Chemo-enzymatic synthesis of optically pure rivastigmine intermediate using alcohol dehydrogenase from baker's yeast

An efficient and practical synthesis of (S)-rivastigmine intermediate was developed by employing a chemoenzymatic step toward the synthesis of chiral intermediate N-ethyl-N-methyl-carbamic acid-3-(1S-hydroxy-ethyl)-phenyl ester (2) using crude alcohol dehydrogenase from baker's yeast with reduced nucleotide adenosine dinucleotide (NADH) as proton donor has been demonstrated.     

Stereospecificity of cinnamyl alcohol dehydrogenase and synthesis of stereospecifically labelled coniferyl alcohol

Using horse liver alcohol dehydrogenase, stereospecifically tritiated (R)- and (S)-(γ-³H)-coniferyl alcohol was synthesized. Using both of these substrates it was demonstrated that cinnamyl alcohol dehydrogenase from lignifying Forsythia tissue specifically removes the pro-R-hydrogen atom of coniferyl alcohol in the oxidation to the aldehyde. This also means that in the reverse reaction the A-hydrogen of NADPH is transferred to the Re-site of coniferyl aldehyde.     

Kinetic models for synthesis by a thermophilic alcohol dehydrogenase

Alcohol dehydrogenase (E. C. 1.1.1.1) from Thermoanaerobium brockii at 25 degrees C and at 65 degrees C is more active with secondary than primary alcohols. The enzyme utilizes NADP and NADPH as cosubstrates better than NAD and NADH. The maximum velocities (V(m)) for secondary alcohols at 65 degrees C are 10 to 100 times higher than those at 25 degrees C, whereas the K(m) values are more comparable.At both 25 degrees C and 65 degrees C the substrate analogue 1,1,1,3,3,3-hexafluoro-2-propanol inhibited the oxidation of alcohol competitively with respect to cyclopentanol, and uncompetitively with respect to NADP. Dimethylsulfoxide inhibited the reduction of cyclopentanone competitively with respect to cyclopentanone, and uncompetitively with respect to NADPH. As a product inhibitor, NADP was competitive with respect to NADPH. These results demonstrate that the enzyme binds the nucleotide and then the alcohol or ketone to form a ternary complex which is converted to a product ternary complex that releases product and nucleotide in that order.At 25 degrees C, all aldehydes and ketones examined inhibited the enzyme at concentrations above their Michaelis constants. The substrate inhibition by cyclopentanone was incomplete, and it was uncompetitive with respect to NADPH. Furthermore, cyclopentanone as a product inhibitor showed intercept-linear, slope-parabolic inhibition with respect to cyclopentanol. These results indicate that cyclopentanone binds to the enzyme-NADP complex at high concentrations. The resulting ternary complex slowly dissociates NADP and cyclopentanone.At 65 degrees C, all of the secondary alcohols, with the exception of cyclohexanol, show substrate activation at high concentration. Experiments in which NADP was the variable substrate and cyclopentanol as the constant-variable substrate over a wide range of concentrations gave double reciprocal plots in which the intercepts showed substrate activation and the slopes showed substrate inhibition. These results indicate that the secondary alcohols bind to the enzyme-NADPH complex at high concentrations and that the resulting ternary complex dissociates NADPH faster than the enzyme-NADPH complex. (c) 1993 John Wiley & Sons, Inc.     

Selective synthesis of alcohol dehydrogenase during anaerobic treatment of maize

Summary Anaerobic treatment of a maize seedling mediates the synthesis of five major, native proteins and seven polypeptide size-classes; slab polyacrylamide and autoradiographic techniques were used to analyze extracts from single primary roots. The alcohol dehydrogenase-1 polypeptide is most dramatically synthesized and accumulated during anaerobiosis, as compared to aerobic control data. Allozymes were used to identify alcohol dehydrogenase unequivocally. Our results pertain to interpretations of previous studies on the alcohol dehydrogenase gene system in maize, and to work on the stress proteins of Drosophila.     

Continuous coenzyme dependent stereoselective synthesis of sulcatol by alcohol dehydrogenase

Summary 6-methyl-5-hepten-2-one was reduced to sulcatol ((+)-6-methyl-5-hepten-2-ol) by using alcohol dehydrogenase fromThermoanaerobium brockii in a continuous process. The cofactor NADP(H) was retained by a charged UF-membrane and regenerated by oxidation of isopropanol to acetone. Use of native NADP in a charged UF-membrane reactor proved to be superior to use of PEG coupled NADP in a uncharged UF-membrane reactor.     

In vitro synthesis of pig kidney general acyl CoA dehydrogenase

In vitro synthesis of general acyl CoA dehydrogenase [EC 1.3.99.3], one of the mitochondrial flavoenzymes, was carried out to elucidate its biosynthetic mechanism. Poly(A)+ RNA isolated from pig kidney was translated in vitro using wheat germ lysate system and the synthesized enzyme was immunoprecipitated by the antibody against purified pig kidney general acyl CoA dehydrogenase. The apparent molecular weight of the synthesized protein was estimated to be approximately 1,000 daltons larger than that of the mature enzyme, indicating that general acyl CoA dehydrogenase in pig kidney is synthesized as a precursor with a larger molecular weight.     

A new approach for using cofactor dependent enzymes: example of alcohol dehydrogenase

The use of enzymes requiring a cofactor as substrate in organic synthesis is still a problem since the cofactors are expensive. This study deals with a new approach consisting of using fragments of NAD+. Three fragments of NAD(H) are examined. The activities of NMN+ and NMNH are greatly improved by the addition of adenosine in ethanol oxidation and in cyclohexanone reduction, respectively. Nicotinamide mononucleoside is not active in the ethanol oxidation but the addition of AMP promotes this reaction.     

Retinoic acid synthesis by cytosol from the alcohol dehydrogenase negative deermouse

Cytosolic alcohol dehydrogenase in the deermouse is coded by a single genetic locus and a strain of the deermouse which is alcohol dehydrogenase negative exists. These two strains of the deermouse were used to extend insight into the role of cytosolic alcohol dehydrogenases in the conversion of retinol into retinoic acid. Retinoic acid synthesis from physiological concentrations of retinol (7.5 microM) with cytosol from the alcohol dehydrogenase negative deermouse was 13% (liver), 14% (kidney), 60% (testes), 78% (lung), and 100% (small intestinal mucosa) of that observed with cytosol from the positive deermouse. The rates in the negative strain ranged from 0.3 to 0.7 nmol/h/mg protein: sufficient to fulfill cellular needs for retinoic acid. Ten millimolar 4-methylpyrazole inhibited retinoic acid synthesis 92, 94, 26, and 30% in kidney, liver, lung, and testes of the positive deermouse, respectively, but only 50, 30, 0, and 0% in the same tissues from the negative deermouse. Ethanol (300 mM) did not inhibit retinoic acid synthesis in kidney cytosol from the negative strain. Therefore multiple cytosolic dehydrogenases, including alcohol dehydrogenases, contribute to retinol metabolism in vitro. The only enzyme(s) likely to be physiologically significant to retinoic acid synthesis in vivo, however, is the class of dehydrogenase, distinct from ethanol dehydrogenase, that is common to both the positive and the negative deermouse. This conclusion is supported by the data described above, the kinetics of retinoic acid synthesis and retinal reduction in kidney cytosol from the negative deermouse, and the very existence of the alcohol dehydrogenase negative deermouse. This work also shows that microsomes inhibit the cytosolic conversion of retinol into retinoic acid and that the synthesis of retinal, a retinoid that has no known function outside of the eye, does not reflect the ability or capacity of a sample to synthesize retinoic acid.     

Liver alcohol dehydrogenase

The article deals with the structure and function of liver alcohol dehydrogenase and reviews mainly literature published after 1979, i.e., summarizes progress made in the field since Klinman presented her review on alcohol dehydrogenases. The emphasis will be on high-resolution crystallographic data, results obtained with metal-substituted enzyme derivatives, and on the mechanism and pH dependence of the catalytic reaction.     

Soybean alcohol dehydrogenase

Alcohol dehydrogenase was prepared from germinating soybean seeds. Specific activity was increased from 511 to 31316 units. The coenzyme is NAD with a K_m of 10^?4M. Allyl alcohol is oxidized faster than ethanol; with the latter substrate, the K_m is 1.3 × 10^?2M, and the pH optimum 8.7. The enzyme catalyses acetaldehyde reduction, with a K_m of 10^?2M and a pH opt of 7.1. The MW is 53(±5) × 10^?3.     

A dual function of alcohol dehydrogenase in Drosophila

Alcohol dehydrogenase (ADH) of Drosophila not only catalyzes the oxidation of ethanol to acetaldehyde, but additionally catalyzes the conversion of this highly toxic product into acetate. This mechanism is demonstrated by using three different methods. After electrophoresis the oxidation of acetaldehyde is shown in an NAD-dependent reaction revealing bands coinciding with the bands likewise produced by a conventional ADH staining procedure. In spectrophotometric measurements acetaldehyde is oxidized in an NAD-dependent reaction. This activity is effectively inhibited by pyrazole, as specific inhibitor of ADH. By means of gas chromatographic analysis a quick generation of acetate from ethanol could be demonstrated. Our conclusion is further supported by experimental results obtained with either purified ADH^F enzyme or genotypes with or without ADH, aldehyde-oxidase, pyridoxal-oxidase and xanthine-dehydrogenase activity. These results are discussed in relation to ethanol tolerance in the living organism in particular with respect to differences found between ADH in Drosophila melanogaster and D. simulans, and in relation to the possible implications for the selective forces acting on ADH-polymorphism.     

Regulation of synthesis of benzyl alcohol dehydrogenase in Acinetobacter calcoaceticus NCIB8250.

Specific activity of benzyl alcohol dehydrogenase in carbon-limited continuous cultures was at a maximum at a specific growth rate of 0.2 h-1, but fell off at lower and higher growth rates. The specific activity in nitrogen-limited cultures was always lower and was inversely proportional to growth rate. There was severe repression of benzyl alcohol dehydrogenase during metabolism of L(+)-mandelate or phenylglyoxylate in batch cultures. Synthesis of benzyl alcohol dehydrogenase was followed in experiments where various compounds, including a gratuitous inducer and an anti-inducer of the mandelate enzymes, were added to uninduced or pre-induced cultures and to constitutive and blocked mutants. The results led to the conclusion that there were at least two types of repression. One was caused by phenylglyoxylate carbon-lyase (or a compound synthesized co-ordinately with it), but not by the other mandelate enzymes or by L(+)-mandelate, phenylglyoxylate, benzaldehyde or benzoate. A second type of repression was observed during rapid growth or after the addition of compound such as succinate which are rapidly and completely metabolized.     

Concurrent synthesis and degradation of alcohol dehydrogenase in elicitor-treated and wounded potato tubers

The accumulation of alcohol dehydrogenase (ADH) in arachidonic acid-elicited potato (Solanum tuberosum L.) tuber discs was studied. In accordance with our previous report of the accumulation of Adh mRNA beginning 2 hours after elicitor treatment (DP Matton, CP Constabel, N Brisson [1990] Plant Mol Biol 14: 775-783), immunoprecipitation of ADH from in vivo labeled discs indicated that ADH synthesis occurred as early as 12 hours after treatment. However, levels of ADH activity and protein, as shown by enzyme assay and immunoblot, did not rise in parallel but decreased during the first 24 hours of treatment. After 24 hours, ADH activity and protein began to increase, reaching a several-fold increase at 96 hours after elicitation. Water-treated control discs showed a similar though delayed and less pronounced pattern. These results imply a turnover of ADH following elicitor treatment of potato tuber discs. As shown by nondenaturing gel electrophoresis, the synthesis and degradation involved the same ADH isozyme.     

A novel alcohol dehydrogenase present in Rhodomicrobium vannielii

Summary An alcohol dehydrogenase specific for NADP as coenzyme and with a pH optimum of 10.2 has been partially purified from the photosynthetic bacterium, Rhodomicrobium vannielii. With the exception of methan-1-ol, primary straight chain alcohols up to eight carbon atoms were active, highest rates being obtained with butan-1-ol. Substrate specificity was examined by both enzymic rate determination and Km value measurement. The alcohol dehydrogenase described was constitutive.     

Stereoselective synthesis of the key intermediate of ticagrelor and its diverse analogs using a new alcohol dehydrogenase from Rhodococcus kyotonensis

Bioreduction catalyzed by alcohol dehydrogenase/reductase is one of the most valuable biotransformation processes widely used in industry. The (S)-2-Chloro-1-(3, 4-difluorophenyl) ethanol is a key chiral synthon for synthesizing the antithrombotic agent ticagrelor. Herein, a new alcohol dehydrogenase (named Rhky-ADH) identified from Rhodococcus kyotonensis by an enzyme promiscuity-based genome mining method was successfully cloned and functionally expressed in Escherichia coli. The whole cell biocatalyst harboring Rhky-ADH was biochemically characterized and was shown to be able to convert 2-Chloro-1-(3, 4-difluorophenyl) ethanone to (S)-2-Chloro-1-(3, 4-difluorophenyl) ethanol with more than 99 % enantiomeric excess (ee) and 99 % conversion. Our data showed that the optimum temperature and pH for Rhky-ADH were 25 °C and pH 8.0, respectively. The addition of NADH and an appropriate concentration of isopropanol enhanced the activity of Rhky-ADH, and 1 mM Mn²⁺ increased the enzyme activity by about 8 %. Substrate specificity experiments showed that Rhky-ADH had notable enzyme promiscuity and could reduce several ketones with high stereoselectivity. Our investigation on this novel enzyme adds another rare biocatalyst to the toolbox for producing chiral alcohols, which are widely used in the pharmaceutical industry.     

An alcohol dehydrogenase ribozyme

We report an RNA molecule that exhibits activity analogous to that of alcohol dehydrogenase (ADH). Directed in vitro evolution was used to enrich nicotinamide adenine dinucleotide (NAD+)-dependent redox-active RNAs from a combinatorial pool. The most active ribozyme in the population forms a compact pseudoknotted structure and oxidizes an alcohol seven orders of magnitude faster than the estimated spontaneous rate. Moreover, this ADH RNA was coupled with a redox relay between NADH and flavin adenine dinucleotide to give a NAD+-regeneration system. Our demonstration of the redox ability of RNA adds support to an RNA-based metabolic system in ancient life.