Regeneration and retention of NADP (H) for xylitol production in an ionized membrane reactor

Nanoparticle-supported multi-enzyme biocatalysis with in situ cofactor regeneration

Although there have been a long history of studying and using immobilized enzymes, little has been reported regarding the nature of immobilized cofactors. Herein we report that cofactor NAD(H) covalently attached to silica nanoparticles successfully coordinated with particle-immobilized enzymes and enabled multistep biotransformations. Specifically, silica nanoparticle-attached glutamate dehydrogenase (GLDH), lactate dehydrogenase (LDH) and NAD(H) were prepared and applied to catalyze the coupled reactions for production of alpha-ketoglutarate and lactate with the cofactor regenerated within the reaction cycle. It appeared that particle-particle collision driven by Brownian motion of the nanoparticles provided effective interactions among the catalytic components, and thus realized a dynamic shuttling of the particle-supported cofactor between the two enzymes to keep the reaction cycles continuing. Total turnover numbers (TTNs) as high as 20,000h(-1) were observed for the cofactor. It appeared to us that the use of particle-attached cofactor promises a new biochemical processing strategy for cofactor-dependent biotransformations.

Cofactor regeneration for sustainable enzymatic biosynthesis

Oxidoreductases are attractive catalysts for biosynthesis of chiral compounds and polymers, construction of biosensors, and degradation of environmental pollutants. Their practical applications, however, can be quite challenging since they often require cofactors such as nicotinamide adenine dinucleotide (NAD) and nicotinamide adenine dinucleotide phosphate (NADP). These cofactors are generally expensive. Efficient regeneration of cofactors is therefore critical to the economic viability of industrial-scale biotransformations using oxidoreductases. The chemistry of cofactor regeneration is well known nowadays. The challenge is mostly regarding how to achieve the regeneration with immobilized enzyme systems which are preferred for industrial processes to facilitate the recovery and continuous use of the catalysts. This has become a great hurdle for the industrialization of many promising enzymatic processes, and as a result, most of the biotransformations involving cofactors have been traditionally performed with living cells in industry. Accompanying the rapidly growing interest in industrial biotechnology, immobilized enzyme biocatalyst systems with cofactor regeneration have been the focus for many studies reported since the late 1990s. The current paper reviews the methods of cofactor retention for development of sustainable and regenerative biocatalysts as revealed in these recent studies, with the intent to complement other reviewing articles that are mostly regeneration chemistry-oriented. We classify in this paper the methods of sustainable cofactor regeneration into two categories, namely membrane entrapment and solid-attachment of cofactors.

Synthesis and application of water-soluble macromolecular derivatives of the redox coenzymes NAD(H), NADP(H) and FAD

During the past 15 years, the development of strategies to apply the catalytic potential of redox coenzyme-requiring enzymes has been a subject of intensive study; the main purpose of which has been to cut the cost of coenzyme to an economically acceptable level. One approach has been the utilization of isolated coenzyme-dependent enzyme systems with simultaneous enzymatic coenzyme regeneration (recycling). This has been used in conjugation with ultrafiltration reactor technology (enzyme membrane reactor), with coenzyme concentration being kept at a catalytic level. The concept implies confinement (immobilization) and practically 100% retention of both enzymes and coenzymes being dissolved in homogeneous solution within the reactor space that is closed off by an ultrafiltration membrane through which low-molecular-weight reactants (substrates and products) can freely pass. Since the problem of retaining nearly 100% native coenzymes of relatively low molecular weight by ultrafiltration membranes has not been satisfactorily solved, active macromolecular coenzyme derivatives are required. In this review, the syntheses, properties and merits of water-soluble macromolecular derivatives of NAD(H), NADP(H) and FAD are considered with respect to their biotechnological application.

Mechanistic investigation of a highly active phosphite dehydrogenase mutant and its application for NADPH regeneration

NAD(P)H regeneration is important for biocatalytic reactions that require these costly cofactors. A mutant phosphite dehydrogenase (PTDH-E175A/A176R) that utilizes both NAD and NADP efficiently is a very promising system for NAD(P)H regeneration. In this work, both the kinetic mechanism and practical application of PTDH-E175A/A176R were investigated for better understanding of the enzyme and to provide a basis for future optimization. Kinetic isotope effect studies with PTDH-E175A/A176R showed that the hydride transfer step is (partially) rate determining with both NAD and NADP giving (D)V values of 2.2 and 1.7, respectively, and (D)V/K(m,phosphite) values of 1.9 and 1.7, respectively. To better comprehend the relaxed cofactor specificity, the cofactor dissociation constants were determined utilizing tryptophan intrinsic fluorescence quenching. The dissociation constants of NAD and NADP with PTDH-E175A/A176R were 53 and 1.9 microm, respectively, while those of the products NADH and NADPH were 17.4 and 1.22 microm, respectively. Using sulfite as a substrate mimic, the binding order was established, with the cofactor binding first and sulfite binding second. The low dissociation constant for the cofactor product NADPH combined with the reduced values for (D)V and k(cat) implies that product release may become partially rate determining. However, product inhibition does not prevent efficient in situ NADPH regeneration by PTDH-E175A/A176R in a model system in which xylose was converted into xylitol by NADP-dependent xylose reductase. The in situ regeneration proceeded at a rate approximately fourfold faster with PTDH-E175A/A176R than with either WT PTDH or a NADP-specific Pseudomonas sp.101 formate dehydrogenase mutant with a total turnover number for NADPH of 2500.

Coenzymatic properties of low molecular-weight and macromolecular N6-derivatives of NAD+ and NADP+ with dehydrogenases of interest for organic synthesis

The catalytic activity, expressed as Km and Vmax values, of 16 enzymes of practical interest with the macromolecular coenzymes poly(ethylene glycol)-N6-(2-aminoethyl)-NAD+ and poly(ethylene glycol)-N6-(2-aminoethyl)-NADP+ and their low molecular weight precursors N6-(2-aminoethyl)-NAD+ and N6-(2-aminoethyl)-NADP+, was investigated. The enzymes examined are of direct interest for organic synthesis (i.e. alcohol dehydrogenase from yeast, horse liver, or Thermoanaerobium brockii, lactic dehydrogenase, and several hydroxysteroid dehydrogenases) or are used for the regeneration of NAD+, NADP+, NADH, or NADPH (i.e. glutamate dehydrogenase from liver or Proteus, formate dehydrogenase, glucose dehydrogenase, and malic enzyme). The cycling efficiency of poly(ethylene glycol)-N6-(2-aminoethyl)-NADP+ was examined with coupled-enzymes or coupled-substrates systems. Poly(ethylene glycol)-N6-(2-aminoethyl)-NAD+ and, even more so, poly(ethylene glycol)-N6-(2-aminoethyl)-NADP+ were excellent coenzymes with several dehydrogenases. In addition, the coenzymatic properties of N6-(3-sulfonatopropyl)-NAD+, an NAD+ derivative carrying a strong anionic group, were compared with those of the newly synthesized N6-(2-hydroxy-3-trimethylammonium propyl)-NAD+, an NAD+ derivative carrying a strong cationic group. It was expected that the presence of the sulfonic or quaternary ammonium group would enhance the residence time of the coenzyme inside continuous-flow reactors if membranes with anionic or cationic groups, respectively, were used.