Kessi-Pérez Eduardo I, Araos Sebastián, García Verónica, Salinas Francisco, Abarca Valentina, Larrondo Luis F, Martínez Claudio, Cubillos Francisco A
Centro de Estudios en Ciencia y Tecnología de Alimentos (CECTA), Universidad de Santiago de Chile (USACH), Santiago 9170201, Chile.
Centro de Estudios en Ciencia y Tecnología de Alimentos (CECTA), Universidad de Santiago de Chile (USACH), Santiago 9170201, Chile Departamento de Ciencia y Tecnología de los Alimentos, Universidad de Santiago de Chile (USACH), Santiago 9170201, Chile.
FEMS Yeast Res. 2016 May;16(3). doi: 10.1093/femsyr/fow021. Epub 2016 Mar 4.
Different natural yeast populations have faced dissimilar selective pressures due to the heterogeneous fermentation substrates available around the world; this increases the genetic and phenotypic diversity in Saccharomyces cerevisiae In this context, we expect prominent differences between isolates when exposed to a particular condition, such as wine or sake musts. To better comprehend the mechanisms underlying niche adaptation between two S. cerevisiae isolates obtained from wine and sake fermentation processes, we evaluated fermentative and fungicide resistance phenotypes and identify the molecular origin of such adaptive variation. Multiple regions were associated with fermentation rate under different nitrogen conditions and fungicide resistance, with a single QTL co-localizing in all traits. Analysis around this region identified RIM15 as the causative locus driving fungicide sensitivity, together with efficient nitrogen utilization and glycerol production in the wine strain. A null RIM15 variant confers a greater fermentation rate through the utilization of available glucose instead of its storage. However, this variant has a detrimental effect on fungicide resistance since complex sugars are not synthesized and transported into the membrane. Together, our results reveal the antagonist pleiotropic nature of a RIM15 null variant, positively affecting a series of fermentation related phenotypes, but apparently detrimental in the wild.
由于世界各地可获得的发酵底物种类繁多,不同的天然酵母群体面临着不同的选择压力;这增加了酿酒酵母的遗传和表型多样性。在此背景下,我们预计当暴露于特定条件下(如葡萄酒或清酒原酒)时,不同菌株之间会存在显著差异。为了更好地理解从葡萄酒和清酒发酵过程中获得的两种酿酒酵母菌株之间生态位适应的潜在机制,我们评估了发酵和抗真菌剂抗性表型,并确定了这种适应性变异的分子起源。多个区域与不同氮条件下的发酵速率和抗真菌剂抗性相关,有一个单一的数量性状位点(QTL)在所有性状中共同定位。对该区域的分析确定RIM15是导致葡萄酒菌株对杀真菌剂敏感、有效利用氮和产生甘油的致病基因座。RIM15基因的无效变体通过利用可用的葡萄糖而非储存葡萄糖,赋予了更高的发酵速率。然而,这种变体对杀真菌剂抗性有不利影响,因为复合糖没有合成并运输到细胞膜中。总之,我们的结果揭示了RIM15无效变体的拮抗性多效性本质,它对一系列与发酵相关的表型有积极影响,但在野生环境中显然是有害的。
