Mammalian alcohol dehydrogenases of separate classes: intermediates between different enzymes and intraclass isozymes

Bioengineered Polymer/Composites as Advanced Biological Detection of Sorbitol: An Application in Healthcare Sector

Bioengineered polymers and nanomaterials have emerged as promising and advanced materials for the fabrication and development of novel biosensors. Nanotechnology-enabled biosensor methods have high sensitivity, selectivity and more rapid detection of an analyte. Biosensor based methods are more rapid and simple with higher sensitivity and selectivity and can be developed for point-of-care diagnostic testing. Development of a simple, sensitive and rapid method for sorbitol detection is of considerable significance to efficient monitoring of diabetes-associated disorders like cataract, neuropathy, and nephropathy at initial stages. This issue encourages us to write a review that highlights recent advancements in the field of sorbitol detection as no such reports have been published till the date. The first section of this review will be dedicated to the conventional approaches or methods that had been playing a role in detection. The second part focused on the emerging field i.e. biosensors with optical, electrochemical, piezoelectric, etc. approaches for sorbitol detection and the importance of its detection in healthcare application. It is expected that this review will be very helpful for readers to know the different conventional and recent detection techniques for sorbitol at a glance.

Alcohol Dehydrogenase: An Autoantibody Target in Patients with Alcoholic Liver Disease

The link between alcohol consumption and liver disease is not direct and several factors including autoimmunity to hepatocyte components have been implicated. We have previously identified alcohol dehydrogenase (ADH) as an autoantigen in autoimmune liver disease and in a proportion of patients with alcoholic liver disease. The aim of the present study is to investigate the association between the presence of anti-ADH antibodies, alcohol consumption and severity of liver damage in alcoholic patients. The presence of antibodies to human ADH β2 and horse ADH was investigated in 108 patients with documented history of alcohol consumption and alcohol related liver disease, 86 being active alcohol abusers and 22 on sustained alcohol withdrawal, 39 with non-alcohol related disease and 22 normal subjects.

Antibodies to either ADH form were more frequently detected in active alcohol abusers (55/86, 64%) than in patients on sustained alcohol withdrawal longer than 6 months (1/8, 13%, p<0.005), HBV infection (2/8, 25%, P=0.03), non-alcohol related disease (9/29, 23%, p<0.0001) and in normal controls (3/22, 14%, p<0.0001); were more frequent in patients with cirrhosis than in those with steatosis (26/34, 76% vs 34/64, 53%, P=0.02); and were associated with elevated levels of ALT (anti-ADH β2, p<0.05), immunoglobulin A (p<0.05) and γ-glutamyl transpeptidase (P=0.01). Anti-ADH antibody positive serum samples were able to inhibit the enzymatic activity of ADH. These findings suggest that anti-ADH antibodies may be triggered by alcohol consumption and act as a disease activity marker in alcoholic liver disease.

Alcohol dehydrogenase-specific T-cell responses are associated with alcohol consumption in patients with alcohol-related cirrhosis

Patients with alcohol-related liver disease (ALD) have antibodies directed to alcohol dehydrogenase (ADH), anti-ADH titers being associated with disease severity and active alcohol consumption. ADH-specific T-cell responses have not been characterized. We aimed to define anti-ADH cellular immune responses and their association with active alcohol consumption and disease severity. Using cultures of peripheral blood mononuclear cells (PBMCs) from 25 patients with alcohol-related cirrhosis (ARC; 12 were actively drinking or abstinent for <6 months, and 13 were abstinent for >6 months) and hepatic mononuclear cells (HMCs) from 14 patients with ARC who were undergoing transplantation, we investigated T-cell reactivity to 25 overlapping peptides representing the full human ADH protein (beta 1 subunit). ADH-specific peripheral T-cell responses were assessed by the quantification of T-cell proliferation and cytokine production and were correlated with the clinical course. In active alcohol consumers, proliferative T-cell responses targeted ADH31-95 and other discontinuous sequences in the ADH peptide, whereas only one sequence was targeted in abstinents. ADH peptides induced the production of interferon-γ (IFN-γ), interleukin-4 (IL-4), and IL-17. IL-4 production was lower in active drinkers versus abstinents, and IL-17 production was higher. Peptides inducing IFN-γ production outnumbered those inducing T-cell proliferation. The intensity of the predominantly T helper 1 (Th 1) responses directly correlated with disease severity. Similar to PBMCs in abstinents, ADH peptides induced weak T-cell proliferation and a similar level of IL-4 production in HMCs but less vigorous Th 1 and T helper 17 responses.

CONCLUSION

This suggests that Th 1 responses to ADH in ARC are induced by alcohol consumption. A Th 1/T helper 2 imbalance characterizes T-cell responses in active drinkers with ARC, whereas IL-4 production prevails in abstinents. This identifies new targets for immunoregulatory therapies in ALD patients for halting detrimental effector T-cell responses, which may encourage liver fibrogenesis and progression to end-stage liver disease.

A cold-active and thermostable alcohol dehydrogenase of a psychrotorelant from Antarctic seawater, Flavobacterium frigidimaris KUC-1

An NAD(+)-dependent alcohol dehydrogenase of a psychrotorelant from Antarctic seawater, Flavobacterium frigidimaris KUC-1 was purified to homogeneity with an overall yield of about 20% and characterized enzymologically. The enzyme has an apparent molecular weight of 160k and consists of four identical subunits with a molecular weight of 40k. The pI value of the enzyme and its optimum pH for the oxidation reaction were determined to be 6.7 and 7.0, respectively. The enzyme contains 2 gram-atoms Zn per subunit. The enzyme exclusively requires NAD(+) as a coenzyme and shows the pro-R stereospecificity for hydrogen transfer at the C4 position of the nicotinamide moiety of NAD(+). F. frigidimaris KUC-1 alcohol dehydrogenase shows as high thermal stability as the enzymes from thermophilic microorganisms. The enzyme is active at 0 to over 85 degrees C and the most active at 70 degrees C. The half-life time and k (cat) value at 60 degrees C were calculated to be 50 min and 27,400 min(-1), respectively. The enzyme also shows high catalytic efficiency at low temperatures (0-20 degrees C) (k(cat)/K(m) at 10 degrees C; 12,600 mM(-1)min(-1)) similar to other cold-active enzymes from psychrophiles. The alcohol dehydrogenase gene is composed of 1,035 bp and codes 344 amino acid residues with an estimated molecular weight of 36,823. The sequence identities were found with the amino acid sequences of alcohol dehydrogenases from Moraxella sp. TAE123 (67%), Pseudomonas aeruginosa (65%) and Geobacillus stearothermophilus LLD-R (56%). This is the first example of a cold-active and thermostable alcohol dehydrogenase.

Crystal structures of mouse class II alcohol dehydrogenase reveal determinants of substrate specificity and catalytic efficiency

The structure of mouse class II alcohol dehydrogenase (ADH2) has been determined in a binary complex with the coenzyme NADH and in a ternary complex with both NADH and the inhibitor N-cyclohexylformamide to 2.2 A and 2.1 A resolution, respectively. The ADH2 dimer is asymmetric in the crystal with different orientations of the catalytic domains relative to the coenzyme-binding domains in the two subunits, resulting in a slightly different closure of the active-site cleft. Both conformations are about half way between the open apo structure and the closed holo structure of horse ADH1, thus resembling that of ADH3. The semi-open conformation and structural differences around the active-site cleft contribute to a substantially different substrate-binding pocket architecture as compared to other classes of alcohol dehydrogenase, and provide the structural basis for recognition and selectivity of alcohols and quinones. The active-site cleft is more voluminous than that of ADH1 but not as open and funnel-shaped as that of ADH3. The loop with residues 296-301 from the coenzyme-binding domain is short, thus opening up the pocket towards the coenzyme. On the opposite side, the loop with residues 114-121 stretches out over the inter-domain cleft. A cavity is formed below this loop and adds an appendix to the substrate-binding pocket. Asp301 is positioned at the entrance of the pocket and may control the binding of omega-hydroxy fatty acids, which act as inhibitors rather than substrates. Mouse ADH2 is known as an inefficient ADH with a slow hydrogen-transfer step. By replacing Pro47 with His, the alcohol dehydrogenase activity is restored. Here, the structure of this P47H mutant was determined in complex with NADH to 2.5 A resolution. His47 is suitably positioned to act as a catalytic base in the deprotonation of the substrate. Moreover, in the more closed subunit, the coenzyme is allowed a position closer to the catalytic zinc. This is consistent with hydrogen transfer from an alcoholate intermediate where the Pro/His replacement focuses on the function of the enzyme.

Molecular divergence of lysozymes and alpha-lactalbumin

The vast number of proteins that sustain the currently living organisms have been generated from a relatively small number of ancestral genes that has involved a variety of processes. Lysozyme is an ancient protein whose origin goes back an estimated 400 to 600 million years. This protein was originally a bacteriolytic defensive agent and has been adapted to serve a digestive function on at least two occasions, separated by nearly 40 million years. The origins of the related goose type and T4 phage lysozyme that are distinct from the more common C type are obscure. They share no discernable amino acid sequence identity and yet they possess common secondary and tertiary structures. Lysozyme C gene also gave rise, after gene duplication 300 to 400 million years ago, to a gene that currently codes for alpha-lactalbumin, a protein expressed only in the lactating mammary gland of all but a few species of mammals. It is required for the synthesis of lactose, the sugar secreted in milk. alpha-Lactalbumin shares only 40% identity in amino acid sequence with lysozyme C, but it has a closer spatial structure and gene organization. Although structurally similar, functionally they are quite distinct. Specific amino acid substitutions in alpha-lactalbumin account for the loss of the enzyme activity of lysozyme and the acquisition of the features necessary for its role in lactose synthesis. Evolutionary implications are as yet unclear but are being unraveled in many laboratories.

Mycothiol-dependent formaldehyde dehydrogenase, a prokaryotic medium-chain dehydrogenase/reductase, phylogenetically links different eukaroytic alcohol dehydrogenases--primary structure, conformational modelling and functional correlations

Prokaryotic mycothiol-dependent formaldehyde dehydrogenase has been structurally characterized by peptide analysis of the 360-residue protein chain and by molecular modelling and functional correlation with the conformational properties of zinc-containing alcohol dehydrogenases. The structure is found to be a divergent medium-chain dehydrogenase/reductase (MDR), at a phylogenetic position intermediate between the cluster of dimeric alcohol dehydrogenases of all classes (including the human forms), and several tetrameric reductases/dehydrogenases. Molecular modelling and functionally important residues suggest a fold of the mycothiol-dependent formaldehyde dehydrogenase related overall to that of MDR alcohol dehydrogenases, with the presence of the catalytic and structural zinc atoms, but otherwise much altered active-site relationships compatible with the different substrate specificity, and an altered loop structure compatible with differences in the quaternary structure. Residues typical of glutathione binding in class-III alcohol dehydrogenase are not present, consistent with that the mycothiol factor is not closely similar to glutathione. The molecular architecture is different from that of the 'constant' alcohol dehydrogenases (of class-III type) and the 'variable' alcohol dehydrogenases (of class-I and class-II types), further supporting the unique structure of mycothiol-dependent formaldehyde dehydrogenase. Borders of internal chain-length differences between this and other MDR enzymes coincide in different combinations, supporting the concept of limited changes in loop regions within this whole family of proteins.

Characterization of the functional gene encoding mouse class III alcohol dehydrogenase (glutathione-dependent formaldehyde dehydrogenase) and an unexpressed processed pseudogene with an intact open reading frame

Multiple forms of vertebrate alcohol dehydrogenase (ADH) have been identified, but only one form, class III ADH, has been conserved in all organisms studied. Class III ADH functions in vitro as a glutathione-dependent formaldehyde dehydrogenase, which suggests that this was the original function that drove the evolution of ADH. Genetic analysis of class III ADH in yeast supports this view, but such studies are lacking in higher eukaryotes. The mouse ADH family has been previously analyzed and it contains three forms of ADH including the class III enzyme. We have initiated a molecular genetic analysis of the mouse class III ADH gene (Adh-2) by screening a genomic library with a full-length cDNA. Two overlapping clones contained the complete Adh-2 gene composed of nine exons in a 12-kb region, with the placement of introns matching that observed in other mammalian ADH genes. In this screening, we also isolated a clone (psi Adh-2) that lacks introns and which resembles a processed pseudogene. psi Adh-2 contained 25 point mutations relative to the previously analyzed Adh-2 cDNA, but still retained an intact open reading frame. Northern blot analysis using gene-specific probes provided evidence that psi Adh-2 does not produce a mRNA in either liver or kidney, whereas Adh-2 does. The functionality of the two genes was also compared by fusion of their 5'-flanking regions to a lacZ reporter gene. Reporter gene expression following transfection into mouse F9 embryonal carcinoma cells indicated that only Adh-2 possesses promoter activity.

Crystal structure of cod liver class I alcohol dehydrogenase: substrate pocket and structurally variable segments

The structural framework of cod liver alcohol dehydrogenase is similar to that of horse and human alcohol dehydrogenases. In contrast, the substrate pocket differs significantly, and main differences are located in three loops. Nevertheless, the substrate pocket is hydrophobic like that of the mammalian class I enzymes and has a similar topography in spite of many main-chain and side-chain differences. The structural framework of alcohol dehydrogenase is also present in a number of related enzymes like glucose dehydrogenase and quinone oxidoreductase. These enzymes have completely different substrate specificity, but also for these enzymes, the corresponding loops of the substrate pocket have significantly different structures. The domains of the two subunits in the crystals of the cod enzyme further differ by a rotation of the catalytic domains by about 6 degrees. In one subunit, they close around the coenzyme similarly as in coenzyme complexes of the horse enzyme, but form a more open cleft in the other subunit, similar to the situation in coenzyme-free structures of the horse enzyme. The proton relay system differs from the mammalian class I alcohol dehydrogenases. His 51, which has been implicated in mammalian enzymes to be important for proton transfer from the buried active site to the surface is not present in the cod enzyme. A tyrosine in the corresponding position is turned into the substrate pocket and a water molecule occupies the same position in space as the His side chain, forming a shorter proton relay system.

Linking of isozyme and class variability patterns in the emergence of novel alcohol dehydrogenase functions. Characterization of isozymes in Uromastix hardwickii

The nature of the isozyme differences in the class-I alcohol dehydrogenase structure from the lizard, Uromastix hardwickii, was determined and related to those in the human and horse enzymes, for which isozyme structures have also been established. The Uromastix isozymes differ much (at a total of 72 positions, 19%) but, in spite of this, have similar properties and were not obtained resolved. Their structures were analyzed in mixture, and the two sub-sets of peptides obtained could be distinguished by evaluation of the recovery ratios within the peptide pairs. The isozymes have class-I activities, with an ethanol dehydrogenase activity of 0.6 U/mg and no formaldehyde dehydrogenase activity, have typical class-I structures, and are composed of N-terminally acetylated 375-residue subunits (a and b). Importantly, variability patterns between the isozymes are reminiscent of those both in the other two lines with isozymes (primates and horse) and in the class distinctions of the enzyme. Hence, the variability pattern since the distant stage of class-I emergence is also visible within the more recent isozyme divergence, illustrating a continuity in the evolution of isozymes to classes (and then to enzymes). The pattern also links the different levels of multiplicity and may suggest an acceptability in common to duplications and mutations, compatible with the emergence of novel functions.

Liver class-I alcohol dehydrogenase isozyme relationships and constant patterns in a variable basic structure. Distinctions from characterization of an ethanol dehydrogenase in cobra, Naja naja

The major ethanol dehydrogenase of cobra liver was characterized in order to clarify isozyme relationships and functional motifs of the vertebrate enzyme. The cobra protein is a class-I form, most related to one of the isozyme subunits (the a form) in Uromastix (lizard) liver. This positions the isozyme duplication and defines the main-line alternative. The new structure also allows extensive correlations with structure/function relationships for alcohol dehydrogenases in general, of which 38 animal variants (still disregarding strain and allelic differences) now have been characterized. Architectural features are discerned, distinguishing the enzyme at large, the classes, and the functional interactions at the sites of substrate binding and coenzyme binding. Variability is greater at the substrate-binding site, with only one of 13 residues strictly conserved (His67, one of the active-site zinc ligands) but all other residues differing among and frequently within classes. However, many substrate-interacting residues are class preferential and may be used in predictive assignments. Class-I/III differences concern position 48 (typically Ser in class I, Thr in class III), position 93 (Phe versus Tyr), position 141 (branch-chained aliphatic residue versus methionine), position 57 (hydrophobic residue versus Asp), position 115 (Asp versus Arg), position 116 (Leu or Ile versus Val), position 306 (Met or Leu/Ile versus Phe), position 309 (Phe or Leu/Ile versus Val) and position 318 (Val or Ile versus Ala). In contrast, coenzyme binding is more conserved. A characteristic coenzyme-binging motif, covering only a 50-residue stretch, is defined as tVDiK (residues 178, 203, 223, 224, 228; capital letters for residues strictly conserved and small-cases letters for residues nearly so). This motif is class independent and unique to animal alcohol dehydrogenases. Therefore, the novel enzyme structure establishes class-I isozyme relationships, shows characteristic 'constant' residues also in the 'variable' class-I line, and defines residue-specific patterns which may have a predictive value in functional assignments of an increasing number of undefined further forms expected to result from gene projects.

Cloning of the mouse class IV alcohol dehydrogenase (retinol dehydrogenase) cDNA and tissue-specific expression patterns of the murine ADH gene family

Humans possess five classes of alcohol dehydrogenase (ADH), including forms able to oxidize ethanol or formaldehyde as part of a defense mechanism, as well as forms acting as retinol dehydrogenases in the synthesis of the regulatory ligand retinoic acid. However, the mouse has previously been shown to possess only three forms of ADH. Hybridization analysis of mouse genomic DNA using cDNA probes specific for each of the five classes of human ADH has now indicated that mouse DNA cross-hybridizes to only classes I, III, and IV. With human class II or class V ADH cDNA probes, hybridization to mouse genomic DNA was very weak or undetectable, suggesting either a lack of these genes in the mouse or a high degree of mutational divergence relative to the human genes. cDNAs for murine ADH classes I and III have previously been cloned, and we now report the cloning of a full-length mouse class IV ADH cDNA. In Northern blot analyses, mouse class IV ADH mRNA was abundant in the stomach, eye, skin, and ovary, thus correlating with the expression pattern for the mouse Adh-3 gene previously determined by enzyme analysis. In situ hybridization studies on mouse stomach indicated that class IV ADH transcripts were abundant in the mucosal epithelium but absent from the muscular layer. Comparison of the expression patterns for all three mouse ADH genes indicated that class III was expressed ubiquitously, whereas classes I and IV were differentially expressed in an overlapping set of tissues that all contain a large component of epithelial cells. This expression pattern is consistent with the ability of classes I and IV to oxidize retinol for the synthesis of retinoic acid known to regulate epithelial cell differentiation. The results presented here indicate that the mouse has a simpler ADH gene family than the human but has conserved class IV ADH previously shown to be a very active retinol dehydrogenase in humans.

Genomic structure and expression of the ADH7 gene encoding human class IV alcohol dehydrogenase, the form most efficient for retinol metabolism in vitro

Human alcohol dehydrogenase (ADH) consists of a family of five evolutionarily related classes of enzymes that collectively function in the metabolism of a wide variety of alcohols including ethanol and retinol. Class IV ADH has been found to be the most active as a retinol dehydrogenase, thus it may participate in retinoic acid synthesis. The gene encoding class IV ADH (ADH7) has now been cloned and subjected to molecular examination. Southern blot analysis indicated that class IV ADH is encoded by a single unique gene and has no related pseudogenes. The class IV ADH gene is divided into nine exons, consistent with the highly conserved intron/exon structure of other mammalian ADH genes. The predicted amino acid sequence of the exon coding regions indicates that a protein of 373 amino acids, excluding the amino-terminal methionine, would be translated, sharing greater sequence identity with class I ADH (69%) than with classes II, III or V (59-61%). Expression of class IV ADH mRNA was detected in human stomach but not liver. This correlates with previous protein studies, which have indicated that class IV ADH is the major stomach ADH but unlike other ADHs is absent from liver. Primer extension studies using human stomach RNA were performed to identify the transcription initiation site lying 100 base pairs upstream of the ATG translation start codon. Nucleotide sequence analysis of the promoter region indicated the absence of a TATA box sequence often located about 25 base pairs upstream of the start site as well as the absence of GC boxes, which are quite often seen in promoters lacking a TATA box. The class IV ADH promoter thus differs from the other ADH promoters, which contain either a TATA box (classes I and II) or GC-boxes (class III), suggesting a fundamentally different form of transcriptional regulation.

Alcohol dehydrogenase class III contrasted to class I. Characterization of the cyclostome enzyme, the existence of multiple forms as for the human enzyme, and distant cross-species hybridization

Alcohol dehydrogenases of classes I (the classical liver enzyme) and III (formaldehyde dehydrogenase) constitute a pair of moderately related enzymes (63% residue identity between the human forms) that differ fundamentally in many respects. To elucidate the nature of the differences, we have characterized alcohol dehydrogenase from the most primitive vertebrate line (a cyclostome, Atlantic Hagfish), related that to the multiplicity of the human enzyme, and submitted the enzymes to in vitro hybridization for evaluation of subunit interactions. Three findings illustrate important principles of the enzyme system. First, the alcohol dehydrogenase purified from cyclostomes is a class-III protein, compatible with the facts that cyclostomes constitute the earliest extant vertebrate line and that class III has a distant pre-vertebrate origin. Second, the hagfish enzyme shows multiplicity, with acidic forms in decreasing yield and with amino acid sequences identical between two major isoforms, both aspects constituting properties similar to those of the corresponding human forms. The chemically different subunits are present as homodimers and heterodimers of unmodified and modified subunits, suggesting that the class-III multiplicity derives from modification of a type common to lines as divergent as mammals and cyclostomes. Third, the human enzyme can form cross-species hybrid dimers in vitro with the cod and hagfish or Drosophila class-III enzymes (positional identity with the human form of 82, 76 and 70%, respectively). Hence, the results provide experimental evidence for little class-III divergence in the segments of subunit interactions. The extent of conservation of residues directly involved in the formation of the subunit interface also reveals a clearly different pattern between classes I and III. This highlights separation of divergent forms in an enzyme system, with the constant form (class III) resembling house-keeping enzymes, and exhibiting a correlation between subunit-interacting and substrate-interacting segments.

Fundamental molecular differences between alcohol dehydrogenase classes

Two types of alcohol dehydrogenase in separate protein families are the "medium-chain" zinc enzymes (including the classical liver and yeast forms) and the "short-chain" enzymes (including the insect form). Although the medium-chain family has been characterized in prokaryotes and many eukaryotes (fungi, plants, cephalopods, and vertebrates), insects have seemed to possess only the short-chain enzyme. We have now also characterized a medium-chain alcohol dehydrogenase in Drosophila. The enzyme is identical to insect octanol dehydrogenase. It is a typical class III alcohol dehydrogenase, similar to the corresponding human form (70% residue identity), with mostly the same residues involved in substrate and coenzyme interactions. Changes that do occur are conservative, but Phe-51 is of functional interest in relation to decreased coenzyme binding and increased overall activity. Extra residues versus the human enzyme near position 250 affect the coenzyme-binding domain. Enzymatic properties are similar--i.e., very low activity toward ethanol (Km beyond measurement) and high selectivity for formaldehyde/glutathione (S-hydroxymethylglutathione; kcat/Km = 160,000 min-1.mM-1). Between the present class III and the ethanol-active class I enzymes, however, patterns of variability differ greatly, highlighting fundamentally separate molecular properties of these two alcohol dehydrogenases, with class III resembling enzymes in general and class I showing high variation. The gene coding for the Drosophila class III enzyme produces an mRNA of about 1.36 kb that is present at all developmental stages of the fly, compatible with the constitutive nature of the vertebrate enzyme. Taken together, the results bridge a previously apparent gap in the distribution of medium-chain alcohol dehydrogenases and establish a strictly conserved class III enzyme, consistent with an important role for this enzyme in cellular metabolism.

Mammalian class IV alcohol dehydrogenase (stomach alcohol dehydrogenase): structure, origin, and correlation with enzymology

The structure of a mammalian class IV alcohol dehydrogenase has been determined by peptide analysis of the protein isolated from rat stomach. The structure indicates that the enzyme constitutes a separate alcohol dehydrogenase class, in agreement with the distinct enzymatic properties; the class IV enzyme is somewhat closer to class I (the "classical" liver alcohol dehydrogenase; approximately 68% residue identities) than to the other classes (II, III, and V; approximately 60% residue identities), suggesting that class IV might have originated through duplication of an early vertebrate class I gene. The activity of the class IV protein toward ethanol is even higher than that of the classical liver enzyme. Both Km and kcat values are high, the latter being the highest of any class characterized so far. Structurally, these properties are correlated with replacements at the active site, affecting both substrate and coenzyme binding. In particular, Ala-294 (instead of valine) results in increased space in the middle section of the substrate cleft, Gly-47 (instead of a basic residue) results in decreased charge interactions with the coenzyme pyrophosphate, and Tyr-363 (instead of a basic residue) may also affect coenzyme binding. In combination, these exchanges are compatible with a promotion of the off dissociation and an increased turnover rate. In contrast, residues at the inner part of the substrate cleft are bulky, accounting for low activity toward secondary alcohols and cyclohexanol. Exchanges at positions 259-261 involve minor shifts in glycine residues at a reverse turn in the coenzyme-binding fold. Clearly, class IV is distinct in structure, ethanol turnover, stomach expression, and possible emergence from class I.

Molecular characterization of microbial alcohol dehydrogenases

There is an astonishing array of microbial alcohol oxidoreductases. They display a wide variety of substrate specificities and they fulfill several vital but quite different physiological functions. Some of these enzymes are involved in the production of alcoholic beverages and of industrial solvents, others are important in the production of vinegar, and still others participate in the degradation of naturally occurring and xenobiotic aromatic compounds as well as in the growth of bacteria and yeasts on methanol. They can be divided into three major categories. (1) The NAD- or NADP-dependent dehydrogenases. These can in turn be divided into the group I long-chain (approximately 350 amino acid residues) zinc-dependent enzymes such as alcohol dehydrogenases I, II, and III of Saccharomyces cerevisiae or the plasmid-encoded benzyl alcohol dehydrogenase of Pseudomonas putida; the group II short-chain (approximately 250 residues) zinc-independent enzymes such as ribitol dehydrogenase of Klebsiella aerogenes; the group III "iron-activated" enzymes that generally contain approximately 385 amino acid residues, such as alcohol dehydrogenase II of Zymomonas mobilis and alcohol dehydrogenase IV of Saccharomyces cerevisiae, but may contain almost 900 residues in the case of the multifunctional alcohol dehydrogenases of Escherichia coli and Clostridium acetobutylicum. The aldehyde/alcohol oxidoreductase of Amycolatopsis methanolica and the methanol dehydrogenases of A. methanolica and Mycobacterium gasti are 4-nitroso-N,N-dimethylaniline-dependent nicotinoproteins. (2) NAD(P)-independent enzymes that use pyrroloquinoline quinone, haem or cofactor F420 as cofactor, exemplified by methanol dehydrogenase of Paracoccus denitrificans, ethanol dehydrogenase of Acetobacter and Gluconobacter spp. and the alcohol dehydrogenases of certain archaebacteria. (3) Oxidases that catalyze an essentially irreversible oxidation of alcohols, such as methanol oxidase of Hansenula polymorpha and probably the veratryl alcohol oxidases of certain fungi involved in lignin degradation. This review deals mainly with those enzymes for which complete amino acid sequences are available. The discussion focuses on a comparison of their primary, secondary, tertiary, and quaternary structures and their catalytic mechanisms. The physiological roles of the enzymes and isoenzymes are also considered, as are their probable evolutionary relationships.

Basic features of class-I alcohol dehydrogenase: variable and constant segments coordinated by inter-class and intra-class variability. Conclusions from characterization of the alligator enzyme

The enzymatic and structural properties of alligator liver alcohol dehydrogenase have been determined. Aliphatic and alicyclic alcohols serve as substrates for this first reptilian form of the enzyme characterized, with Km values decreasing rapidly from methanol to hexanol, as for the human class I enzymes, and a Km of 1.2 mM for ethanol at pH 9.9. The N-terminus of the 374-residue protein chain is acetyl-blocked. The enzyme is related in descending order to class I > III > V > II of the structurally characterized mammalian alcohol dehydrogenases. This observation is compatible with the presence of a I/III ancestral line. Differences of the enzyme classes exceed those of the species, suggesting an early origin of the classes. Within its enzyme class, the reptilian protein is most closely related to the avian form (82% residue identities), and is closer to the human than to the amphibian form (76%, versus 69%, respectively). This establishes class I alcohol dehydrogenase as an enzyme having fairly constant rate of change during much of vertebrate evolution, approximately 10% residue differences/100 million years of separation between pairs compared. Residues interacting with the substrate and coenzyme are largely conserved. In the alligator enzyme, there are only four replacements in the substrate pocket compared with the human class I gamma subunit, and those are not known to have functional roles. These properties account for the kinetic parameters, and suggest distinct metabolic functions for the class I enzyme in vertebrates. Comparisons of the enzymes of the different vertebrate lines reveal that segment patterns are characteristic features of the class I enzymes. Three segments are 'variable', while two are 'constant', and both these types of segment are identical with those of the classes. There is extensive variability in close proximity to the active site of the enzyme and this appears to constitute a fundamental property of class I liver alcohol dehydrogenases in general.

A synthetic peptide encompassing the binding site of the second zinc atom (the 'structural' zinc) of alcohol dehydrogenase

A 23-residue peptide was synthesized that incorporates the loop which binds the structural zinc atom of mammalian alcohol dehydrogenases and contributes, in part, to subunit interactions in the native enzyme. Neither the amino acid composition nor the sequence of the peptide resemble those of zinc fingers. The reduced peptide stoichiometrically binds zinc or cobalt to form stable complexes with a dissociation constant of the peptide/CO2+ complex of 2.1 microM at pH 7.5. EDTA disrupts the complex. The absorption and magnetic circular dichroic spectra of the cobalt-peptide are indicative of a tetrahedral coordination geometry, and are similar to those of the cobalt-substituted structural site of horse and human (beta 1 beta 1) liver alcohol dehydrogenases. Consequently, the synthetic peptide can serve as a model for the metal-binding segment of alcohol dehydrogenase and for studies of fundamental problems concerning protein/metal interactions.

Hydroperoxidic inhibitor of horse liver alcohol dehydrogenase activity, tightly bound to the enzyme-NAD+ complex, characteristically degrades the coenzyme

The strong inhibition of horse liver alcohol dehydrogenase (HLAD) by p-methylbenzyl hydroperoxide (XyHP) is only transient, XyHP behaves also as a pseudo-substrate of the enzyme and in the presence of NAD+, is degraded by HLAD to (as yet unidentified) non-inhibiting products while the NAD+ is converted to a derivative similar to the "NADX", originally observed in an analogous reaction of HLAD with hydrogen peroxide. The apparent KM for XyHP is approximately 10(4) times smaller than that for H2O2. The catalytic constant kcat for HLAD degradation of XyHP is two orders of magnitude less than that for ethanol dehydrogenation. XyHP inhibits both directions of the alcohol-aldehyde interconversion with equal potency. The first step of the inhibition mechanism is a tight binding of XyHP to the binary HLAD-NAD+ complex.

A human alcohol dehydrogenase gene (ADH6) encoding an additional class of isozyme

The human alcohol dehydrogenase (ADH; alcohol:NAD+ oxidoreductase, EC 1.1.1.1) gene family consists of five known loci (ADH1-ADH5), which have been mapped close together on chromosome 4 (4q21-25). ADH isozymes encoded by these genes are grouped in three distinct classes in terms of their enzymological properties. A moderate structural similarity is observed between the members of different classes. We isolated an additional member of the ADH gene family by means of cross-hybridization with the ADH2 (class I) cDNA probe. cDNA clones corresponding to this gene were derived from PCR-amplified libraries as well. The coding sequence of a 368-amino-acid-long open reading frame was interrupted by introns into eight exons and spanned approximately 17 kilobases on the genome. The gene contains a glucocorticoid response element at the 5' region. The transcript was detected in the stomach and liver. The deduced amino acid sequence of the open reading frame showed about 60% positional identity with known human ADHs. This extent of homology is comparable to interclass similarity in the human ADH family. Thus, the newly identified gene, which is designated ADH6, governs the synthesis of an enzyme that belongs to another class of ADHs presumably with a distinct physiological role.

Avian alcohol dehydrogenase: the chicken liver enzyme. Primary structure, cDNA-cloning, and relationships to other alcohol dehydrogenases

The major ethanol-active form of chicken liver alcohol dehydrogenase was characterized. The primary structure was determined by peptide analysis and, to a large part, was also deduced by cDNA analysis of a near full-length cDNA clone. The latter was detected by screening of a chicken liver cDNA library with antibodies raised against the purified dehydrogenase. The structure shows that the avian enzyme exhibits characteristics of the complex mammalian alcohol dehydrogenase system, tracing its origin and divergence, and allowing functional correlations. The chicken protein analyzed proves to be a class I alcohol dehydrogenase, with 74% residue identity to gamma chains of the human enzyme, a Km for ethanol of 0.5 mM and a Ki for 4-methyl pyrazole of 2.5 microM. Relationships to the other two classes are non-identical; residue exchanges towards the human classes increase in the order I less than III less than II, and human/chicken differences are less than inter-class differences. Consequently, the origins of the classes are more distant than the avian/mammalian separation. They reflect duplicatory events separated in time, and the lines that lead to present-day classes I and II deviate early. Integrated with the data for the quail enzyme, the structure of the chicken protein shows that within the avian enzymes the degree of variation is comparable to that within the mammalian class I enzymes, which are more variable than the class III forms. The coenzyme-binding and substrate-binding residues of this chicken alcohol dehydrogenase are largely identical to those in the mammalian class I counterparts. However, the subunit-interacting areas are more variable and suggest some relationships of the avian enzyme with both class I and III mammalian forms. One of the residues, Gly260 (mammalian class I numbering system), previously considered characteristic of all alcohol dehydrogenases, is replaced by Gln.

Multiplication of the class I alcohol dehydrogenase locus in mammalian evolution

Chromosomal DNA samples derived from various primates and other mammals (horse, sheep, rabbit, and mouse) were digested with restriction endonuclease and hybridized with a probe of the sixth exon of the human ADH gene, which is highly conserved in the class I alcohol dehydrogenase of these mammalian species. The copy number of the class I ADH gene in each species was estimated from the number of hybridized bands. Primate DNA samples showed three distinct bands in the blots of PstI digest and DraI digest. Moreover, most of the bands from primate DNA showed a similarity in size so as to allow us to assign the ADH1, ADH2, and ADH3 homologues in each species. In contrast, mouse has only one gene, and rabbit, sheep, and horse seem to have only two genes, for the class I ADH, which showed divergent hybridization bands. These results are consistent with the view that the human class I ADH gene cluster has been generated through gene multiplication events which occurred before the Catarrhini branch point in the course of primate evolution.

Comparison of three classes of human liver alcohol dehydrogenase. Emphasis on different substrate binding pockets

Conformational models of the three characterized classes of mammalian liver alcohol dehydrogenase were constructed using computer graphics based on the known three-dimensional structure of the E subunit of the horse enzyme (class I) and the primary structures of the three human enzyme classes. This correlates the substrate-binding pockets of the class I subunits (alpha, beta and gamma in the human enzyme) with those of the class II and III subunits (pi and chi, respectively) for three enzymes that differ in substrate specificity, inhibition pattern and many other properties. The substrate-binding sites exhibit pronounced differences in both shape and properties. Comparing human class I subunits with those of class II and III subunits there are no less than 8 and 10 replacements, respectively, out of 11 residues in the substrate pocket, while in the human class I isozyme variants, only 1-3 of these 11 positions differ. A single residue, Val294, is conserved throughout. The liver alcohol dehydrogenases, with different substrate-specificity pockets, resemble the patterns of other enzyme families such as the pancreatic serine proteases. The inner part of the substrate cleft in the class II and III enzymes is smaller than in the horse class I enzyme, because both Ser48 and Phe93 are replaced by larger residues, Thr and Tyr, respectively. In class II, the residues in the substrate pocket are larger in about half of the positions. It is rich in aromatic residues, four Phe and one Tyr, making the substrate site distinctly smaller than in the class I subunits. In class III, the inner part of the substrate cleft is narrow but the outer part considerably wider and more polar than in the class I and II enzymes. In addition, Ser (or Thr) and Tyr in class II and III instead of His51 may influence proton abstraction/donation at the active site.

Avian alcohol dehydrogenase. Characterization of the quail enzyme, functional interpretations, and relationships to the different classes of mammalian alcohol dehydrogenase

The primary structure of the major quail liver alcohol dehydrogenase was determined. It is a long-chain, zinc-containing alcohol dehydrogenase of the type occurring also in mammals and hence allows judgement of the gene duplications giving rise to the classes of the human alcohol dehydrogenase system. The avian form is most closely related to the class I mammalian enzyme (72-75% residue identity), least related to class II (60% identity), and intermediately related to class III (64-65% identity). This pattern distinguishes the mammalian enzyme classes and separates classes I and II in particular. In addition to the generally larger similarities with class I, the avian enzyme exhibits certain residue patterns otherwise typical of the other classes, including an extra Trp residue, present in both class II and III but not in class I, with a corresponding increase in the UV absorbance. The avian enzyme further shows that a Gly residue at position 260 previously considered strictly conserved in alcohol dehydrogenases can be exchanged with Lys. However, zinc-binding residues, coenzyme-binding residues, and to a large extent substrate-binding residues are unchanged in the avian enzyme, suggesting its functional properties to be related to those of the class I mammalian alcohol dehydrogenases. In contrast, the areas of subunit interactions in the dimers differ substantially. These results show that (a) the vertebrate enzyme classes are of distant origin, (b) the submammalian enzyme exhibits partly mixed properties in relation to the classes, and (c) the three mammalian enzyme classes are not as equidistantly related as initially apparent but suggest origins from two sublevels.

Active-site zinc ligands and activated H2O of zinc enzymes

The x-ray crystallographic structures of 12 zinc enzymes have been chosen as standards of reference to identify the ligands to the catalytic and structural zinc atoms of other members of their respective enzyme families. Universally, H2O is a ligand and critical component of the catalytically active zinc sites. In addition, three protein side chains bind to the catalytic zinc atom, whereas four protein ligands bind to the structural zinc atom. The geometry and coordination number of zinc can vary greatly to accommodate particular ligands. Zinc forms complexes with nitrogen and oxygen just as readily as with sulfur, and this is reflected in catalytic zinc sites having a binding frequency of His much greater than Glu greater than Asp = Cys, three of which bind to the metal atom. The systematic spacing between the ligands is striking. For all catalytic zinc sites except the coenzyme-dependent alcohol dehydrogenase, the first two ligands are separated by a "short-spacer" consisting of 1 to 3 amino acids. These ligands are separated from the third ligand by a "long spacer" of approximately 20 to approximately 120 amino acids. The spacer enables formation of a primary bidentate zinc complex, whereas the long spacer contributes flexibility to the coordination sphere, which can poise the zinc for catalysis as well as bring other catalytic and substrate binding groups into apposition with the active site. The H2O is activated by ionization, polarization, or poised for displacement. Collectively, the data imply that the preferred mechanistic pathway for activating the water--e.g., zinc hydroxide or Lewis acid catalysis--will be determined by the identity of the other three ligands and their spacing.

Cobalt(II)-substituted class III alcohol and sorbitol dehydrogenases from human liver

The catalytic zinc atoms in class III (chi) alcohol dehydrogenase (ADH) and sorbitol dehydrogenase (SDH) from human liver have been specifically removed and replaced by cobalt(II) with a new ultrafiltration technique. The electronic absorption spectrum of class III cobalt ADH (epsiolon 638 = 870 M-1 cm-1) is nearly identical with those of active site substituted horse EE and human class I (beta 1 beta 1) cobalt ADH. Thus, the coordination environment of the catalytic metal is strictly conserved in these enzymes. However, significant differences are noted when the spectra of class III ADH-coenzyme complexes are compared to the corresponding spectra of the horse enzyme. The spectrum of class III ADH.NADH is split into three bands, centered at 680, 638, and 562 nm. The class III ADH.NAD+ species resembles the alkaline form of the corresponding horse enzyme complex but without exhibiting the pH dependence of the latter. These spectral changes underscore the role of the coenzymes in differentially fine tuning the catalytic metal for its particular function in each ADH. The noncatalytic zinc of class III ADH exchanges with cobalt at pH 7.0. While 9 residues out of 15 in the loop surrounding the noncatalytic zinc of class III ADH differ from those of the class I ADH, the electronic absorption spectra of cobalt in the noncatalytic metal site of class III ADH establish that the coordination environment of this site is conserved as well. The spectrum of cobalt SDH differs significantly from those of cobalt ADHs.(ABSTRACT TRUNCATED AT 250 WORDS)

Variability within mammalian sorbitol dehydrogenases. The primary structure of the human liver enzyme

The primary structure of sorbitol dehydrogenase from human liver has been determined by peptide analysis in order to relate the variability of this enzyme to that of the others within the alcohol dehydrogenase family. The structure obtained reveals 355 residues with an acyl-blocked N-terminus and an unexpected microheterogeneity at position 237 (Gln/Leu). The residue identity between sheep and human liver sorbitol dehydrogenase is 89%. This variability is similar to that of class I alcohol dehydrogenases, but distinctly different from that of class III alcohol dehydrogenases, the structures of which are much more conserved. Consequently, class III alcohol dehydrogenase is thus far unique within this family of dehydrogenases, suggesting a particularly strict requirement for that structure. The variability within sorbitol dehydrogenase involves all segments of the molecule but is largely at surface positions and clusters in one such region, covering positions 214-240, corresponding to a segment of the coenzyme-binding domain. Ligands to the active-site zinc and most residues lining the coenzyme-binding and substrate-binding pockets are conserved. However, provided conformational models are reliable, a charge difference may affect the interactions at the inner part of the substrate pocket, another charge difference may affect the interdomain region, and a size difference the adenine pocket. The primary structure of human liver sorbitol dehydrogenase further shows that the absence of three of the four ligands to a second zinc atom present in alcohol dehydrogenases is a general property of sorbitol dehydrogenase.

Characteristics of mammalian class III alcohol dehydrogenases, an enzyme less variable than the traditional liver enzyme of class I

Class III alcohol dehydrogenase, whose activity toward ethanol is negligible, has defined, specific properties and is not just a "variant" of the class I protein, the traditional liver enzyme. The primary structure of the horse class III protein has now been determined, and this allows the comparison of alcohol dehydrogenases from human, horse, and rat for both classes III and I, providing identical triads for both these enzyme types. Many consistent differences between the classes separate the two forms as distinct enzymes with characteristic properties. The mammalian class III enzymes are much less variable in structure than the corresponding typical liver enzymes of class I: there are 35 versus 84 positional differences in these identical three-species sets. The class III and class I subunits contain four versus two tryptophan residues, respectively. This makes the differences in absorbance at 280 nm a characteristic property. There are also 4-6 fewer positive charges in the class III enzymes accounting for their electrophoretic differences. The substrate binding site of class III differs from that of class I by replacements at positions that form the hydrophobic barrel typical for this site. In class III, two to four of these positions contain residues with polar or even charged side chains (positions 57 and 93 in all species, plus positions 116 in the horse and 140 in the human and the horse), while corresponding intraclass variation is small. All these structural features correlate with functional characteristics and suggest that the enzyme classes serve different roles. In addition, the replacements between these triad sets illustrate further general properties of the two mammalian alcohol dehydrogenase classes.(ABSTRACT TRUNCATED AT 250 WORDS)

Alcohol dehydrogenase gene from Alcaligenes eutrophus: subcloning, heterologous expression in Escherichia coli, sequencing, and location of Tn5 insertions

The nucleotide sequence of the gene that encodes the fermentative, multifunctional alcohol dehydrogenase (ADH) in Alcaligenes eutrophus, and of adjacent regions on a 1.8-kilobase-pair PstI fragment was determined. From the deduced amino acid sequence, a molecular weight of 38,549 was calculated for the ADH subunit. The amino acid sequence reveals homologies from 22.3 to 26.3% with zinc-containing alcohol dehydrogenases from eucaryotic organisms (Schizosaccharomyces pombe, Zea mays, mouse, horse liver, and human liver). Most of the 22 amino acid residues, which are strictly conserved in this group of ADHs (H. Jörnvall, B. Persson, and J. Jeffery, Eur. J. Biochem. 167:195-201, 1987), either were present in the A. eutrophus enzyme or had been substituted by related amino acids. The A. eutrophus adh gene was transcribed in Escherichia coli only under the control of the lac promoter, but was not expressed by its own promoter. A sequence resembling the E. coli consensus promoter DNA sequence did not contain the invariant T, but a G, in the potential -10 region. In the transposon-induced mutants HC1409 and HC1421, which form ADH constitutively, the insertions of Tn5::mob were localized 56 and 66 base pairs, respectively, upstream of the presumptive translation initiation codon. In contrast to the promoter, the A. eutrophus ribosome-binding site with a GGAG Shine-Dalgarno sequence 6 base pairs upstream of the translation initiation codon was accepted by the E. coli translation apparatus. A stable hairpin structure, which may provide a transcription termination signal, is predicted to occur in the mRNA, with its starting point 21 base pairs downstream from the translation termination codon.

Benzyl alcohol dehydrogenase and benzaldehyde dehydrogenase II from Acinetobacter calcoaceticus. Substrate specificities and inhibition studies

The apparent Km and maximum velocity values of benzyl alcohol dehydrogenase and benzaldehyde dehydrogenase II from Acinetobacter calcoaceticus were determined for a range of alcohols and aldehydes and the corresponding turnover numbers and specificity constants were calculated. Benzyl alcohol was the most effective alcohol substrate for benzyl alcohol dehydrogenase. Perillyl alcohol was the second most effective substrate, and was the only non-aromatic alcohol oxidized. The other substrates of benzyl alcohol dehydrogenase were all aromatic in nature, with para-substituted derivatives of benzyl alcohol being better substrates than other derivatives. Coniferyl alcohol and cinnamyl alcohol were also substrates. Benzaldehyde was much the most effective substrate for benzaldehyde dehydrogenase II. Benzaldehydes with a single small substituent group in the meta or para position were better substrates than any other benzaldehyde derivatives. Benzaldehyde dehydrogenase II could also oxidize the aliphatic aldehydes hexan-1-al and octan-1-al, although poorly. Benzaldehyde dehydrogenase II was substrate-inhibited by benzaldehyde when the assay concentration exceeded approx. 10 microM. Benzaldehyde dehydrogenase II, but not benzyl alcohol dehydrogenase, exhibited esterase activity with 4-nitrophenyl acetate as substrate. Both benzyl alcohol dehydrogenase and benzaldehyde dehydrogenase II were inhibited by the thiol-blocking reagents iodoacetate, iodoacetamide, 4-chloromercuribenzoate and N-ethylmaleimide. Benzyl alcohol or benzaldehyde respectively protected against these inhibitions. NAD+ also gave some protection. Neither benzyl alcohol dehydrogenase nor benzaldehyde dehydrogenase II was inhibited by the metal-ion-chelating agents EDTA, 2,2'-bipyridyl, pyrazole or 2-phenanthroline. Neither enzyme was inhibited by a range of plausible metabolic inhibitors such as mandelate, phenylglyoxylate, benzoate, succinate, acetyl-CoA, ATP or ADP. Benzaldehyde dehydrogenase II was sensitive to inhibition by several aromatic aldehydes; in particular, ortho-substituted benzaldehydes such as 2-bromo-, 2-chloro- and 2-fluoro-benzaldehydes were potent inhibitors of the enzyme.

Rat liver alcohol dehydrogenase of class III. Primary structure, functional consequences and relationships to other alcohol dehydrogenases

The amino acid sequence of alcohol dehydrogenase of class III from rat liver (the enzyme ADH-2) has been determined. This type of structure is quite different from those of both the class I and the class II alcohol dehydrogenases. The rat class III structure differs from the rat and human class I structures by 133-138 residues (exact value depending on species and isozyme type); and from that of human class II by 132 residues. In contrast, the rat/human species difference within the class III enzymes is only 21 residues. The protein was carboxymethylated with iodo[2(14)C]acetate, and cleaved with CNBr and proteolytic enzymes. Peptides purified by exclusion chromatography and reverse-phase high-performance liquid chromatography were analyzed by degradation with a gas-phase sequencer and with the manual 4-N,N-dimethylaminoazobenzene-4'-isothiocyanate double-coupling method. The protein chain has 373 residues with a blocked N terminus. No evidence was obtained for heterogeneity. The rat ADH-2 enzyme of class III contains an insertion of Cys at position 60 in relation to the class I enzymes, while the latter alcohol dehydrogenase in rat (ADH-3) has another Cys insertion (at position 111) relative to ADH-2. The structure deduced explains the characteristic differences of the class III alcohol dehydrogenase in relation to the other classes of alcohol dehydrogenase, including a high absorbance, an anodic electrophoretic mobility and special kinetic properties. The main amino acid substitutions are found in the catalytic domain and in the subunit interacting segments of the coenzyme-binding domain, the latter explaining the lack of hybrid dimers between subunits of different classes. Several substitutions provide an enlarged and more hydrophilic substrate-binding pocket, which appears compatible with a higher water content in the pocket and hence could possibly explain the higher Km for all substrates as compared with the corresponding values for the class I enzymes. Finally the class III structure supports evolutionary relationships suggesting that the three classes constitute clearly separate enzymes within the group of mammalian zinc-containing alcohol dehydrogenases.

Regulation of gene expression of class I alcohol dehydrogenase by glucocorticoids

The effect of glucocorticoids on gene expression of rat class I alcohol dehydrogenase (ADH; alcohol:NAD+ oxidoreductase, EC 1.1.1.1) was investigated. A cDNA clone for the beta-subunit of human ADH (ADH2) was used to analyze class I ADH mRNA levels in rat hepatoma cells, which are known to contain a functional glucocorticoid receptor. RNA gel blot analysis of total cellular RNA isolated from these cells showed hybridization of the human ADH2 cDNA probe to a single approximately equal to 1500-base RNA species. Treatment of the cells with dexamethasone (0.1 nM to 1 microM) caused a dose-dependent increase in total cellular class I ADH mRNA levels by a factor of 2-4. Maximal levels were reached within 18-24 hr of treatment. This effect was reversible following withdrawal of dexamethasone. The glucocorticoid induction of class I ADH mRNA does not seem to require ongoing protein synthesis since treatment of the cells with cycloheximide did not affect the increase in class I ADH mRNA levels by dexamethasone. The human ADH2 gene contains both upstream and within the coding region sequence motifs that display homology with response elements of genes positively regulated by glucocorticoids. These data suggest a receptor-mediated transcriptional enhancement of the ADH2 gene as the mechanism of regulation. However, analysis of RNA decay in cells treated with actinomycin D indicates that the dexamethasone-induced increase in class I ADH mRNA might, at least in part, be due to enhanced ADH mRNA stability.

Interpreting the behavior of enzymes: purpose or pedigree?

To interpret the growing body of data describing the structural, physical, and chemical behaviors of biological macromolecules, some understanding must be developed to relate these behaviors to the evolutionary processes that created them. Behaviors that are the products of natural selection reflect biological function and offer clues to the underlying chemical principles. Nonselected behaviors reflect historical accident and random drift. This review considers experimental data relevant to distinguishing between nonfunctional and functional behaviors in biological macromolecules. In the first segment, tools are developed for building functional and historical models to explain macromolecular behavior. These tools are then used with recent experimental data to develop a general outline of the relationship between structure, behavior, and natural selection in proteins and nucleic acids. In segments published elsewhere, specific functional and historical models for three properties of enzymes--kinetics, stereospecificity, and specificity for cofactor structures--are examined. Functional models appear most suitable for explaining the kinetic behavior of proteins. A mixture of functional and historical models appears necessary to understand the stereospecificity of enzyme reactions. Specificity for cofactor structures appears best understood in light of purely historical models based on a hypothesis of an early form of life exclusively using RNA catalysis.

Expression in Escherichia coli of active human alcohol dehydrogenase lacking N-terminal acetylation

Human alcohol dehydrogenase (ADH, beta beta isozyme of class I) was expressed in Escherichia coli, purified to homogeneity, and characterized regarding N-terminal processing. The expression system was obtained by ligation of a cDNA fragment corresponding to the beta-subunit of human liver alcohol dehydrogenase into the vector pKK 223-3 containing the tac promoter. The enzyme, detected by Western-blot analysis and ethanol oxidizing activity, constituted up to 3% of the total amount of protein. Recombinant ADH was separated from E. coli ADH by ion-exchange chromatography and the isolated enzyme was essentially pure as judged by SDS-polyacrylamide gel electrophoresis and sequence analysis. The N-terminal sequence was identical to that of the authentic beta-subunit except that the N-terminus was non-acetylated, indicating a correct removal of the initiator methionine, but lack of further processing.