Synthesis of d-xylulose from d-arabitol by enzymatic conversion with immobilized mannitol dehydrogenase from Rhodobacter sphaeroides

Overcoming NADPH product inhibition improves D-sorbitol conversion to L-sorbose

Gluconobacter oxydans sorbitol dehydrogenase (GoSLDH) exhibits a higher catalytic efficiency than other l-sorbose producing enzymes. During the reaction catalysed by GoSLDH, NADP⁺ is reduced to NADPH and d-sorbitol is oxidized to l-sorbose. However, GoSLDH activity is inhibited by the NADPH (K_i = 100 μM) formed during the enzymatic reaction. Therefore, Escherichia coli_{gosldh-lrenox} producing both GoSLDH for d-sorbitol oxidation and LreNOX (NAD(P)H oxidase from Lactobacillus reuteri) for NADP⁺ regeneration was generated and used for l-sorbose production. Whole cell biocatalysts with the LreNOX cofactor recycling system showed a high conversion rate (92%) of d-sorbitol to l-sorbose in the presence of low concentration of NADP⁺ (0.5 mM). By alleviating NADPH accumulation during the catalytic reactions, E. coli_{gosldh-lrenox} exhibited 23-fold higher conversion rate of d-sorbitol than E. coli_gosldh. l-Sorbose production by E. coli_{gosldh-lrenox} reached 4.1 g/L after 40 min, which was 20.5-fold higher than that of E. coli_gosldh. We also constructed G. oxydans_gosldh and G. oxydans_{gosldh-lrenox} strains, and they exhibited 1.2- and 2.9-fold higher conversion rates than the wild-type G. oxydans KCTC 1091. The results indicate that overcoming NADPH product inhibition using LreNOX improves chemical production in NADP⁺-dependent enzymatic reactions.

Rare sugar production by coupling of NADH oxidase and l-arabinitol dehydrogenase

An efficient biocatalytic cell-free system containing l-arabinitol dehydrogenase (LAD) for l-arabinitol oxidation and NADH oxidase (Nox) for cofactor regeneration was successfully constructed and used for l-rare sugar production.

Production of d-lyxose from d-glucose by microbial and enzymatic reactions

D-arabitol was first prepared from D-glucose using Candida famata R28. The reaction gave 5.0% D-arabitol from 10.0% D-glucose. D-arabitol was then almost completely converted to D-xylulose using Acetobacter aceti IFO 3281. Finally, D-lyxose was prepared from D-xylulose enzymatically using L-ribose isomerase from toluene-treated cells of Acinetobacter sp. strain DL-28. The isomerization reaction progressed steadily and the concentration of D-xylulose increased from 1.0 to 10.0%. About 70% of D-xylulose was converted to D-lyxose in all cases. Separation of residual D-xylulose from the reaction mixture is very difficult to achieve by column chromatography, but D-xylulose could be selectively degraded easily using Saccharomyces cerevisiae IFO 0841. The product was crystallized and was confirmed to be D-lyxose by HPLC, 13C-NMR spectra, IR spectra analysis, and optical rotation measurement.

Cloning, nucleotide sequence, and overexpression of smoS, a component of a novel operon encoding an ABC transporter and polyol dehydrogenases of Rhodobacter sphaeroides Si4

The gene coding for sorbitol dehydrogenase (SDH) of Rhodobacter sphaeroides Si4 was located 55 nucleotides upstream of the mannitol dehydrogenase gene (mtlK) within a previously unrecognized polyol operon. This operon probably consists of all the proteins necessary for transport and metabolization of various polyols. The gene encoding SDH (smoS) was cloned and sequenced. Analysis of the deduced amino acid sequence revealed homology to enzymes of the short-chain dehydrogenase/reductase protein family. For structure analysis of this unique bacterial enzyme, smoS was subcloned into the overexpression vector pET-24a(+) and then overproduced in Escherichia coli BL21(DE3), which yielded a specific activity of 24.8 U/mg of protein and a volumetric yield of 38,000 U/liter. Compared to values derived with the native host, R. sphaeroides, these values reflected a 270-fold increase in expression of SDH and a 971-fold increase in the volumetric yield. SDH was purified to homogeneity, with a recovery of 49%, on the basis of a three-step procedure. Upstream from smoS, another gene (smoK), which encoded a putative ATP-binding protein of an ABC transporter, was identified.

Enzyme evolution in Rhodobacter sphaeroides: selection of a mutant expressing a new galactitol dehydrogenase and biochemical characterization of the enzyme

A gain of function mutant of Rhodobacter sphaeroides Si4, capable of growing on galactitol, was isolated from a chemostat culture. Continuous cultivation was performed for 54 d with a limiting concentration (1 mM) of the substrate D-glucitol and an excess (20 mM) of the non-metabolizable galactitol. The mutant strain, R. sphaeroides D, grew in galactitol minimal medium with a growth rate of 0.11 h-1 (td = 6.3 h). In crude extracts of R. sphaeroides D, a specific galactitol dehydrogenase (GDH) activity of 380 mU mg-1 was found, while the wild-type strain exhibited GDH activities lower than 50 mU mg-1 when grown on different polyols. Unlike mannitol, sorbitol or ribitol dehydrogenase from the wild-type strain, the new GDH was expressed constitutively. To study whether it was a newly evolved enzyme or an improved side activity of one of the pre-existing polyol dehydrogenases, GDH was purified to apparent homogeneity by ammonium sulfate precipitation and chromatography on Phenyl-Sepharose, Q-Sepharose, Matrex Gel Red-A and Mono-Q. The relative molecular mass (M(r)) of the native GDH was 110,000. SDS-PAGE resulted in one single band that represented a polypeptide with a M(r) of 28,000, indicating that the native protein is a tetramer. The isoelectric point of GDH was determined to be pH 4.2. The enzyme was specific for NAD+ but catalysed the oxidation of different sugar alcohols as well as different diols and secondary alcohols.(ABSTRACT TRUNCATED AT 250 WORDS)