Impact of inter-species hybridisation on antifungal drug response in the Saccharomyces genus

Antifungal drug resistance across fungal and yeast pathogens presents one of the major concerns for global public health. Understanding the interactions between genetic background and environment is important for the development of new, effective treatments of infections. Allelic variation within populations of Ascomycota as well as hybridisation impacts the phenotype in response to stressful conditions, including to antifungal drugs. We exploited recent advances in multigenerational breeding of Saccharomyces interspecies hybrids to study the impact of hybridisation on antifungal resistance and identify quantitative trait loci (QTL) responsible for the phenotypes observed. A library of Saccharomyces cerevisiae x S. kudriavzevii hybrid offspring was screened in the presence of sub-lethal concentrations of six antifungal drugs and revealed a broad phenotypic diversity across the progeny. QTL analysis was carried out comparing alleles between the pools of high and low fitness offspring, identifying hybrid-specific genetic regions involved in resistance to fluconazole, micafungin and flucytosine. We found both drug specific and pleiotropic regions, and through gene ontology and SIFT analysis we identify potential causal genes, such as BCK2 and DNF1 that were validated via reciprocal hemizygosity analysis. We highlight 41 regions that contain genes not previously associated with resistance phenotypes in the literature. The results of this screening will help identify new pathways contributing to drug resistance, and lead to greater understanding of how allelic variation, hybridisation and evolution affect antifungal drug resistance in yeast and fungi.