Aldehyde dehydrogenase

About: Aldehyde dehydrogenase is a research topic. Over the lifetime, 3365 publications have been published within this topic receiving 107683 citations.

Kinetics and specificity of human liver aldehyde dehydrogenases toward aliphatic, aromatic, and fused polycyclic aldehydes.

Abstract: Human mitochondrial aldehyde dehydrogenase (ALDH-2) has a Km for acetaldehyde that is 900-fold lower than that for the cytosolic isozyme, ALDH-1. An increase in aliphatic aldehyde chain length decreases the ALDH-2 Km by up to 10-fold but decreases that of ALDH-1 by 5 orders of magnitude. As a consequence, the Km of ALDH-1 for decanal is 8 times lower than that of ALDH-2, i.e. 2.9 +/- 0.4 and 22 +/- 3 nM, respectively. Determination of these low Km values required kinetic analysis of the simultaneous enzymatic conversion of two aldehyde substrates, an approach also applied to aromatic and fused polycyclic aldehydes. For most of these substrates, maximum velocities are 5-100 times lower than those for acetaldehyde. Addition of one of these tight-binding, slow-turnover substrates to a reaction mixture containing ALDH, NAD+, and a "reference" aldehyde substrate (e.g. acetaldehyde) blocks the principal (reference) enzymatic reaction temporarily and reversibly. Once the first substrate is converted to product, the enzyme can act on the reference substrate. In terms of apparent affinity and blocking capacity, naphthalene and phenanthrene aldehydes were the most potent effectors. Other aromatic and fused polycyclic and heterocyclic aldehydes, as well as derivatives of coumarin, quinoline, indole, and pyridine, are tight-binding, slow-turnover substrates for ALDH-2 and relatively weak inhibitors of ALDH-1. The hydrophobicity of substituents of benzaldehydes, and particularly of naphthaldehydes, correlates with their binding constants toward ALDH-2. Vitamin A1 aldehydes are specific natural substrates for ALDH-1; at pH 7.5, for all-trans- and 13-cis-retinal, Km = 1.1 and 0.37 micromolar, respectively, and kcat/Km is 50-100 times higher than that for acetaldehyde. At the same time, the retinals are inhibitors of ALDH-2, all-trans-retinal being a particularly potent inhibitor (competitive Ki = 43 nM, noncompetitive Ki = 316 nM). These properties suggest that all-trans-retinal is a possible regulatory compound for ALDH-2 in vivo. The data in general point to specialized roles for both major human liver ALDH isozymes in the oxidation of bulky/hydrophobic natural compounds, with Km values in the low nanomolar range.

Coenzyme isomerization is integral to catalysis in aldehyde dehydrogenase

Abstract: Crystal structures of many enzymes in the aldehyde dehydrogenase superfamily determined in the presence of bound NAD(P)+ have exhibited conformational flexibility for the nicotinamide half of the cofactor. This has been hypothesized to be important in catalysis because one conformation would block the second half of the reaction, but no firm evidence has been put forth which shows whether the oxidized and reduced cofactors preferentially occupy the two observed conformations. We present here two structures of the wild type and two structures of a Cys302Ser mutant of human mitochondrial aldehyde dehydrogenase in binary complexes with NAD+ and NADH. These structures, including the Cys302Ser mutant in complex with NAD+ at 1.4 A resolution and the wild-type enzyme in complex with NADH at 1.9 A resolution, provide strong evidence that bound NAD+ prefers an extended conformation ideal for hydride transfer and bound NADH prefers a contracted conformation ideal for acyl−enzyme hydrolysis. Unique interactions betw...

Retinal oxidation activity and biological role of human cytosolic aldehyde dehydrogenase.

Abstract: The major cytosolic aldehyde dehydrogenase isozyme (ALDH1) exhibits strong activity for oxidation of retinal to retinoic acid, while the major mitochondrial ALDH2 and the stomach cytosolic ALDH3 have no such activity. The Km of ALDH1 for retinal is about 0.06 mumol/l at pH 7.5, and the catalytic efficiency (Vmax/Km) for retinal is about 600 times higher than that for acetaldehyde. Thus, ALDH1 can efficiently produce retinoic acid from retinal in tissues with low retinal concentrations (< 0.01 mumol/l). The gene for ALDH1 has hormone response elements. These findings suggest that the major physiological substrate of human ALDH1 is retinal, and that its primary biological role is generation of retinoic acid resulting in modulation of cell differentiation including hormone-mediated development.

Alcohol sensitivity related to polymorphism of alcohol-metabolizing enzymes in Japanese.

Abstract: Normal Japanese subjects were divided into two groups, ie, one with both low and high Km isozymes of aldehyde dehydrogenase for acetaldehyde, and the other deficient in the low Km isozyme After intake of 04 g/kg alcohol, the deficient subjects showed high level of blood acetaldehyde, facial flushing and the other dysphoric symptoms, including increase of pulse rate, decrease of diastolic blood pressure, changes of pulse wave in the fingertip, and elevation of the arterial pressure and blood flow rate in common carotid arteries as well as increase of plasma catecholamines level In contrast, subjects with normal ALDH did not show these changes From the observation of liver specimens obtained at autopsy, the frequency of deficient phenotype of ALDH in Japanese was presumed to be about 36%