Metabolic engineering of Escherichia coli: increase of NADH availability by overexpressing an NAD(+)-dependent formate dehydrogenase.

Metabolic engineering studies have generally focused on manipulating enzyme levels through either the amplification, addition, or deletion of a particular pathway. However, with cofactor-dependent production systems, once the enzyme levels are no longer limiting, cofactor availability and the ratio of the reduced to oxidized form of the cofactor can become limiting. Under these situations, cofactor manipulation may become crucial in order to further increase system productivity. Although it is generally known that cofactors play a major role in the production of different fermentation products, their role has not been thoroughly and systematically studied. However, cofactor manipulations can potentially become a powerful tool for metabolic engineering. Nicotinamide adenine dinucleotide (NAD) functions as a cofactor in over 300 oxidation-reduction reactions and regulates various enzymes and genetic processes. The NADH/NAD+ cofactor pair plays a major role in microbial catabolism, in which a carbon source, such as glucose, is oxidized using NAD+ producing reducing equivalents in the form of NADH. It is crucially important for continued cell growth that NADH be oxidized to NAD+ and a redox balance be achieved. Under aerobic growth, oxygen is used as the final electron acceptor. While under anaerobic growth, and in the absence of an alternate oxidizing agent, the regeneration of NAD+ is achieved through fermentation by using NADH to reduce metabolic intermediates. Therefore, an increase in the availability of NADH is expected to have an effect on the metabolic distribution. This paper investigates a genetic means of manipulating the availability of intracellular NADH in vivo by regenerating NADH through the heterologous expression of an NAD(+)-dependent formate dehydrogenase. More specifically, it explores the effect on the metabolic patterns in Escherichia coli under anaerobic and aerobic conditions of substituting the native cofactor-independent formate dehydrogenase (FDH) by and NAD(+)-dependent FDH from Candida boidinii. The over-expression of the NAD(+)-dependent FDH doubled the maximum yield of NADH from 2 to 4 mol NADH/mol glucose consumed, increased the final cell density, and provoked a significant change in the final metabolite concentration pattern both anaerobically and aerobically. Under anaerobic conditions, the production of more reduced metabolites was favored, as evidenced by a dramatic increase in the ethanol-to-acetate ratio. Even more interesting is the observation that during aerobic growth, the increased availability of NADH induced a shift to fermentation even in the presence of oxygen by stimulating pathways that are normally inactive under these conditions.

[1]  J. Zeikus,et al.  Utilization of Electrically Reduced Neutral Red byActinobacillus succinogenes: Physiological Function of Neutral Red in Membrane-Driven Fumarate Reduction and Energy Conservation , 1999, Journal of bacteriology.

[2]  P. Cunningham,et al.  Anaerobic regulation of the adhE gene, encoding the fermentative alcohol dehydrogenase of Escherichia coli , 1993, Journal of bacteriology.

[3]  Y. Waché,et al.  Extracellular Oxidoreduction Potential Modifies Carbon and Electron Flow in Escherichia coli , 2000, Journal of bacteriology.

[4]  U. Kragl,et al.  Enzyme engineering aspects of biocatalysis: cofactor regeneration as example. , 2000, Biotechnology and bioengineering.

[5]  H. Sahm,et al.  Purification and properties of formaldehyde dehydrogenase and formate dehydrogenase from Candida boidinii. , 1976, European journal of biochemistry.

[6]  A. Böck,et al.  Nucleotide sequence and expression of the selenocysteine-containing polypeptide of formate dehydrogenase (formate-hydrogen-lyase-linked) from Escherichia coli. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[7]  L. Ingram,et al.  Expression of Different Levels of Ethanologenic Enzymes from Zymomonas mobilis in Recombinant Strains of Escherichia coli , 1988, Applied and environmental microbiology.

[8]  V. V. Fedorchuk,et al.  Pilot scale production and isolation of recombinant NAD+- and NADP+-specific formate dehydrogenases. , 1999, Biotechnology and bioengineering.

[9]  G. Phillips,et al.  High copy number plasmids compatible with commonly used cloning vectors. , 2000, BioTechniques.

[10]  M. Mandrand-Berthelot,et al.  An improved method for the identification and characterization of mutants of Escherichia coli deficient in formate dehydrogenase activity , 1978 .

[11]  M. Kleerebezem,et al.  Cofactor Engineering: a Novel Approach to Metabolic Engineering in Lactococcus lactis by Controlled Expression of NADH Oxidase , 1998, Journal of bacteriology.

[12]  A. Iwamatsu,et al.  Regulation of the formate dehydrogenase gene, FDH1, in the methylotrophic yeast Candida boidinii and growth characteristics of an FDH1-disrupted strain on methanol, methylamine, and choline , 1997, Journal of bacteriology.

[13]  J. Katzenellenbogen,et al.  Proline-valine pseudo peptide enol lactones. Effective and selective inhibitors of chymotrypsin and human leukocyte elastase. , 1991, The Journal of biological chemistry.

[14]  D. Grahame,et al.  Kinetics for formate dehydrogenase of Escherichia coli formate-hydrogenlyase. , 1991, The Journal of biological chemistry.

[15]  J. Foster,et al.  Regulation of NAD metabolism in Salmonella typhimurium: molecular sequence analysis of the bifunctional nadR regulator and the nadA-pnuC operon , 1990, Journal of Bacteriology.

[16]  A. Böck,et al.  On the redox control of synthesis of anaerobically induced enzymes in enterobacteriaceae , 1983, Archives of Microbiology.

[17]  J. Sambrook,et al.  Molecular Cloning: A Laboratory Manual , 2001 .

[18]  D. Clark,et al.  Anaerobic fermentation balance of Escherichia coli as observed by in vivo nuclear magnetic resonance spectroscopy , 1989, Journal of bacteriology.

[19]  G. Bennett,et al.  Metabolic engineering through cofactor manipulation and its effects on metabolic flux redistribution in Escherichia coli. , 2002, Metabolic engineering.

[20]  Svetlana Alexeeva,et al.  The Steady-State Internal Redox State (NADH/NAD) Reflects the External Redox State and Is Correlated with Catabolic Adaptation in Escherichia coli , 1999, Journal of bacteriology.

[21]  Robert M. Williams Synthesis of optically active α-amino acids , 1989 .

[22]  J. Aguilar,et al.  Metabolism of L-fucose and L-rhamnose in Escherichia coli: aerobic-anaerobic regulation of L-lactaldehyde dissimilation , 1988, Journal of bacteriology.

[23]  D. Clark,et al.  Role of NAD in regulating the adhE gene of Escherichia coli , 1996, Journal of bacteriology.

[24]  M. Kula,et al.  Dehydrogenases for the synthesis of chiral compounds. , 1989, European journal of biochemistry.