通过三孢布拉氏霉的交配发酵进行生物技术番茄红素生产。

Biotechnological lycopene production by mated fermentation of Blakeslea trispora.

作者信息

López-Nieto M J, Costa J, Peiro E, Méndez E, Rodríguez-Sáiz M, de la Fuente J L, Cabri W, Barredo J L

机构信息

R&D Biology, Antibióticos S.A., Avenida de Antibióticos 59-61, 24009 León, Spain.

出版信息

Appl Microbiol Biotechnol. 2004 Dec;66(2):153-9. doi: 10.1007/s00253-004-1669-4. Epub 2004 Jul 10.

DOI:10.1007/s00253-004-1669-4

PMID:15248041

Abstract

A semi-industrial process (800-l fermentor) for lycopene production by mated fermentation of Blakeslea trispora plus (+) and minus (-) strains has been developed. The culture medium was designed at the flask scale, using a program based on a genetic algorithm; and a fermentation process by means of this medium was developed. Fermentation involves separate vegetative phases for (+) and (-) strains and inoculation of the production medium with a mix of both together. Feeding with imidazole or pyridine, molecules known to inhibit lycopene cyclase enzymatic activity, enhanced lycopene accumulation. Different raw materials and physical parameters, including dissolved oxygen, stirring speed, air flow rate, temperature, and pH, were checked in the fermentor to get maximum lycopene production. Typical data for the fermentation process are presented and discussed. This technology can be easily scaled-up to an industrial application for the production of this carotenoid nowadays widely in demand.

摘要

已开发出一种半工业化工艺（800升发酵罐），用于通过三孢布拉氏霉菌（Blakeslea trispora）的正（+）和负（-）菌株的交配发酵生产番茄红素。培养基是在摇瓶规模上设计的，使用基于遗传算法的程序；并开发了使用这种培养基的发酵工艺。发酵包括正（+）和负（-）菌株的单独营养阶段，以及将两者的混合物接种到生产培养基中。用已知可抑制番茄红素环化酶酶活性的咪唑或吡啶进料，可提高番茄红素的积累。在发酵罐中检查了不同的原材料和物理参数，包括溶解氧、搅拌速度、空气流速、温度和pH值，以获得最大的番茄红素产量。给出并讨论了发酵过程的典型数据。如今，这种技术可以很容易地扩大规模，应用于这种需求广泛的类胡萝卜素的工业化生产。

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通过三孢布拉氏霉的交配发酵进行生物技术番茄红素生产。

Biotechnological lycopene production by mated fermentation of Blakeslea trispora.

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