Your search keyword '"Zhou Zhe-Min"' showing total 3 results

1. Efficient L-Alanine Production by a Thermo-Regulated Switch in Escherichia coli.

Author

Zhou, Li, Deng, Can, Cui, Wen-Jing, Liu, Zhong-Mei, and Zhou, Zhe-Min

Abstract

L-Alanine has important applications in food, pharmaceutical and veterinary and is used as a substrate for production of engineered thermoplastics. Microbial fermentation could reduce the production cost and promote the application of L-alanine. However, the presence of L-alanine significantly inhibit cell growth rate and cause a decrease in the ultimate L-alanine productivity. For efficient l-alanine production, a thermo-regulated genetic switch was designed to dynamically control the expression of l-alanine dehydrogenase ( alaD) from Geobacillus stearothermophilus on the Escherichia coli B0016-060BC chromosome. The optimal cultivation conditions for the genetically switched alanine production using B0016-060BC were the following: an aerobic growth phase at 33 °C with a 1-h thermo-induction at 42 °C followed by an oxygen-limited phase at 42 °C. In a bioreactor experiment using the scaled-up conditions optimized in a shake flask, B0016-060BC accumulated 50.3 g biomass/100 g glucose during the aerobic growth phase and 96 g alanine/100 g glucose during the oxygen-limited phase, respectively. The L-alanine titer reached 120.8 g/l with higher overall and oxygen-limited volumetric productivities of 3.09 and 4.18 g/l h, respectively, using glucose as the sole carbon source. Efficient cell growth and L-alanine production were reached separately, by switching cultivation temperature. The results revealed the application of a thermo-regulated strategy for heterologous metabolic production and pointed to strategies for improving L-alanine production. [ABSTRACT FROM AUTHOR]

Published

2016

2. Metagenomic technology and genome mining: emerging areas for exploring novel nitrilases.

Author

Gong, Jin-Song, Lu, Zhen-Ming, Li, Heng, Zhou, Zhe-Min, Shi, Jin-Song, and Xu, Zheng-Hong

Subjects

NITRILASES, METAGENOMICS, GENOMES, BIOREMEDIATION, ENZYMES

Abstract

Nitrilase is one of the most important members in the nitrilase superfamily and it is widely used for bioproduction of commodity chemicals and pharmaceutical intermediates as well as bioremediation of nitrile-contaminated wastes. However, its application was hindered by several limitations. Searching for new nitrilases and improving their application performances are the driving force for researchers. Genetic data resources in various databases are quite rich in post-genomic era. Besides, more than 99 % of microbes in the environment are unculturable. Metagenomic technology and genome mining are thus becoming burgeoning areas and provide unprecedented opportunities for searching more useful novel nitrilases due to the abundance of already existing but unexplored gene resources, namely uncharacterized genome information in the database and unculturable microbes in the natural environment. These techniques seem to be innovative and highly efficient. This study reviews the current status and future directions of metagenomics and genome mining in nitrilase exploration. Moreover, it discussed their utilization in coping with the challenges for nitrilase application. In the next several years, with the rapid development of nitrile biocatalysis, these two techniques would be bound to attract increasing attentions and even become a dominant trend for finding more novel nitrilases. Also, this review would provide guidance for exploitation of other commercially important enzymes. [ABSTRACT FROM AUTHOR]

Published

2013

3. Isolation, Identification, and Culture Optimization of a Novel Glycinonitrile-Hydrolyzing Fungus- Fusarium oxysporum H3.

Author

Gong, Jin-Song, Lu, Zhen-Ming, Shi, Jing-Song, Dou, Wen-Fang, Xu, Hong-Yu, Zhou, Zhe-Min, and Xu, Zheng-Hong

Abstract

Microbial transformation of glycinonitrile into glycine by nitrile hydrolase is of considerable interest to green chemistry. A novel fungus with high nitrile hydrolase was newly isolated from soil samples and identified as Fusarium oxysporum H3 through 18S ribosomal DNA, 28S ribosomal DNA, and the internal transcribed spacer sequence analysis, together with morphology characteristics. After primary optimization of culture conditions including pH, temperature, carbon/nitrogen sources, inducers, and metal ions, the enzyme activity was greatly increased from 326 to 4,313 U/L. The preferred carbon/nitrogen sources, inducer, and metal ions were glucose and yeast extract, caprolactam, and Cu, Mn, and Fe, respectively. The maximum enzyme formation was obtained when F. oxysporum H3 was cultivated at 30 °C for 54 h with the initial pH of 7.2. There is scanty report about the optimization of nitrile hydrolase production from nitrile-converting fungus. [ABSTRACT FROM AUTHOR]

Published

2011