Monomeric Corynebacterium glutamicum N-acetyl glutamate kinase maintains sensitivity to L-arginine but has a lower intrinsic catalytic activity

l-arginine production in Corynebacterium glutamicum: manipulation and optimization of the metabolic process

As an important semi-essential amino acid, l-arginine is extensively used in the food and pharmaceutical fields. At present, l-arginine production depends on cost-effective, green, and sustainable microbial fermentation by using a renewable carbon source. To enhance its fermentative production, various metabolic engineering strategies have been employed, which provide valid paths for reducing the cost of l-arginine production. This review summarizes recent advances in molecular biology strategies for the optimization of l-arginine-producing strains, including manipulating the principal metabolic pathway, modulating the carbon metabolic pathway, improving the intracellular biosynthesis of cofactors and energy usage, manipulating the assimilation of ammonia, improving the transportation and membrane permeability, and performing biosensor-assisted high throughput screening, providing useful insight into the current state of l-arginine production.

Enhancement of himastatin bioproduction via inactivation of atypical repressors in Streptomyces hygroscopicus

Three atypical regulatory genes, hmtABD have been discovered within the himastatin biosynthetic gene cluster (BGC) in Streptomyces hygroscopicus ATCC 53653 and the roles of their products have been identified. HmtA and HmtD do not show any structurally distinct features characteristic of regulatory function yet were shown to play important repressive and stimulatory roles, respectively, related to himastatin biosynthesis. HmtB encodes a conserved acetylglutamate kinase; new member of this family serves as repressor of secondary metabolism. Through repressive networks engineering, the limiting functions of HmtA and HmtB along with the activating functions of HmtD in the himastatin BGC have been identified for the first time by gene activation, qPCR, RT-PCR and HPLC studies of selected mutant strains; two of these mutant strains (ΔhmtA and ΔhmtB) produced himastatin in titers (19.02 ± 1.2 μg/mL, 9.9 folds and 30.40 ± 0.83 μg/mL, 15.8 folds) far exceeding those of the wild-type (WT) producer. Overall, this work provides significant insight into secondary metabolic regulatory mechanisms in Streptomyces. These efforts also highlight and validate a new strategy enabling expanded exploitation of cyclopeptidic natural products such as himastatin that demonstrate exciting antimicrobial and antitumor potentials.

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Identification of two new atypical repressors HmtA and HmtB in himastatin biosynthesis.

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Construction of two new himastatin high-producing genetic engineered mutant strains.

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Enhancement of himastatin bioproduction titers to about 9.9 folds and 15.8 folds more than those of in wild type strain.

NADPH metabolism: a survey of its theoretical characteristics and manipulation strategies in amino acid biosynthesis

Reduced nicotinamide adenine nucleotide phosphate (NADPH), which is one of the key cofactors in the metabolic network, plays an important role in the biochemical reactions, and physiological function of amino acid-producing strains. The manipulation of NADPH availability and form is an efficient and easy method of redirecting the carbon flux to the amino acid biosynthesis in industrial strains. In this review, we survey the metabolic mode of NADPH. Furthermore, we summarize the research developments in the understanding of the relationship between NADPH metabolism and amino acid biosynthesis. Detailed strategies to manipulate NADPH availability are addressed based on this knowledge. Finally, the uses of NADPH manipulation strategies to enhance the metabolic function of amino acid-producing strains are discussed.

Conformational dynamics play important roles upon the function of N-acetylglutamate kinase

N-acetylglutamate kinase (NAGK) catalyzes the phosphorylation of N-acetylglutamate. In many bacteria, NAGK catalysis is the rate controlling step in the L-arginine biosynthesis pathway from glutamate to L-arginine and is allosterically inhibited by L-arginine. Many data show that conformational dynamics of NAGKs are essential for their function. The demonstration of the conformational mechanism provides a potential way to improve the yield of arginine. Due to the lack of NAGK catalysis step in arginine synthesis route of mammals, the elucidation of the dynamic mechanism can also provide a way to design a new antivirus drug. This paper reviews how the dynamics affect the activity of NAGKs and are controlled by the effectors. X-ray crystallography and modeling data have shown that in NAGKs, the structural elements required for inhibitor and substrate binding, catalysis and product release, are highly mobile. It is possible to eliminate the inhibition of the arginine and/or block the synthesis of arginine by disturbing the flexibility of the NAGKs. Amino acid kinase family is thought to share some common dynamic features; the flexible structural elements of NAGKs have been identified, but the details of the dynamics and the signal transfer pathways are yet to be elucidated.

Reengineering of the feedback-inhibition enzyme N-acetyl-l-glutamate kinase to enhance l-arginine production in Corynebacterium crenatum

N-acetyl-l-glutamate kinase (NAGK) catalyzes the second step of l-arginine biosynthesis and is inhibited by l-arginine in Corynebacterium crenatum. To ascertain the basis for the arginine sensitivity of CcNAGK, residue E19 which located at the entrance of the Arginine-ring was subjected to site-saturated mutagenesis and we successfully illustrated the inhibition-resistant mechanism. Typically, the E19Y mutant displayed the greatest deregulation of l-arginine feedback inhibition. An equally important strategy is to improve the catalytic activity and thermostability of CcNAGK. For further strain improvement, we used site-directed mutagenesis to identify mutations that improve CcNAGK. Results identified variants I74V, F91H and K234T display higher specific activity and thermostability. The l-arginine yield and productivity of the recombinant strain C. crenatum SYPA-EH3 (which possesses a combination of all four mutant sites, E19Y/I74V/F91H/K234T) reached 61.2 and 0.638 g/L/h, respectively, after 96 h in 5 L bioreactor fermentation, an increase of approximately 41.8% compared with the initial strain.