Molecular aspects of functional differences between alcohol and sorbitol dehydrogenases

Eklund, Hans; Horjales, E.; Jörnvall, Hans; Ci, Brändén; Jeffery, Jonathan

doi:10.1021/bi00348a025

Cited by 140 publications

(129 citation statements)

References 47 publications

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“…This is consistent with a nonessential role for the 3-hydroxyl, and lends strength to the concept that a hydroxyl group in this position interacts unfavourably with the nicotinamide ring of the coenzyme [26,29].…”

Section: R-lactaldehydesupporting

confidence: 80%

“…The presence of including (2R,3R)-2,3-butanediol, have been reported a primary hydroxyl group adjacent to the oxidation site to serve as substrates for the enzyme from human liver is considered essential for positioning the reactive 2- [27]. The present findings show that the presence of the hydroxyl at the catalytic zinc atom of SDH, probably C,H(OH) moiety per se is not essential, and the subby hydrogen bond formation between this functional strate specificity of sorbitol dehydrogenase can thus be group and the Glu-154 residue [26]. That l-deoxysorextended to include di-and trifunctional alcohols with bitol or monofunctional secondary alcohols like proa three-carbon chain.…”

Section: R-lactaldehydementioning

confidence: 49%

“…[NADH] = 100 ,uM. chain compounds, of a 1,2-dihydroxy compound [25,26]. The presence of including (2R,3R)-2,3-butanediol, have been reported a primary hydroxyl group adjacent to the oxidation site to serve as substrates for the enzyme from human liver is considered essential for positioning the reactive 2- [27].…”

Section: R-lactaldehydementioning

confidence: 99%

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Methylglyoxal and the polyol pathway

Lindstad

McKinley-McKee

1993

FEBS Letters

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Methylglyoxal, I,'-propanediol and glycerol are shown to be substrates for sheep liver sorbltol dehydrogenase. With 1,2-propanedlol the enzymecatalyzed reaction occurs specifically with the R(-)-enanttomer.The maximum veloctties and the specificity constants obtained for the three-carbon substrates are considerably lower than those reported previously for sorbitol, and suggest that rate-determmation is Imposed by catalytic steps other than the enzymecoenzyme product dissociation. The present findings are discussed m terms of substrate spectficity and stereospectfictty, and may indicate novel aspects of sorbttol dehydrogenase function m relation to glucose metabolism and diabetic pathogenests.

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Section: R-lactaldehydesupporting

confidence: 80%

Section: R-lactaldehydementioning

confidence: 49%

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Methylglyoxal and the polyol pathway

Lindstad

McKinley-McKee

1993

FEBS Letters

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“…It appears possible that longer and more hydrophobic substrate chains may be ncecessary for the class I11 enzymes to displace the enlarged water content thereby allowing for correct binding at the substrate-binding site. The explanation for the substrate specificity differences between class I11 and the enzyme of other classes may then, at least in part, derive from the effects of water molecules, in a manner similar to the effects implied in explaining the differentiation between ethanol and sorbitol at the active site of sorbitol dehydrogenase [28], or between methanol and larger substrates at the active site of horse liver alcohol dehydrogenase [38].…”

Section: Catalytic Domainmentioning

confidence: 94%

Rat liver alcohol dehydrogenase of class III

Julià

Parés

Jörnvall

1988

European Journal of Biochemistry

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The amino acid sequence of alcohol dehydrogenase of class I11 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 I1 alcohol dehydrogenases. The rat class I11 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 I1 by 132 residues. In contrast, the rat/human species difference within the class I11 enzymes is only 21 residues. The protein was carboxymethylated with iod0[2~~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 I11 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 I11 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 K , for all substrates as compared with the corresponding values for the class I enzymes. Finally the class I11 structure supports evolutionary relationships suggesting that the three classes constitute clearly separate enzymes within the group of mammalian zinc-containing alcohol dehydrogenases.Mammalian alcohol dehydrogenases (ADH) are zinc-containing enzymes with known relationships to similar enzymes in yeast, plants and other organisms [l -31. The horse enzyme constitutes the crystallographically investigated model enzyme [4] (recent review in [5]). The human enzymes form a complex system of three classes [6], which have all recently been characterized (summaries in [7 -91).

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“…Like alcohol dehydrogenase and apparently all known niembers of the family except l-crystallin (2), sorbitol dehydrogenase has zinc at the active site [4]. However, based on fitting the primary structure of sheep liver sorbitol dehydrogenase to the three-dimensional model of horse liver alcohol dehydrogenase, it has been proposed that the coordination of the catalytic zinc is different in the two enzymes; of the two cysteine ligands in alcohol dehydrogenase, one could be glutamic acid in sorbitol dehydrogenase, the third ligand in both cases being a histidine residue [5]. In relation to substrates, sorbitol dehydrogenase does not oxidize primary alcohols such as ethanol, while alcohol dehydrogenase essentially does not oxidize sorbitol [6 -81.…”

mentioning

confidence: 99%

Variability within mammalian sorbitol dehydrogenases

Karlsson

Maret

Auld

et al. 1989

European Journal of Biochemistry

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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 ramily. 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 I1 1 alcohol dehydrogenases, the structures of which are much more conserved. Consequently, class I11 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 surfacc 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 coenzymebinding 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 dchydrogenasc 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.Sorbitol dehydrogenase is distantly related to alcohol dehydrogenase and a member of an extended protein family [l], recently shown to also contain S-crystallin [2] and threonine dehydrogenase 131. Like alcohol dehydrogenase and apparently all known niembers of the family except l-crystallin (2), sorbitol dehydrogenase has zinc at the active site [4]. However, based on fitting the primary structure of sheep liver sorbitol dehydrogenase to the three-dimensional model of horse liver alcohol dehydrogenase, it has been proposed that the coordination of the catalytic zinc is different in the two enzymes; of the two cysteine ligands in alcohol dehydrogenase, one could be glutamic acid in sorbitol dehydrogenase, the third ligand in both cases being a histidine residue [5]. In relation to substrates, sorbitol dehydrogenase does not oxidize primary alcohols such as ethanol, while alcohol dehydrogenase essentially does not oxidize sorbitol [6 -81. Substrates and residues at some or all of the liganding positions also differ in the other proteins of the family [2, 31.The substantial lack of substrates common to alcohol and sorbitol dehydrogenases is noteworthy in view of the broad substrate specificity of alcohol dehydrogenases [9]. Thus, sorbitol dehydrogenase is of interest for the analysis of structure/ function and evolutionary relationships in the alcohol dehydrogenase family. Determination of the extent of variabi...

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Molecular aspects of functional differences between alcohol and sorbitol dehydrogenases

Cited by 140 publications

References 47 publications

Methylglyoxal and the polyol pathway

Methylglyoxal and the polyol pathway

Rat liver alcohol dehydrogenase of class III

Variability within mammalian sorbitol dehydrogenases

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