Enzyme-based systems and methods for synthesizing the NAD precursors NMN and NaMN are disclosed. Such methods and systems utilize a mutated form of phosphoribosylpyrophosphate synthetase (PRS) that is superactive and/or other enzyme or enzyme combinations that are immobilized onto a solid surface. The methods and systems substantially increase the efficiency and yield of NAD precursor synthesis.

A cofactor self-sufficient Escherichia coli and its construction method and application in the synthesis of L-glufosinate are provided. The present invention expresses a NADH kinase and key enzymes of the cofactor synthesis pathway in E. coli, and knocks out the genes of enzymes that catabolizes cofactor, and with the addition of co-metabolic intermediates during cell incubation, the intracellular NADP(H) concentration is increased by at least 50% and the catalytic activity of glufosinate dehydrogenase by 2-fold, resulting in a significant increase in the spatiotemporal yield of the glufosinate synthesis reaction.

Enzyme-based systems and methods for synthesizing the NAD precursors NMN and NaMN are disclosed. Such methods and systems utilize a mutated form of phosphoribosylpyrophosphate synthetase (PRS) that is superactive and/or other enzyme or enzyme combinations that are immobilized onto a solid surface. The methods and systems substantially increase the efficiency and yield of NAD precursor synthesis.