游动放线菌属CKD485 - 16在阿卡波糖发酵中副产物组分C的生成减少。

Reduced formation of byproduct component C in acarbose fermentation by Actinoplanes sp. CKD485-16.

作者信息

Choi Byoung Taek, Shin Chul Soo

机构信息

Department of Biotechnology, College of Engineering, Yonsei University, Seodaemun-gu, Seoul 120-749, South Korea.

出版信息

Biotechnol Prog. 2003 Nov-Dec;19(6):1677-82. doi: 10.1021/bp034079y.

DOI:10.1021/bp034079y

PMID:14656141

Abstract

Acarbose fermentation was conducted by cultivation of Actinoplanes sp. CKD485-16. Approximately 2,300 mg/L of acarbose was produced at the end of cultivation along with 600 mg/L of the acarbose byproduct component C. Maltose, a known moiety of acarbose, should be maintained at high concentration levels in culture broths for efficient acarbose production. The acarbose yield increased with an increasing osmolality of the culture medium, with a maximum value of 3,200 mg/L obtained at 500 mOsm/kg. Component C was also produced in proportion to the osmolality. Conversion of acarbose to component C was accomplished with resting whole cells. Inhibitors of the conversion of acarbose to component C were sought since component C is probably derived from acarbose. Valienamine was found to be a potent inhibitor, resulting in a more than 90% reduction in component C formation at a 10 microM concentration. Effects were similar in a 1,500-L pilot fermentor with acarbose and component C yields of 3,490 and 43 mg/L at 500 mOsm/kg, respectively.

摘要

通过培养游动放线菌属菌株CKD485 - 16进行阿卡波糖发酵。培养结束时产生了约2300 mg/L的阿卡波糖以及600 mg/L的阿卡波糖副产物组分C。麦芽糖作为阿卡波糖的已知部分，应在培养液中保持高浓度水平以实现高效的阿卡波糖生产。阿卡波糖产量随着培养基渗透压的增加而增加，在500 mOsm/kg时获得的最大值为3200 mg/L。组分C也与渗透压成比例产生。阿卡波糖向组分C的转化是通过静息全细胞完成的。由于组分C可能源自阿卡波糖，因此寻找了阿卡波糖向组分C转化的抑制剂。发现戊糖尿胺是一种有效的抑制剂，在10 microM浓度下可使组分C的形成减少90%以上。在1500 L的中试发酵罐中也有类似效果，在500 mOsm/kg时阿卡波糖和组分C的产量分别为3490 mg/L和43 mg/L。

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游动放线菌属CKD485 - 16在阿卡波糖发酵中副产物组分C的生成减少。

Reduced formation of byproduct component C in acarbose fermentation by Actinoplanes sp. CKD485-16.

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