Kan Tulsook, Piyada Bussadee, Jantima Arnthong, Wuttichai Mhuantong, Panida U-Thai, Srisakul Trakarnpaiboon, Verawat Champreda, Surisa Suwannarangsee
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引用次数: 0
摘要
使用脱卤糖合成酶(TreS)通过一步酶法路线生产脱卤糖,因其操作简单和可利用低成本底物而在工业规模应用方面前景广阔。然而,开发一种表达 TreS 的稳健的全细胞生物催化剂对于实现实用且经济可行的生产仍然至关重要。在本研究中,筛选出一株高糖耐受性的 S. cerevisiae 菌株,并将其作为宿主细胞,用于在细胞表面展示来自 Acidiplasma aeolicum 的 TreS。产生的菌株 S. cerevisiae I3A 显示出显著的表面显示 TreS 活性(3358 U/g CDW),并从麦芽糖中获得了约 64% 的三卤糖产率(10.8 g/L/h 生产率)。有趣的是,在生产曲哈糖的过程中没有观察到葡萄糖副产物。S. cerevisiae I3A 细胞可重复使用长达 12 个周期,从而有可能降低曲哈糖产品的成本。因此,我们的研究证明了一种表面表达 TreS 的高糖耐受性 S. cerevisiae 菌株的开发,这种全细胞生物催化剂可高效、经济地生产曲哈露糖,在食品和制药行业具有潜在的应用前景。
Engineering a high-sugar tolerant strain of Saccharomyces cerevisiae for efficient trehalose production using a cell surface display approach.
Trehalose production via a one-step enzymatic route using trehalose synthase (TreS) holds significant promise for industrial-scale applications due to its simplicity and utilization of low-cost substrates. However, the development of a robust whole-cell biocatalyst expressing TreS remains crucial for enabling practical and economically viable production. In this study, a high-sugar tolerant strain of S. cerevisiae was screened and employed as a host cell for the cell surface display of TreS from Acidiplasma aeolicum. The resultant strain, S. cerevisiae I3A, exhibited remarkable surface displayed TreS activity of 3358 U/g CDW and achieved approximately 64% trehalose yield (10.8 g/L/h productivity) from maltose. Interestingly, no glucose by-product was observed during trehalose production. The S. cerevisiae I3A cells exhibited reusability for up to 12 cycles leading to potential cost reduction of trehalose products. Therefore, our study demonstrated the development of a high-sugar tolerant S. cerevisiae strain expressing TreS on its surface as a whole-cell biocatalyst for efficient and economical trehalose production with potential applications in the food and pharmaceutical industries.
期刊介绍:
Bioresources and Bioprocessing (BIOB) is a peer-reviewed open access journal published under the brand SpringerOpen. BIOB aims at providing an international academic platform for exchanging views on and promoting research to support bioresource development, processing and utilization in a sustainable manner. As an application-oriented research journal, BIOB covers not only the application and management of bioresource technology but also the design and development of bioprocesses that will lead to new and sustainable production processes. BIOB publishes original and review articles on most topics relating to bioresource and bioprocess engineering, including: -Biochemical and microbiological engineering -Biocatalysis and biotransformation -Biosynthesis and metabolic engineering -Bioprocess and biosystems engineering -Bioenergy and biorefinery -Cell culture and biomedical engineering -Food, agricultural and marine biotechnology -Bioseparation and biopurification engineering -Bioremediation and environmental biotechnology