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

Transcriptional regulation of the gene encoding an alcohol dehydrogenase in the archaeon Sulfolobus solfataricus involves multiple factors and control elements

A transcriptionally active region has been identified in the 5' flanking region of the alcohol dehydrogenase gene of the crenarchaeon Sulfolobus solfataricus through the evaluation of the activity of putative transcriptional regulators and the role of the region upstream of the gene under specific metabolic circumstances. Electrophoretic mobility shift assays with crude extracts revealed protein complexes that most likely contain TATA box-associated factors. When the TATA element was deleted from the region, binding sites for both DNA binding proteins, such as the small chromatin structure-modeling Sso7d and Sso10b (Alba), and transcription factors, such as the repressor Lrs14, were revealed. To understand the molecular mechanisms underlying the substrate-induced expression of the adh gene, the promoter was analyzed for the presence of cis-acting elements recognized by specific transcription factors upon exposure of the cell to benzaldehyde. Progressive dissection of the identified promoter region restricted the analysis to a minimal responsive element (PAL) located immediately upstream of the transcription factor B-responsive element-TATA element, resembling typical bacterial regulatory sequences. A benzaldehyde-activated transcription factor (Bald) that specifically binds to the PAL cis-acting element was also identified. This protein was purified from heparin-fractionated extracts of benzaldehyde-induced cells and was shown to have a molecular mass of approximately 16 kDa. The correlation between S. solfataricus adh gene activation and benzaldehyde-inducible occupation of a specific DNA sequence in its promoter suggests that a molecular signaling mechanism is responsible for the switch of the aromatic aldehyde metabolism as a response to environmental changes.

Medium-chain dehydrogenases/reductases (MDR). Family characterizations including genome comparisons and active site modeling

Completed eukaryotic genomes were screened for medium-chain dehydrogenases/reductases (MDR). In the human genome, 23 MDR forms were found, a number that probably will increase, because the genome is not yet fully interpreted. Partial sequences already indicate that at least three further members exist. Within the MDR superfamily, at least eight families were distinguished. Three families are formed by dimeric alcohol dehydrogenases (ADH; originally detected in animals/plants), cinnamyl alcohol dehydrogenases (originally detected in plants) and tetrameric alcohol dehydrogenases (originally detected in yeast). Three further families are centred around forms initially detected as mitochondrial respiratory function proteins, acetyl-CoA reductases of fatty acid synthases, and leukotriene B4 dehydrogenases. The two remaining families with polyol dehydrogenases (originally detected as sorbitol dehydrogenase) and quinone reductases (originally detected as zeta-crystallin) are also distinct but with variable sequences. The most abundant families in the human genome are the dimeric ADH forms and the quinone oxidoreductases. The eukaryotic patterns are different from those of Escherichia coli. The different families were further evaluated by molecular modelling of their active sites as to geometry, hydrophobicity and volume of substrate-binding pockets. Finally, sequence patterns were derived that are diagnostic for the different families and can be used in genome annotations.

Recommended nomenclature for the vertebrate alcohol dehydrogenase gene family

The alcohol dehydrogenase (ADH) gene family encodes enzymes that metabolize a wide variety of substrates, including ethanol, retinol, other aliphatic alcohols, hydroxysteroids, and lipid peroxidation products. Studies on 19 vertebrate animals have identified ADH orthologs across several species, and this has now led to questions of how best to name ADH proteins and genes. Seven distinct classes of vertebrate ADH encoded by non-orthologous genes have been defined based upon sequence homology as well as unique catalytic properties or gene expression patterns. Each class of vertebrate ADH shares <70% sequence identity with other classes of ADH in the same species. Classes may be further divided into multiple closely related isoenzymes sharing >80% sequence identity such as the case for class I ADH where humans have three class I ADH genes, horses have two, and mice have only one. Presented here is a nomenclature that uses the widely accepted vertebrate ADH class system as its basis. It follows the guidelines of human and mouse gene nomenclature committees, which recommend coordinating names across species boundaries and eliminating Roman numerals and Greek symbols. We recommend that enzyme subunits be referred to by the symbol "ADH" (alcohol dehydrogenase) followed by an Arabic number denoting the class; i.e. ADH1 for class I ADH. For genes we recommend the italicized root symbol "ADH" for human and "Adh" for mouse, followed by the appropriate Arabic number for the class; i.e. ADH1 or Adh1 for class I ADH genes. For organisms where multiple species-specific isoenzymes exist within a class, we recommend adding a capital letter after the Arabic number; i.e. ADH1A, ADH1B, and ADH1C for human alpha, beta, and gamma class I ADHs, respectively. This nomenclature will accommodate newly discovered members of the vertebrate ADH family, and will facilitate functional and evolutionary studies.

Sorbitol dehydrogenase of Drosophila. Gene, protein, and expression data show a two-gene system

The Drosophila melanogaster sorbitol dehydrogenase (SDH) is characterized as a two-enzyme system of the medium chain dehydrogenase/reductase family (MDR). The SDH-1 enzyme has an enzymology with Km and kcat values an order of magnitude higher than those for the human enzyme but with a similar kcat/Km ratio. It is a tetramer with identical subunits of approximately 38 kDa. At the genomic level, two genes, Sdh-1 and Sdh-2, have a single transcriptional start site and no functional TATA box. Expression is greater in larvae and adults than in pupae, where it is very low. At all three stages, Sdh-1 constitutes the major transcript. Sdh-1 and Sdh-2 genes were located at positions 84E-F and 86D in polytene chromosomes. The deduced amino acid sequences of the two genes show 90% residue identity. Evaluation of the sequence and modeling of the structure toward that of class I alcohol dehydrogenase (ADH) show altered loop and gap arrangements as in mammalian SDH and establishes that SDH, despite gene multiplicity and larger variability than the "constant" ADH of class III, is an enzyme conserved over wide ranges.

Isozyme multiplicity with anomalous dimer patterns in a class III alcohol dehydrogenase. Effects on the activity and quaternary structure of residue exchanges at "nonfunctional" sites in a native protein

The isozymes of class III alcohol dehydrogenase/glutathione-dependent formaldehyde dehydrogenase from cod were characterized. They exhibited three unexpected properties of general interest. First, these dimeric isozymes, derived from two types of subunit (h and l, for high- and low-activity forms), were recovered from liver preparations in only the homodimeric ll and heterodimeric hl combinations. Dissociation and reassociation of the isolated hl form in vitro also resulted in lower yields of the hh than the ll homodimer, although class III subunits are usually freely associable over wide borders of divergence (human and Drosophila). The h and l primary structures show that both chain types are characteristic of class III enzymes, without large amino acid replacements at positions of known subunit interactions. Hence, the hh dimer partial restriction indicates nontraditional alterations at h-subunit interfaces. The structure provides a possible explanation, in the form of h-chain modifications that may influence the anchoring of a loop at positions of two potentially deamidative beta-aspartyl shifts at distant Asn-Gly structures. Second the ll and hl forms differ in enzymatic properties, having 5-fold different K(m) values for NAD+ at pH 8, different K(m) values for S-(hydroxymethyl)glutathione (10 versus 150 microM), and different specific activities (4.5 versus 41 units/mg), with ll resembling and hl deviating from human and other class III alcohol dehydrogenases. However, functional residues lining substrate and coenzyme pockets in the known conformations of homologous forms are largely identical in the two isozymes [only minor conservative exchanges of Val/Leu116, Val/Leu203, Ile/Val224, and Ile/Val269 (numbering system of the human class I enzyme)], again indicating effects from distantly positioned h-chain replacements. Third, the two isozymes differ a surprising amount in amino acid sequence (18%, the same as the piscine/ human difference), reflecting a remarkably old isozyme duplication or, more probably, discordant accumulation of residue exchanges with greater speed of evolution for one of the subunits (h chain) than is typical for the slowly evolving class III alcohol dehydrogenase.

Arabidopsis formaldehyde dehydrogenase. Molecular properties of plant class III alcohol dehydrogenase provide further insights into the origins, structure and function of plant class p and liver class I alcohol dehydrogenases

A glutathione-dependent formaldehyde dehydrogenase (class III alcohol dehydrogenase) has been characterized from Arabidopsis thaliana. This plant enzyme exhibits kinetic and molecular properties in common with the class III forms from mammals, with a K(m) for S-hydroxymethylglutathione of 1.4 microM, an anodic electrophoretic mobility (pI: 5.3-5.6) and a cross-reaction with anti-(rat class III alcohol dehydrogenase) antibodies. The enzyme structure, deduced from the cDNA sequence, fits into the complex system of alcohol dehydrogenases and shows that all life forms share the class III protein type. The corresponding mRNA is 1.4 kb and present in all plant organs; a single copy of the gene is found in the genome. The class III structural variability is different from that of the ethanol-active enzyme types in both vertebrates (class I) and plants (class P), although class P conserves more of the class III properties than class I does. Also the enzymatic properties differ between the two ethanol-active classes. Active-site variability and exchanges at essential residues (Leu/Gly57, Asp/Arg115) may explain the distinct kinetics. These patterns are consistent with two different metabolic roles for the ethanol-active enzymes, a more constant function, reduction of acetaldehyde during hypoxia, for class P, and a more variable function, the detoxication of alcohols and participation in metabolic conversions, for class I. A sequence motif, Pro-Xaa-Ile/Val-Xaa-Gly-His-Glu-Xaa-Xaa-Gly, common to all medium-chain alcohol dehydrogenases is defined.

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.