Assessing the molecular and phenotypic contribution of a horizontally acquired region to yeast adaptation

Horizontal Gene Transfer (HGT) is the movement of genetic material across species. In Saccharomyces cerevisiae , a DNA segment known as Region B was acquired horizontally from a distant yeast species. This region (∼17 Kb) encodes 5 genes and is present in the genomes of yeast strains from different phylogenetic clades, with its contribution to yeast niche-specific adaptation remaining unclear. In this work, the genomic structure of Region B was analyzed in yeast strains from the ScRAP ( Saccharomyces cerevisiae Reference Assembly Panel) collection, identifying 10 variants that maintain a circular continuity. To assess the role of Region B in yeast adaptation, we performed a high-throughput phenotyping of the ScRAP collection under different growth conditions, identifying that Region B is potentially associated with higher tolerance to oxidative stress. Then, we selected a single yeast strain from the ScRAP collection for characterization of the transcriptional activity of each gene within Region B using a fluorescent reporter. The results revealed that gene expression depends on the host’s genetic background and transcription factors encoded within Region B. To identify the genetic determinants involved in Region B expression within different genetic backgrounds, three expression Quantitative Trait Loci (eQTLs) were mapped and validated. Finally, by performing Region B deletion, we determine the contribution of this region to different fermentative phenotypes, including fermentation rate and amino acid consumption. Altogether, our results suggest a complex regulatory interaction between the horizontally acquired genes and the host genome that contributes to yeast adaptation under fermentation conditions.