Li Yueqi, Xu Lingbin, Sam Faisal Eudes, Li Aihua, Hu Kai, Tao Yongsheng
College of Enology, Northwest A&F University, Yangling, China.
College of Food Science and Engineering, Yangling, China.
J Sci Food Agric. 2024 Aug 30;104(11):6875-6883. doi: 10.1002/jsfa.13519. Epub 2024 May 15.
Higher alcohol acetates (HAAs) are potent aroma-active esters that impart desirable fruity and floral aromas. However, the conversion of higher alcohol precursors into HAAs is extremely low in winemaking. To investigate the underlying yeast-yeast interaction on targeted improvement of aromatic HAAs, we evaluated fermentation activity, cell viability, amino acid consumption and HAA production when Pichia kluyveri and Saccharomyces cerevisiae were inoculated concurrently or sequentially.
Pichia kluyveri PK-21 possessed the ability to survive and increased HAA level up to 5.2-fold in mixed fermentation. Such an increment may benefit from the efficient conversion of higher alcohol precursors into HAAs (>27-fold higher than S. cerevisiae). During mixed fermentation, the two yeasts exhibited crucial interactions regarding cell growth and amino acid competition. Saccharomyces cerevisiae dominated over the co-inoculated P. kluyveri by efficient uptake of amino acids and biomass production. However, this dominance decreased in sequential fermentation, where P. kluyveri growth increased due to the consumption of preferred amino acids prior to S. cerevisiae. Pearson correlation analysis indicated that phenylalanine and aspartic acid may act as positive amino acids in boosting P. kluyveri growth and HAA production. Laboratory-scale winemaking validated the fermentation performance of P. kluyveri in sequential inoculum, resulting in a balanced aroma profile with enhanced floral and tropical fruity characteristics in the final wines.
This study proposes a microbial, non-genetically engineered approach for targeted increase of HAA production in winemaking and the findings provide new insights into yeast-yeast interactions. © 2024 Society of Chemical Industry.
高级乙酸酯(HAAs)是具有强大香气活性的酯类物质,能赋予葡萄酒宜人的果香和花香。然而,在葡萄酒酿造过程中,高级醇前体向HAAs的转化效率极低。为了研究酵母与酵母之间相互作用对目标提升芳香型HAAs的潜在影响,我们评估了同时接种或顺序接种克鲁维毕赤酵母和酿酒酵母时的发酵活性、细胞活力、氨基酸消耗及HAA产量。
克鲁维毕赤酵母PK - 21在混合发酵中具有生存能力,且能将HAA水平提高至5.2倍。这种增加可能得益于高级醇前体向HAAs的高效转化(比酿酒酵母高27倍以上)。在混合发酵过程中,两种酵母在细胞生长和氨基酸竞争方面表现出关键的相互作用。酿酒酵母通过高效摄取氨基酸和生物量生产,在共接种时占主导地位,超过了克鲁维毕赤酵母。然而,在顺序发酵中,这种主导地位有所下降,因为克鲁维毕赤酵母在酿酒酵母之前优先消耗了氨基酸,从而使其生长增加。皮尔逊相关性分析表明,苯丙氨酸和天冬氨酸可能是促进克鲁维毕赤酵母生长和HAA产量的正向氨基酸。实验室规模的葡萄酒酿造验证了顺序接种时克鲁维毕赤酵母的发酵性能,最终葡萄酒呈现出平衡的香气特征,花香和热带水果香气增强。
本研究提出了一种微生物的、非基因工程的方法,用于在葡萄酒酿造中有针对性地提高HAA产量,研究结果为酵母与酵母之间的相互作用提供了新的见解。©2024化学工业协会
