Alcohol dehydrogenase: multiplicity and relatedness in the solvent-producing clostridia

Abstract: Alcohol dehydrogenase (ADH) is a key enzyme for the production of butanol, ethanol, and isopropanol by the solvent-producing clostridia. Initial studies of ADH in extracts of several strains of Clostridium acetobutylicum and C. beijerinckii gave conflicting molecular properties. A more coherent picture has emerged because of the following results: (i) identification of ADHs with different coenzyme specificities in these species; (ii) discovery of structurally conserved ADHs (type 3) in three solvent-producing species; (iii) isolation of mutants with deficiencies in butanol production and restoration of butanol production with a cloned alcohol/aldehyde dehydrogenase gene; and (iv) resolution of various ' C. acetobutylicum ' cultures into four species. The three ADH isozymes of C. beijerinckii NRRL B592 have high sequence similarities to ADH-1 of Clostridium sp. NCP 262 (formerly C. acetobutylicum P262) and to the ADH domain of the alcohol/aldehyde dehydrogenase of C. acetobutylicum ATCC 824/DSM 792. The NADH-dependent activity of the ADHs from C. beijerinckii NRRL B592 and the BDHs from C. acetobutylicum ATCC 824 is profoundly affected by the pH of the assay, and the relative importance of NADH and NADPH to butanol production may be misappraised when NAD(P)H-dependent activities were measured at different pH values. The primary/secondary ADH of isopropanol-producing C. beijerinckii is a type-1 enzyme and is highly conserved in Thermoanaerobacter brockii (formerly Thermoanaerobium brockii ) and Entamoeba histolytica . Several solvent-forming enzymes (primary ADH, aldehyde dehydrogenase, and 3-hydroxybutyryl-CoA dehydrogenase) are very similar between C. beijerinckii and the species represented by Clostridium sp. NCP 262 and NRRL B643. The realization of such relationships will facilitate the elucidation of the roles of different ADHs because each type of ADH can now be studied in an organism most amenable to experimental manipulations.     

Purification and characterization of two NAD-dependent alcohol dehydrogenases (ADHs) induced in the quinoprotein ADH-deficient mutant of Acetobacter pasteurianus SKU1108

High NAD-dependent alcohol dehydrogenase (ADH) activity was found in the cytoplasm when a membrane-bound, quinoprotein, ADH-deficient mutant strain of Acetobacter pasteurianus SKU1108 was grown on ethanol. Two NAD-dependent ADHs were separated and purified from the supernatant fraction of the cells. One (ADH I) is a trimer, consisting of an identical subunit of 42 kDa, while the other (ADH II) is a homodimer, having a subunit of 31 kDa. One of the two ADHs, ADH II, easily lost the activity during the column chromatographies, which could be stabilized by the addition of DTT and MgCl2 in the column buffer. ADH I but not ADH II contained approximately one zinc atom per subunit. The N-terminal amino acid analysis indicated that ADH I and ADH II have homology to the long-chain and short-chain ADH families, respectively. ADH I showed a preference for primary alcohols, while ADH II had a preference for secondary alcohols. The two ADHs showed clear difference in their kinetics on ethanol, acetaldehyde, NAD, and NADH. The physiological function of both ADH I and ADH II are also discussed.     

Purification and properties of F420- and NADP(+)-dependent alcohol dehydrogenases of Methanogenium liminatans and Methanobacterium palustre, specific for secondary alcohols

The F420-dependent alcohol dehydrogenase (ADH) of Methanogenium liminatans and the NADP(+)-dependent ADH of Methanobacterium palustre were purified to homogeneity. The native F420-dependent ADH of Mg. liminatans had a molecular mass of 150 kDa and consisted of four (presumably identical) subunits with a mass of 39 kDa. The temperature optimum was 42 degrees C, the optimum pH 6.0 and NaCl or KCl were inhibitory. The NADP(+)-dependent ADH of Mb. palustre had a molecular mass of 175 kDa and consisted also of four (presumably identical) subunits with a mass of 44 kDa. The temperature optimum was 60 degrees C, the optimum pH 8.0 and optimal activity was observed in the presence of 500 mM NaCl or KCl. The ADHs of both organisms catalysed the oxidation of various secondary and cyclic alcohols to the corresponding ketones and the reverse reaction. No primary alcohols were apparently oxidized. The NADP(+)-dependent ADH of Mb. palustre contained 4-8 mol atoms zinc/mol enzyme and was inhibited by low concentrations of iodoacetate and 4-hydroxymercuribenzoate, whereas the F420-dependent ADH of Mg. liminatans presumably contained no zinc ions and was inhibited by 1,10-phenanthroline or high concentrations (e.g. 100 microM) of 4-hydroxymercuribenzoate. Polyclonal antibodies against the NADP(+)-dependent ADH of Mb. palustre precipitated only the homologous ADH. A precipitation of the NADP(+)-dependent ADH of Methanocorpusculum parvum required a 10-fold higher antibody concentration, showing at least a distant relationship of both ADHs. Antibodies against the NADP(+)-dependent ADH of Mcp. parvum, however, formed precipitates with the homologous ADH of Mcp. parvum and with the NADP(+)-dependent ADH of Mb. palustre. They also formed precipitates with the ADH of Thermoanaerobium brockii, which is not related to methane bacteria. Antibodies against the F420-dependent ADH of Mg. liminatans reacted only with the homologous enzyme and did not form precipitates with NADP(+)-dependent ADHs. No immunological relation of the NADP(+)- or F420-dependent ADHs of methanogens with ADH of yeast or horse liver was found. In accordance with the immunological data, the N-terminal amino acid sequences of the NADP(+)-dependent ADHs of Mb. palustre and Mcp. parvum had a high degree of similarity, whereas the N-terminal amino acid sequence of the ADH of Mg. liminatans revealed no similarity with the two NADP(+)-dependent enzymes.     

The ald gene, encoding a coenzyme A-acylating aldehyde dehydrogenase, distinguishes Clostridium beijerinckii and two other solvent-producing clostridia from Clostridium acetobutylicum.

The coenzyme A (CoA)-acylating aldehyde dehydrogenase (ALDH) catalyzes a key reaction in the acetone- and butanol (solvent)-producing clostridia. It reduces acetyl-CoA and butyryl-CoA to the corresponding aldehydes, which are then reduced by alcohol dehydrogenase (ADH) to form ethanol and 1-butanol. The ALDH of Clostridium beijerinckii NRRL B593 was purified. It had no ADH activity, was NAD(H) specific, and was more active with butyraldehyde than with acetaldehyde. The N-terminal amino acid sequence of the purified ALDH was determined. The open reading frame preceding the ctfA gene (encoding a subunit of the solvent-forming CoA transferase) of C. beijerinckii NRRL B593 was identified as the structural gene (ald) for the ALDH. The ald gene encodes a polypeptide of 468 amino acid residues with a calculated M(r) of 51, 353. The position of the ald gene in C. beijerinckii NRRL B593 corresponded to that of the aad/adhE gene (encoding an aldehyde-alcohol dehydrogenase) of Clostridium acetobutylicum ATCC 824 and DSM 792. In Southern analyses, a probe derived from the C. acetobutylicum aad/adhE gene did not hybridize to restriction fragments of the genomic DNAs of C. beijerinckii and two other species of solvent-producing clostridia. In contrast, a probe derived from the C. beijerinckii ald gene hybridized to restriction fragments of the genomic DNA of three solvent-producing species but not to those of C. acetobutylicum, indicating a key difference among the solvent-producing clostridia. The amino acid sequence of the ALDH of C. beijerinckii NRRL B593 was most similar (41% identity) to those of the eutE gene products (CoA-acylating ALDHs) of Salmonella typhimurium and Escherichia coli, whereas it was about 26% identical to the ALDH domain of the aldehyde-alcohol dehydrogenases of C. acetobutylicum, E. coli, Lactococcus lactis, and amitochondriate protozoa. The predicted secondary structure of the C. beijerinckii ALDH suggests the presence of an atypical Rossmann fold for NAD(+) binding. A comparison of the proposed catalytic pockets of the CoA-dependent and CoA-independent ALDHs identified 6 amino acids that may contribute to interaction with CoA.     

Three distinct quinoprotein alcohol dehydrogenases are expressed when Pseudomonas putida is grown on different alcohols.

A bacterial strain that can utilize several kinds of alcohols as its sole carbon and energy sources was isolated from soil and tentatively identified as Pseudomonas putida HK5. Three distinct dye-linked alcohol dehydrogenases (ADHs), each of which contained the prosthetic group pyrroloquinoline quinone (PQQ), were formed in the soluble fractions of this strain grown on different alcohols. ADH I was formed most abundantly in the cells grown on ethanol and was similar to the quinoprotein ADH reported for P. putida (H. Görisch and M. Rupp, Antonie Leeuwenhoek 56:35-45, 1989) except for its isoelectric point. The other two ADHs, ADH IIB and ADH IIG, were formed separately in the cells grown on 1-butanol and 1,2-propanediol, respectively. Both of these enzymes contained heme c in addition to PQQ and functioned as quinohemoprotein dehydrogenases. Potassium ferricyanide was an available electron acceptor for ADHs IIB and IIG but not for ADH I. The molecular weights were estimated to be 69,000 for ADH IIB and 72,000 for ADH IIG, and both enzymes were shown to be monomers. Antibodies raised against each of the purified ADHs could distinguish the ADHs from one another. Immunoblot analysis showed that ADH I was detected in cells grown on each alcohol tested, but ethanol was the most effective inducer. ADH IIB was formed in the cells grown on alcohols of medium chain length and also on 1,3-butanediol. Induction of ADH IIG was restricted to 1,2-propanediol or glycerol, of which the former alcohol was more effective. These results from immunoblot analysis correlated well with the substrate specificities of the respective enzymes. Thus, three distinct quinoprotein ADHs were shown to be synthesized by a single bacterium under different growth conditions.     

Molecular cloning, nucleotide sequencing, and expression of genes encoding alcohol dehydrogenases from the thermophile Thermoanaerobacter brockii and the mesophile Clostridium beijerinckii

Proteins play a pivotal role in thermophily. Comparing the molecular properties of homologous proteins from thermophilic and mesophilic bacteria is important for understanding the mechanisms of microbial adaptation to extreme environments. The thermophile Thermoanaerobacter (Thermoanaerobium) brockii and the mesophile Clostridium beijerinckii contain an NADP(H)-linked, zinc-containing secondary alcohol dehydrogenase (TBADH and CBADH) showing a similarly broad substrate range. The structural genes encoding the TBADH and the CBADH were cloned, sequenced, and highly expressed in Escherichia coli. The coding sequences of the TB adh and the CB adh genes are, respectively, 1056 and 1053 nucleotides long. The TB adh gene encoded an amino acid sequence identical to that of the purified TBADH. Alignment of the deduced amino acid sequences of the TB and CB adh genes showed a 76% identity and a 86% similarity, and the two genes had a similar preference for codons with A or T in the third position. Multiple sequence alignment of ADHs from different sources revealed that two (Cys-46 and His-67) of the three ligands for the catalytic Zn atom of the horse-liver ADH are preserved in TBADH and CBADH. Both the TBADH and CBADH were homotetramers. The substrate specificities and thermostabilities of the TBADH and CBADH expressed inE. coli were identical to those of the enzymes isolated from T. brockii and C. beijerinckii, respectively. A comparison of the amino acid composition of the two ADHs suggests that the presence of eight additional proline residues in TBADH than in CBADH and the exchange of hydrophilic and large hydrophobic residues in CBADH for the small hydrophobic amino acids Pro, Ala, and Val in TBADH might contribute to the higher thermostability of the T. brockii enzyme.     

Comparison of alcohol dehydrogenases from wild-type and mutant strain,JW200 Fe 4, of ‘Thermoanaerobacter ethanolicus’

Summary A mutant strain of Thermoanaerobacter ethanolicus (ATCC 31 550) designated JW200 Fe 4 contains primary and secondary alcohol dehydrogenases (ADHs). The primary ADH from JW000 Fe 4 was formed early in the growth cycle compared to the primary ADH form the wild-type strain (JW200 wt). The secondary ADH displayed 2.5-fold greater activity during the growth cycle of JW200 Fe 4 compared to the secondary ADH form JW200 wt. Both primary and secondary ADHs from JW200 Fe 4 were purified to homogeneity ADHs from JW200 Fe 4 were purified to homogeneity as determined by sodium dodecyl sulphate-gel electrophoresis. Relative molecular weight estimations indicated that both ADHs were tetrameric. Each ADH from JW200 Fe 4 contained approximately four Zn atoms per subunit and displayed Arrhenius plots similar to the ADHs from JW200 wt. The substrate specificity for the ADHs from JW200 Fe 4 was similar to that of the ADHs from JW200 wt. The secondary ADH oxidized 2-propanol at 51 times the rate of ethanol. Both ADHs from JW200 Fe 4 apparently reduce acetaldehyde to ethanol while only the secondary ADH from JW200 wt was suggested to contribute significantly to ethanol production.     

A new NADH-dependent,zinc containing alcohol dehydrogenase from Bacillus thuringiensis serovar israelensis involved in oxidations of short to medium chain primary alcohols

The escalation in genome sequencing has presented a mass of potentially useful new alcohol dehydrogenases (ADHs) in the form of putative open reading frame (ORF). To take advantage of such available resources, PCR primers based on the genome sequence of Bacillus thuringiensis serovar israelensis were used to clone a gene encoding a hypothetical alcohol dehydrogenase (named as BtADH). Activity studies of the translation product revealed that the alcohol dehydrogenases catalyse the inter-conversion of aliphatic aldehydes and corresponding primary alcohol with chain length of two to ten carbons. The required co-factor for such inter-conversion was found to be NAD(H). The ADH gene was engineered for heterologous expression in Escherichia coli, and the enzyme was produced in a soluble form. The recombinant enzyme was purified to homogeneity and physical, spectral and catalytical properties were determined.The findings lead us to propose that BtADH represents a novel primary–secondary alcohol dehydrogenase that acts on primary alcohols of medium chain lengths and simple ketones. Besides, BtADH shares high sequence similarity with well known ADHs from thermophilic origins. Such biochemical characterisation of BtADH provides valuable information for the study of sequence–function relationship including source of thermal stability, cofactor and substrate preferences.     

Butanol-Ethanol Dehydrogenase and Butanol-Ethanol-Isopropanol Dehydrogenase: Different Alcohol Dehydrogenases in Two Strains of Clostridium beijerinckii (Clostridium butylicum)

Alcohol-producing strains of Clostridium beijerinckii (Clostridium butylicum) produce, besides acetone, either n-butanol and ethanol or n-butanol, ethanol, and isopropanol as their characteristic products. Alcohol dehydrogenase has been isolated from a strain (NRRL B593) of C. beijerinckii producing isopropanol and from a strain (NRRL B592) not producing isopropanol. Butanol-ethanol dehydrogenase activities were present in both strains, but isopropanol dehydrogenase activity was present only in the isopropanol-producing strain. The butanol-ethanol dehydrogenase of strain NRRL B592 had M(r) 66,000 and a K(m) of 6 muM for butyraldehyde. In contrast, the butanol-ethanol-isopropanol dehydrogenase of strain NRRL B593 had a M(r) 100,000 and K(m)s of 9.5 and 1.0 mM for butyraldehyde and acetone, respectively. In a purification by four different types of separatory methods (DEAE-cellulose, hydroxyapatite, Sephacryl S-300, and Matrex Gel Red A), butanol-ethanol-isopropanol dehydrogenase activities of strain NRRL B593 were purified up to 200-fold (10 to 30% yield), and these activities were not separated. Gel electrophoresis followed by activity stain also revealed distinct mobilities for the butanol-ethanol dehydrogenase of strain NRRL B592 and the butanol-ethanol-isopropanol dehydrogenase of strain NRRL B593. In cell extracts from both strains, a higher alcohol dehydrogenase activity was measured with NADP(H) than with NAD(H). The 150- to 200-fold-purified alcohol dehydrogenase from strain NRRL B593 did not show any NAD(H)-linked activities. The K(m) for NADPH was 31 muM (with butyraldehyde as cosubstrate) and 18 muM (with acetone as cosubstrate) for the alcohol dehydrogenase of strain NRRL B593. This study showed that the alcohol dehydrogenases from two strains of C. beijerinckii differed significantly.     

Probing Structural Elements of Thermal Stability in Bacterial Oligomeric Alcohol Dehydrogenases. I. Construction and Characterization of Chimeras Consisting of Secondary ADHs from Thermoanaerobacter brockii and Clostridium beijerinckii

Two tetrameric secondary alcohol dehydrogenases (ADHs), one from the mesophile Clostridium beijerinckii (CBADH) and the other from the extreme thermophile Thermoanaerobacter brockii (TBADH), share 75% sequence identity but differ by 26 °C in thermal stability. To explore the role of linear segments of these similar enzymes in maintaining the thermal stability of the thermostable TBADH, a series of 12 CBadh and TBadh chimeric genes and the two parental wild-type genes were expressed in Escherichia coli, and the enzymes were isolated, purified and characterized. The thermal stability of each chimeric enzyme was approximately exponentially proportional to the content of the amino acid sequence of the thermophilic enzyme, indicating that the amino acid residues contributing to the thermal stability of TBADH are distributed along the whole protein molecule. It is suggested that major structural elements of thermal stability may reside among the nine discrepant amino acid residues between the N-terminal 50-amino acid residues of TBADH and CBADH.     

Purification of an alcohol dehydrogenase involved in the conversion of methional to methionol in <Emphasis Type="Italic">Oenococcus oeni</Emphasis> IOEB 8406

Oenococcus oeni, the major lactic acid bacteria involved in malolactic fermentation (MLF) in wine, is able to produce volatile sulfur compounds from methionine. Methional reduction is the last enzymatic step of methionol synthesis in methionine catabolism. Alcohol dehydrogenase (ADH) activity was found to be present in the soluble fraction of O. oeni IOEB 8406. An NAD(P)H-dependent ADH involved in the reduction of methional was then purified to homogeneity. Sequencing of the purified enzyme and amino acid sequence comparison with the database revealed the presence of a conserved sequence motif specific to the medium-chain zinc-containing NAD(P)H-dependent ADHs. Despite the great importance of ADH activities in wine flavor modification, this is the first report of the purification of an ADH isolated from O. oeni. The purified ADH does not seem to be involved in the modification of buttery and lactic notes or to be involved in the specific formation of volatile alcohols during MLF. The enzyme was not strictly specific of methional reduction and the highest reducing activity was obtained with acetaldehyde as substrate. The function of the purified ADH remains unclear, although the role of the sulfur atom in methional molecules in the interaction between enzyme and substrate was evidenced.     

Purification and Characterization of Cinnamyl Alcohol Dehydrogenase Isoforms from the Periderm of Eucalyptus gunnii Hook

Cinnamyl alcohol dehydrogenase (CAD, EC 1.1.1.195) isoforms were purified from the periderm (containing both suberized and lignified cell layers) of Eucalyptus gunnii Hook stems. Two isoforms (CAD 1P and CAD 2P) were initially characterized, and the major form, CAD 2P, was resolved into three further isoforms by ion-exchange chromatography. Crude extracts contained two aliphatic alcohol dehydrogenases (ADH) and one aromatic ADH, which was later resolved into two further isoforms. Aliphatic ADHs did not use hydroxycinnamyl alcohols as substrates, whereas both aromatic ADH isoforms used coniferyl and sinapyl alcohol as substrates but with a much lower specific activity when compared with benzyl alcohol. The minor form, CAD 1P, was a monomer with a molecular weight of 34,000 that did not co-elute with either aromatic or aliphatic ADH activity. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and western blot analysis demonstrated that this protein was very similar to another CAD isoform purified from Eucalyptus xylem tissue. CAD 2P had a native molecular weight of approximately 84,000 and was a dimer consisting of two heterogenous subunits (with molecular weights of 42,000 and 44,000). These subunits were differentially combined to give the heterodimer and two homodimers. SDS-PAGE, western blots, and nondenaturing PAGE indicated that the CAD 2P heterodimer was very similar to the main CAD isoform previously purified in our laboratory from differentiating xylem tissue of E. gunnii (D. Goffner, I. Joffroy, J. Grima-Pettenati, C. Halpin, M.E. Knight, W. Schuch, A.M. Boudet [1992] Planta 188: 48-53). Kinetic data indicated that the different CAD 2P isoforms may be implicated in the preferential production of different monolignols used in the synthesis of lignin and/or suberin.     

The multifunctional isopropyl alcohol dehydrogenase of Phytomonas sp. could be the result of a horizontal gene transfer from a bacterium to the trypanosomatid lineage

Isopropyl alcohol dehydrogenase (iPDH) is a dimeric mitochondrial alcohol dehydrogenase (ADH), so far detected within the Trypanosomatidae only in the genus Phytomonas. The cloning, sequencing, and heterologous expression of the two gene alleles of the enzyme revealed that it is a zinc-dependent medium-chain ADH. Both polypeptides have 361 amino acids. A mitochondrial targeting sequence was identified. The mature proteins each have 348 amino acids and a calculated molecular mass of 37 kDa. They differ only in one amino acid, which can explain the three isoenzymes and their respective isoelectric points previously found. A phylogenetic analysis locates iPDH within a cluster with fermentative ADHs from bacteria, sharing 74% similarity and 60% identity with Ralstonia eutropha ADH. The characterization of the two bacterially expressed Phytomonas enzymes and the comparison of their kinetic properties with those of the wild-type iPDH and of the R. eutropha ADH strongly support the idea of a horizontal gene transfer event from a bacterium to a trypanosomatid to explain the origin of the iPDH in Phytomonas. Phytomonas iPDH and R. eutropha ADH are able to use a wide range of substrates with similar Km values such as primary and secondary alcohols, diols, and aldehydes, as well as ketones such as acetone, diacetyl, and acetoin. We speculate that, as for R. eutropha ADH, Phytomonas iPDH acts as a safety valve for the release of excess reducing power.     

Oxidation of methanol, ethylene glycol, and isopropanol with human alcohol dehydrogenases and the inhibition by ethanol and 4-methylpyrazole

Human alcohol dehydrogenases (ADHs) include multiple isozymes with broad substrate specificity and ethnic distinct allozymes. ADH catalyzes the rate-limiting step in metabolism of various primary and secondary aliphatic alcohols. The oxidation of common toxic alcohols, that is, methanol, ethylene glycol, and isopropanol by the human ADHs remains poorly understood. Kinetic studies were performed in 0.1M sodium phosphate buffer, at pH 7.5 and 25°C, containing 0.5 mM NAD(+) and varied concentrations of substrate. K(M) values for ethanol with recombinant human class I ADH1A, ADH1B1, ADH1B2, ADH1B3, ADH1C1, and ADH1C2, and class II ADH2 and class IV ADH4 were determined to be in the range of 0.12-57 mM, for methanol to be 2.0-3500 mM, for ethylene glycol to be 4.3-2600mM, and for isopropanol to be 0.73-3400 mM. ADH1B3 appeared to be inactive toward ethylene glycol, and ADH2 and ADH4, inactive with methanol. The variations for V(max) for the toxic alcohols were much less than that of the K(M) across the ADH family. 4-Methylpyrazole (4MP) was a competitive inhibitor with respect to ethanol for ADH1A, ADH1B1, ADH1B2, ADH1C1 and ADH1C2, and a noncompetitive inhibitor for ADH1B3, ADH2 and ADH4, with the slope inhibition constants (K(is)) for the whole family being 0.062-960 μM and the intercept inhibition constants (K(ii)), 33-3000 μM. Computer simulation studies using inhibition equations in the presence of alternate substrate ethanol and of dead-end inhibitor 4MP with the determined corresponding kinetic parameters for ADH family, indicate that the oxidation of the toxic alcohols up to 50mM are largely inhibited by 20 mM ethanol or by 50 μM 4MP with some exceptions. The above findings provide an enzymological basis for clinical treatment of methanol and ethylene glycol poisoning by 4MP or ethanol with pharmacogenetic perspectives.     

Degradation of tetrahydrofurfuryl alcohol by Ralstonia eutropha is initiated by an inducible pyrroloquinoline quinone-dependent alcohol dehydrogenase.

An organism tentatively identified as Ralstonia eutropha was isolated from enrichment cultures containing tetrahydrofurfuryl alcohol (THFA) as the sole source of carbon and energy. The strain was able to tolerate up to 200 mM THFA in mineral salt medium. The degradation was initiated by an inducible ferricyanide-dependent alcohol dehydrogenase (ADH) which was detected in the soluble fraction of cell extracts. The enzyme catalyzed the oxidation of THFA to the corresponding tetrahydrofuran-2-carboxylic acid. Studies with n-pentanol as the substrate revealed that the corresponding aldehyde was released as a free intermediate. The enzyme was purified 211-fold to apparent homogeneity and could be identified as a quinohemoprotein containing one pyrroloquinoline quinone and one covalently bound heme c per monomer. It was a monomer of 73 kDa and had an isoelectric point of 9.1. A broad substrate spectrum was obtained for the enzyme, which converted different primary alcohols, starting from C2 compounds, secondary alcohols, diols, polyethylene glycol 6000, and aldehydes, including formaldehyde. A sequence identity of 65% with a quinohemoprotein ADH from Comamonas testosteroni was found by comparing 36 N-terminal amino acids. The ferricyanide-dependent ADH activity was induced during growth on different alcohols except ethanol. In addition to this activity, an NAD-dependent ADH was present depending on the alcohol used as the carbon source.     

Purification and characterization of an oxygen-labile, NAD-dependent alcohol dehydrogenase from Desulfovibrio gigas.

A NAD-dependent, oxygen-labile alcohol dehydrogenase was purified from Desulfovibrio gigas. It was decameric, with subunits of M(r) 43,000. The best substrates were ethanol (Km, 0.15 mM) and 1-propanol (Km, 0.28 mM). N-terminal amino acid sequence analysis showed that the enzyme belongs to the same family of alcohol dehydrogenases as Zymomonas mobilis ADH2 and Bacillus methanolicus MDH.     

Crystal structure of sorbitol dehydrogenase

Sorbitol dehydrogenase (SDH) is a distant relative to the alcohol dehydrogenases (ADHs) with sequence identities around 20%. SDH is a tetramer with one zinc ion per subunit. We have crystallized rat SDH and determined the structure by molecular replacement using a tetrameric bacterial ADH as search object. The conformation of the bound coenzyme is extended and similar to NADH bound to mammalian ADH but the interactions with the NMN-part have several differences with those of ADH. The active site zinc coordination in SDH is significantly different than in mammalian ADH but similar to the one found in the bacterial tetrameric NADP(H)-dependent ADH of Clostridiim beijerinckii. The substrate cleft is significantly more polar than for mammalian ADH and a number of residues are ideally located to position the sorbitol molecule in the active site. The SDH molecule can be considered to be a dimer of dimers, with subunits A-B and C-D, where the dimer interactions are similar to those in mammalian ADH. The tetramers are composed of two of these dimers, which interact with their surfaces opposite the active site clefts, which are accessible on the opposite side. In contrast to the dimer interactions, the tetramer-forming interactions are small with only few hydrogen bonds between side-chains.     

A tightly bound quinone functions in the ubiquinone reaction sites of quinoprotein alcohol dehydrogenase of an acetic acid bacterium, Gluconobacter suboxydans

Quinoprotein alcohol dehydrogenase (ADH) of acetic acid bacteria is a membrane-bound enzyme that functions as the primary dehydrogenase in the ethanol oxidase respiratory chain. It consists of three subunits and has a pyrroloquinoline quinone (PQQ) in the active site and four heme c moieties as electron transfer mediators. Of these, three heme c sites and a further site have been found to be involved in ubiquinone (Q) reduction and ubiquinol (QH2) oxidation respectively (Matsushita et al., Biochim. Biophys. Acta, 1409, 154-164 (1999)). In this study, it was found that ADH solubilized and purified with dodecyl maltoside, but not with Triton X-100, had a tightly bound Q, and thus two different ADHs, one having the tightly bound Q (Q-bound ADH) and Q-free ADH, could be obtained. The Q-binding sites of both the ADHs were characterized using specific inhibitors, a substituted phenol PC16 (a Q analog inhibitor) and antimycin A. Based on the inhibition kinetics of Q2 reductase and ubiquinol-2 (Q2H2) oxidase activities, it was suggested that there are one and two PC16-binding sites in Q-bound ADH and Q-free ADH respectively. On the other hand, with antimycin A, only one binding site was found for Q2 reductase and Q2H2 oxidase activities, irrespective of the presence of bound Q. These results suggest that ADH has a high-affinity Q binding site (QH) besides low-affinity Q reduction and QH2 oxidation sites, and that the bound Q in the QH site is involved in the electron transfer between heme c moieties and bulk Q or QH2 in the low-affinity sites.     

Characterization of a zinc-containing alcohol dehydrogenase with stereoselectivity from the hyperthermophilic archaeon Thermococcus guaymasensis

An alcohol dehydrogenase (ADH) from hyperthermophilic archaeon Thermococcus guaymasensis was purified to homogeneity and was found to be a homotetramer with a subunit size of 40 ± 1 kDa. The gene encoding the enzyme was cloned and sequenced; this gene had 1,095 bp, corresponding to 365 amino acids, and showed high sequence homology to zinc-containing ADHs and l-threonine dehydrogenases with binding motifs of catalytic zinc and NADP(+). Metal analyses revealed that this NADP(+)-dependent enzyme contained 0.9 ± 0.03 g-atoms of zinc per subunit. It was a primary-secondary ADH and exhibited a substrate preference for secondary alcohols and corresponding ketones. Particularly, the enzyme with unusual stereoselectivity catalyzed an anti-Prelog reduction of racemic (R/S)-acetoin to (2R,3R)-2,3-butanediol and meso-2,3-butanediol. The optimal pH values for the oxidation and formation of alcohols were 10.5 and 7.5, respectively. Besides being hyperthermostable, the enzyme activity increased as the temperature was elevated up to 95°C. The enzyme was active in the presence of methanol up to 40% (vol/vol) in the assay mixture. The reduction of ketones underwent high efficiency by coupling with excess isopropanol to regenerate NADPH. The kinetic parameters of the enzyme showed that the apparent K(m) values and catalytic efficiency for NADPH were 40 times lower and 5 times higher than those for NADP(+), respectively. The physiological roles of the enzyme were proposed to be in the formation of alcohols such as ethanol or acetoin concomitant to the NADPH oxidation.     

Cloning and comparative mapping of a human class III (chi) alcohol dehydrogenase cDNA

A cDNA encoding human class III (chi ADH5) alcohol dehydrogenase was isolated, sequenced and used to comparatively map this unusual ADH. In their coding sequences, the three major ADH classes were approximately equisimilar, class II and III ADHs sharing the highest sequence identity (67%). A class III-like ADH was mapped to mouse chromosome 3, site of the ADH gene complex, and synteny of ADH5 with four other ADH loci on human chromosome 4 was confirmed. The nearly full-length 1613 nucleotide cDNA contained 433 nucleotides of 3' nontranslated sequence and two possible initiation sites for translation. A protein of 374 amino acid residues could be synthesized using the potential initiation codon at nucleotide 59. However, use of the likely initiation codon at nucleotide 5 would produce a protein of 392 residues with 19 additional N-terminal residues as compared to the known protein sequence. The derived protein sequence also differs at residue 166, where Tyr is found. This difference, due to a single base substitution, could result from cloning artifact, polymorphism, or two expressed class III ADH genes.