Homologous Alcohol Dehydrogenase Research Articles

Stereodivergent evolution of KpADH for the asymmetric reduction of diaryl ketones with para-substituents

KpADH is a promising biocatalyst for the synthesis of chiral bulky-bulky alcohols. Substrate specificity toward diaryl ketone substrates with different substituents at phenyl group was investigated. The results reveal that the para-position of diaryl ketones plays important role in manipulating the stereoselectivity of KpADH. Two vital residues, E214 and T215, were identified through single-point mutagenesis, and saturation mutagenesis was performed to evaluate their contributions to the stereoselectivity. Furthermore, stereodivergent evolution of KpADH was achieved through combinatorial mutagenesis. Among them, E214I/T215S/S237A (ISA) and F161V/S196G/E214G (VGG) exhibited e.e. values of >99% (S) and 99% (R) toward [4-(trifluoromethyl)phenyl]-2-pyridinylmethanone (5a), and e.e. values of >99% (S) and 98% (R) toward (4-methylphenyl)-2-pyridinylmethanone (6a), respectively. Kinetic characterization and interaction analysis further prove that the eliminated side-chain collision and enhanced electrostatic interactions are mainly responsible for the increased catalytic efficiency and stereoselectivity. This study provides beneficial mutants with complementary stereoselectivity toward diaryl ketones with para-substituents and also provides guidance for the engineering of homologous alcohol dehydrogenases toward bulky-bulky ketones.

Biochemical characterization of ethanol-dependent reduction of furfural by alcohol dehydrogenases

Lignocellulosic biomass is usually converted to hydrolysates, which consist of sugars and sugar derivatives, such as furfural. Before yeast ferments sugars to ethanol, it reduces toxic furfural to non-inhibitory furfuryl alcohol in a prolonged lag phase. Bioreduction of furfural may shorten the lag phase. Cupriavidus necator JMP134 rapidly reduces furfural with a Zn-dependent alcohol dehydrogenase (FurX) at the expense of ethanol (Li et al. 2011). The mechanism of the ethanol-dependent reduction of furfural by FurX and three homologous alcohol dehydrogenases was investigated. The reduction consisted of two individual reactions: ethanol-dependent reduction of NAD(+) to NADH and then NADH-dependent reduction of furfural to furfuryl alcohol. The kinetic parameters of the coupled reaction and the individual reactions were determined for the four enzymes. The data indicated that limited NADH was released in the coupled reaction. The enzymes had high affinities for NADH (e.g., K ( d ) of 0.043μM for the FurX-NADH complex) and relatively low affinities for NAD(+) (e.g., K ( d ) of 87μM for FurX-NAD(+)). The kinetic data suggest that the four enzymes are efficient "furfural reductases" with either ethanol or NADH as the reducing power. The standard free energy change (ΔG°') for ethanol-dependent reduction of furfural was determined to be -1.1kJmol(-1). The physiological benefit for ethanol-dependent reduction of furfural is likely to replace toxic and recalcitrant furfural with less toxic and more biodegradable acetaldehyde.

Crystal structure of a carbonyl reductase from Candida parapsilosis with anti-Prelog stereospecificity.

A novel short-chain (S)-1-phenyl-1,2-ethanediol dehydrogenase (SCR) from Candida parapsilosis exhibits coenzyme specificity for NADPH over NADH. It catalyzes an anti-Prelog type reaction to reduce 2-hydroxyacetophenone into (S)-1-phenyl-1,2-ethanediol. The coding gene was overexpressed in Escherichia coli and the purified protein was crystallized. The crystal structure of the apo-form was solved to 2.7 A resolution. This protein forms a homo-tetramer with a broken 2-2-2 symmetry. The overall fold of each SCR subunit is similar to that of the known structures of other homologous alcohol dehydrogenases, although the latter usually form tetramers with perfect 2-2-2 symmetries. Additionally, in the apo-SCR structure, the entrance of the NADPH pocket is blocked by a surface loop. In order to understand the structure-function relationship of SCR, we carried out a number of mutagenesis-enzymatic analyses based on the new structural information. First, mutations of the putative catalytic Ser-Tyr-Lys triad confirmed their functional role. Second, truncation of an N-terminal 31-residue peptide indicated its role in oligomerization, but not in catalytic activity. Similarly, a V270D point mutation rendered the SCR as a dimer, rather than a tetramer, without affecting the enzymatic activity. Moreover, the S67D/H68D double-point mutation inside the coenzyme-binding pocket resulted in a nearly 10-fold increase and a 20-fold decrease in the k(cat) /K(M) value when NADH and NADPH were used as cofactors, respectively, with k(cat) remaining essentially the same. This latter result provides a new example of a protein engineering approach to modify the coenzyme specificity in SCR and short-chain dehydrogenases/reductases in general.

Structural basis for the enhanced thermal stability of alcohol dehydrogenase mutants from the mesophilic bacterium Clostridium beijerinckii: contribution of salt bridging.

Previous research in our laboratory comparing the three-dimensional structural elements of two highly homologous alcohol dehydrogenases, one from the mesophile Clostridium beijerinckii (CbADH) and the other from the extreme thermophile Thermoanaerobacter brockii (TbADH), suggested that in the thermophilic enzyme, an extra intrasubunit ion pair (Glu224-Lys254) and a short ion-pair network (Lys257-Asp237-Arg304-Glu165) at the intersubunit interface might contribute to the extreme thermal stability of TbADH. In the present study, we used site-directed mutagenesis to replace these structurally strategic residues in CbADH with the corresponding amino acids from TbADH, and we determined the effect of such replacements on the thermal stability of CbADH. Mutations in the intrasubunit ion pair region increased thermostability in the single mutant S254K- and in the double mutant V224E/S254K-CbADH, but not in the single mutant V224E-CbADH. Both single amino acid replacements, M304R- and Q165E-CbADH, in the region of the intersubunit ion pair network augmented thermal stability, with an additive effect in the double mutant M304R/Q165E-CbADH. To investigate the precise mechanism by which such mutations alter the molecular structure of CbADH to achieve enhanced thermostability, we constructed a quadruple mutant V224E/S254K/Q165E/M304R-CbADH and solved its three-dimensional structure. The overall results indicate that the amino acid substitutions in CbADH mutants with enhanced thermal stability reinforce the quaternary structure of the enzyme by formation of an extended network of intersubunit ion pairs and salt bridges, mediated by water molecules, and by forming a new intrasubunit salt bridge.

Crystal Structure of the Alcohol Dehydrogenase from the Hyperthermophilic Archaeon Sulfolobus solfataricus at 1.85 Å Resolution

The crystal structure of a medium-chain NAD(H)-dependent alcohol dehydrogenase (ADH) from an archaeon has been solved by multiwavelength anomalous diffraction, using a selenomethionine-substituted enzyme. The protein (SsADH), extracted from the hyperthermophilic organism Sulfolobus solfataricus, is a homo-tetramer with a crystallographic 222 symmetry. Despite the low level of sequence identity, the overall fold of the monomer is similar to that of the other homologous ADHs of known structure. However, a significant difference is the orientation of the catalytic domain relative to the coenzyme-binding domain that results in a larger interdomain cleft. At the bottom of this cleft, the catalytic zinc ion is coordinated tetrahedrally and lacks the zinc-bound water molecule that is usually found in ADH apoform structures. The fourth coordination position is indeed occupied by a Glu residue, as found in bacterial tetrameric ADHs. Other differences are found in the architecture of the substrate pocket whose entrance is more restricted than in other ADHs. SsADH is the first tetrameric ADH X-ray structure containing a second zinc ion playing a structural role. This latter metal ion shows a peculiar coordination, with a glutamic acid residue replacing one of the four cysteine ligands that are highly conserved throughout the structural zinc-containing dimeric ADHs.

A super-family of medium-chain dehydrogenases/reductases (MDR). Sub-lines including zeta-crystallin, alcohol and polyol dehydrogenases, quinone oxidoreductase enoyl reductases, VAT-1 and other proteins.

The protein super-family of medium-chain alcohol dehydrogenases (and glutathione-dependent formaldehyde dehydrogenase), polyol dehydrogenases, threonine dehydrogenase, archaeon glucose dehydrogenase, and eye lens reductase-active zeta-crystallins also includes Escherichia coli quinone oxidoreductase, Torpedo VAT-1 protein, and enoyl reductases of mammalian fatty acid and yeast erythronolide synthases. In addition, two proteins with hitherto unknown function are shown to belong to this super-family of medium-chain dehydrogenases and reductases (MDR). Alignment of zeta-crystallins/quinone oxidoreductases/VAT-1 reveals 38 strictly conserved residues, of which approximately half are glycine residues, including those at several space-restricted turn positions and critical coenzyme-binding positions in the alcohol dehydrogenases. This indicates a conserved three-dimensional structure at the corresponding parts of these distantly related proteins and a conserved binding of a coenzyme in the two proteins with hitherto unknown function, thus ascribing a likely oxidoreductase function to these proteins. When all forms are aligned, including enoyl reductases, a zeta-crystallin homologue from Leishmania and the two proteins with hitherto unknown function, only three residues are strictly conserved among the 106 proteins characterised within the superfamily, and significantly these residues are all glycines, corresponding to Gly66, Gly86 and Gly201 of mammalian class I alcohol dehydrogenase. Notably, these residues are located in different domains. Hence, a distant origin and divergent functions, but related forms and interactions, appear to apply to the entire chains of the many prokaryotic and eukaryotic members. Additionally, in the zeta-crystallins/quinone oxidoreductases, a highly conserved tyrosine residue is found. This residue, in the three-dimensional structure of the homologous alcohol dehydrogenase, is positioned at the subunit cleft that contains the active site and could therefore be involved in catalysis. If so, this residue and its role may resemble the pattern of a conserved tyrosine residue in the different family of short-chain dehydrogenases/reductases (SDR).

A Super‐Family of Medium‐Chain Dehydrogenases/Reductases (MDR)

The protein super‐family of medium‐chain alcohol dehydrogenases (and glutathione‐dependent formaldehyde dehydrogenase), polyol dehydrogenases, threonine dehydrogenase, archaeon glucose dehydrogenase, and eye lens reductase‐active ζ‐crystallins also includes Escherichia coli quinone oxidoreductase, Torpedo VAT‐1 protein, and enoyl reductases of mammalian fatty acid and yeast erythronolide synthases. In addition, two proteins with hitherto unknown function are shown to belong to this super‐family of medium‐chain dehydrogenases and reductases (MDR). Alignment of ζ‐crystallins/quinone oxidoreductases/VAT‐1 reveals 38 strictly conserved residues, of which approximately half are glycine residues, including those at several space‐restricted turn positions and critical coenzyme‐binding positions in the alcohol dehydrogenases. This indicates a conserved three‐dimensional structure at the corresponding parts of these distantly related proteins and a conserved binding of a coenzyme in the two proteins with hitherto unknown function, thus ascribing a likely oxidoreductase function to these proteins. When all forms are aligned, including enoyl reductases, a ζ‐crystallin homologue from Leishmania and the two proteins with hitherto unknown function, only three residues are strictly conserved among the 106 proteins characterised within the super‐family, and significantly these residues are all glycines, corresponding to Gly66, Gly86 and Gly201 of mammalian class I alcohol dehydrogenase. Notably, these residues are located in different domains. Hence, a distant origin and divergent functions, but related forms and interactions, appear to apply to the entire chains of the many prokarotic and eukaryotic members. Additionally, in the ζ‐crystallins/quinone oxidoreductases, a highly conserved tyrosine residue is found. This residue, in the three‐dimensional structure of the homologous alcohol dehydrogenase, is positioned at the sub‐unit cleft that contains the active site and could therefore be involved in catalysis. If so, this residue and its role may resemble the pattern of a conserved tyrosine residue in the different family of short‐chain dehydrogenases/reductases (SDR).

Alcohol dehydrogenase (ADH) Influence of homo- and heterologous ADH administration on albino rats craving for alcohol and on ADH isozyme activity in the liver

The effects of homo- and heterologous alcohol dehydrogenase (ADH) administration into albino rats were investigated. It was found that homologous ADH increases and heterologous ADH decreases the craving for ethanol. The latter effect was accompanied by the appearance of anti-ADH-3 antibodies and by a decrease in ADH-3 activity in the liver. Craving for alcohol decreased after both active and passive immunization against ADH.

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.

Zinc environment in sheep liver sorbitol dehydrogenase.

The extended X-ray absorption fine structure (EXAFS) associated with the zinc K-absorption edge has been recorded for sorbitol dehydrogenase. It is interpreted in terms of one cysteine sulfur among the ligands to the active site zinc atom. Simulations of the EXAFS based on the presence of two such sulfurs are less satisfactory, and comparison with the EXAFS of such systems points to the presence of only one sulfur ligand in sorbitol dehydrogenase. These results provide evidence that sorbitol dehydrogenase does not have the characteristic one water, one His, two Cys arrangement of ligands to the active site zinc found in the homologous alcohol dehydrogenases and are consistent with the one water, one His, one Cys, one Glu ligand arrangement of the proposed model of sorbitol dehydrogenase [Eklund, H., Horjales, E., Jörnvall, H., Brändén, C.-I., & Jeffery J. (1985) Biochemistry 24, 8005-8012]. Evidence for the correctness of the model is also evidence for validity of predictive techniques used in constructing the model, i.e., computer graphics fitting of the amino acid sequence to the crystallographically derived structure of a different but homologous protein.

Tissue-specific regulatory differences for the alcohol dehydrogenase genes of Hawaiian Drosophila are conserved in Drosophila melanogaster transformants.

Naturally occurring regulatory variation is a source of genetic variability that is well documented but poorly understood. Two members of the Hawaiian picture-winged Drosophila, D. affinidisjuncta and D. hawaiiensis, display markedly different levels of alcohol dehydrogenase (alcohol: NAD+ oxidoreductase, EC 1.1.1.1) in the larval midgut and Malpighian tubules. To analyze the regulation of the alcohol dehydrogenase genes from these two species, their homologous alcohol dehydrogenase genes were cloned and introduced, via P element-mediated transformation, into the germ line of Drosophila melanogaster. Histochemical and electrophoretic analyses of larval transformants demonstrate that major differences in the tissue-specific levels of alcohol dehydrogenase production are characteristic of the alcohol dehydrogenase genes themselves. While these results do not directly address possible species-specific differences in the tissue distribution of trans-acting regulatory components, they indicate that demonstrable differences in cis-dominant regulatory information are sufficient to account for the observed regulatory variation.