Functional improvement of natural Saccharomyces cerevisiae yeast strains by cell surface molecular engineering.

IF 5.7 2区生物学 Q1 BIOLOGY

Biology Direct Pub Date : 2025-02-14 DOI:10.1186/s13062-025-00614-1

Sara Granuzzo, Monica Rossetto, Lucio Zennaro, Francesca Righetto, Paolo Antoniali, Raffaele Lopreiato

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引用次数: 0

Abstract

Background: Cellular boundaries of microorganisms can be modified by the expression in the cell wall of specific proteins endowed with relevant properties, improving their functional performance. So far, the surface display (SD) technique had been widely employed in the yeast Saccharomyces cerevisiae, but it was limited to few laboratory strains and never explored in sauvage strains, i.e., isolated from natural environment, which are featured by higher levels of genetic variability, leading to peculiar phenotypic traits of possible advantage in biotechnology.

Results: In this work, a series of plasmids performing SD in natural yeast strains have been generated and further characterized by multiple functional and biochemical assays, providing the first experimental evidence that natural strains of S.cerevisiae can be genetically modified to express on their cell wall a protein-of-interest, which retains its biological competence. Interestingly, data further demonstrated that engineered strains expressing (transiently or stably) metal-binding proteins or peptides on cell surface exhibit significantly enhanced metal adsorption properties.

Conclusions: The molecular tools presented here can be very useful for yeast research community, as the plasmids efficiently support the surface engineering in virtually all S.cerevisiae strains, independently from either genetic background, source, or applications (wine, beer, bread). Overall, data strongly suggest that, upon genetic modification, S. cerevisiae strains isolated from natural environments could serve as promising platforms for biotechnological applications, as heavy metals removal or enzymes immobilization. Importantly, the strains investigated here represent only a small fraction of the multitude of S. cerevisiae strains present in nature yet to be isolated.

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利用细胞表面分子工程技术改良天然酿酒酵母菌的功能。

背景：微生物的细胞边界可以通过在细胞壁中表达具有相关特性的特定蛋白来修饰，从而改善其功能性能。迄今为止，表面显示（SD）技术已广泛应用于酿酒酵母中，但仅限于少数实验室菌株，从未在从自然环境中分离出来的酵母菌中进行过探索，这些酵母菌具有较高的遗传变异性，具有可能在生物技术中具有优势的特殊表型性状。结果：本研究在天然酵母菌株中生成了一系列具有SD功能的质粒，并通过多种功能和生化分析对其进行了进一步的表征，首次提供了实验证据，证明酵母天然菌株可以通过基因修饰在其细胞壁上表达目标蛋白，并保持其生物学活性。有趣的是，数据进一步表明，在细胞表面表达（瞬时或稳定）金属结合蛋白或肽的工程菌株表现出显著增强的金属吸附性能。结论：本文提出的分子工具对酵母研究界非常有用，因为质粒可以有效地支持几乎所有酿酒酵母菌株的表面工程，而不受遗传背景、来源或应用（葡萄酒、啤酒、面包）的影响。总的来说，数据强烈表明，经过基因改造，从自然环境中分离的酿酒葡萄球菌菌株可以作为生物技术应用的有希望的平台，作为重金属去除或酶固定化。重要的是，这里研究的菌株只代表了自然界中尚未分离的众多酿酒葡萄球菌菌株的一小部分。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Biology Direct 生物-生物学

CiteScore

6.40

自引率

10.90%

发文量

审稿时长

7 months

期刊介绍： Biology Direct serves the life science research community as an open access, peer-reviewed online journal, providing authors and readers with an alternative to the traditional model of peer review. Biology Direct considers original research articles, hypotheses, comments, discovery notes and reviews in subject areas currently identified as those most conducive to the open review approach, primarily those with a significant non-experimental component.