this yeast. The high genetic diversity and endemism in Australasia indicates that the genus Phaffia evolved in this region and that the association with Nothofagus is the ancestral tree-association. Our estimates of the divergence times of the various Phaffia lineages point to splits that are much more recent than the breakup of Gondwana. This suggests that long distance dispersal rather than vicariance is responsible for the presence of P. rhodozyma in Australasia, South America and in the Holarctic region.