由蜡状芽孢杆菌 NCIM-5727 增强丁香酚生产香草醛。

Enhanced vanillin production from eugenol by Bacillus cereus NCIM-5727.

机构信息

Department of Bioengineering and Biotechnology, Birla Institute of Technology, Mesra, Ranchi, 835215, Jharkhand, India.

出版信息

Bioprocess Biosyst Eng. 2022 Nov;45(11):1811-1824. doi: 10.1007/s00449-022-02787-9. Epub 2022 Oct 2.

Abstract

Biovanillin production by a wild strain of Bacillus cereus NCIM-5727 is studied using eugenol as the precursor aiming to achieve maximum vanillin productivity. Based on shake flask optimization, molar yield and global volumetric productivity of vanillin reached up to 71.2% (6.6 gL) and 0.18 g(Lh), respectively, at 36 h by resting cells of B. cereus NCIM-5727 at the optimum cell concentration of 3 gL using eugenol concentration of 10 gL at 37 ºC, buffer pH 7.0, buffer volume 10%, and shaking speed 180 rpm. Furthermore, small-scale optimization in a bioreactor at the controlled aeration rate of 0.5 Lmin, agitation rate of 210 rpm, and pH 7.0 enhanced the global volumetric productivity of vanillin up to 0.28 g(Lh) at 25 h of bioconversion. The highest vanillin molar yield (75.2%) is reported using resting cells of B. cereus NCIM-5727 upon eugenol biotransformation and found stable for 10 h.

摘要

采用野生蜡状芽孢杆菌 NCIM-5727 作为生产菌，以丁香酚为前体物质生产香草醛，旨在获得最大香草醛产率。通过摇瓶优化，在 37℃、10 g/L 丁香酚、3 g/L 菌体浓度、缓冲液 pH 值 7.0、缓冲液体积 10%、转速 180 r/min 的条件下，利用休止细胞反应 36 h，蜡状芽孢杆菌 NCIM-5727 的香草醛摩尔产率和比产率分别达到 71.2%（6.6 g/L）和 0.18 g/（L·h）。此外，在控制通气速率为 0.5 L/min、搅拌转速为 210 r/min、pH 值为 7.0 的生物反应器中进行小规模优化，可将生物转化 25 h 时香草醛的比产率提高到 0.28 g/（L·h）。采用蜡状芽孢杆菌 NCIM-5727 的休止细胞进行丁香酚生物转化，香草醛摩尔产率最高可达 75.2%，且在 10 h 内保持稳定。

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由蜡状芽孢杆菌 NCIM-5727 增强丁香酚生产香草醛。

Enhanced vanillin production from eugenol by Bacillus cereus NCIM-5727.

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