Abstract
L-arginine is an important amino acid in food and pharmaceutical industries. Until now, the main production method of L-arginine in China is the highly polluting keratin acid hydrolysis. The industrial level L-arginine production by microbial fermentation has become an important task. In previous work, we obtained a new L-arginine producing Corynebacterium crenatum (subspecies of Corynebacterium glutamicum) through screening and mutation breeding. In this work, we performed systems pathway engineering of C. crenatum for improved L-arginine production, involving amplification of L-arginine biosynthetic pathway flux by removal of feedback inhibition and overexpression of arginine operon; optimization of NADPH supply by modulation of metabolic flux distribution between glycolysis and pentose phosphate pathway; increasing glucose consumption by strengthening the preexisting glucose transporter and exploitation of new glucose uptake system; channeling excess carbon flux from glycolysis into tricarboxylic acid cycle to alleviate the glucose overflow metabolism; redistribution of carbon flux at α-ketoglutarate metabolic node to channel more flux into L-arginine biosynthetic pathway; minimization of carbon and cofactor loss by attenuation of byproducts formation. The final strain could produce 87.3 g L−1 L-arginine with yield up to 0.431 g L-arginine g−1 glucose in fed-batch fermentation.
Highlights
L-arginine is an important amino acid in food and pharmaceutical industries
Pilot-scale fermentation of the final strain resulted in 78.4 g L−1 of L-arginine with a productivity of 0.98 g L−1 h−1 and yield of 0.387 g g−1 glucose
This feedback inhibition was removed by site-directed mutagenesis of N-acetylglutamate kinase (NAGK), and L-arginine production was largely enhanced by plasmid-encoded overexpression of the multi-mutated NAGKM35
Summary
L-arginine is an important amino acid in food and pharmaceutical industries. The main production method of L-arginine in China is the highly polluting keratin acid hydrolysis. The industrial level L-arginine production by microbial fermentation has become an important task. L-arginine, a semiessential amino acid, has numerous applications in food flavoring and pharmaceutical industries. L-arginine can be produced by starting from keratinous proteins in human hair, pig bristles or animal feathers via acid hydrolysis, like L-cysteine[3]. In China, due to the abundant sources of keratinous proteins and low manufacturing costs, L-arginine is nowadays mainly produced by the highly polluting keratin hydrolysis. Like most of the other amino acids, L-arginine can be produced by microbial fermentation, employing mutant strains of Corynebacterium[1,5,6]. Due to the development of recombinant DNA techniques and increased understanding of the biochemistry of metabolic reactions, metabolic engineering has strongly contributed to the performance of C. glutamicum in www.nature.com/scientificreports/
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