Alcohol dehydrogenase kinetics

Von Wartburg JP, Bethune JL, Vallee BL. Human liver alcohol dehydrogenase. Kinetic and physicochemical properties. Biochemistry 1964 3 1775-1782. 

TABLE 1. Alcohol dehydrogenases, kinetic parameters of hexanal... 

In zero-orrler kinetics, a constant amount of a chemical compound is excreted per unit of rime. In most cases, this phenomenon is caused by the saturation of a rate-limiting enzyme, and the enzyme commonly functions at its maximal rate, i.e., a constant amount of a chemical compound is metabolized per unit time. A good example is ethyl alcohol alcohol dehydrogenase becomes saturated at relatively low concentrations. Because of this saturation, ethyl alcohol is eliminated at a constant rate about 7 g/h. However, rhe reason is not always an enzyme anv... 

Alcohol dehydrogenase is a cytoplasmic enzyme mainly found in the liver, but also in the stomach. The enzyme accomplishes the first step of ethanol metabolism, oxidation to acetaldehyde, which is further metabolized by aldehyde dehydrogenase. Quantitatively, the oxidation of ethanol is more or less independent of the blood concentration and constant with time, i.e. it follows zero-order kinetics (pharmacokinetics). On average, a 70-kg person oxidizes about 10 ml of ethanol per hour. 

In addition to enzyme activity, the concentration of an nonelectroactive substrate can be determined electrochemically by this technique. By keeping the substrate (analyte) the limiting reagent, the amount of product produced is directly related to the initial concentration of substrate. Either kinetic or equilibrium measurements can be used. Typically an enzyme which produces NADH is used because NADH is readily detected electrochemically. Lactate has been detected using lactate dehydrogenase, and ethanol and methanol detected using alcohol dehydrogenase... 

Rhin(bpy)3]3+ and its derivatives are able to reduce selectively NAD+ to 1,4-NADH in aqueous buffer.48-50 It is likely that a rhodium-hydride intermediate, e.g., [Rhni(bpy)2(H20)(H)]2+, acts as a hydride transfer agent in this catalytic process. This system has been coupled internally to the enzymatic reduction of carbonyl compounds using an alcohol dehydrogenase (HLADH) as an NADH-dependent enzyme (Scheme 4). The [Rhin(bpy)3]3+ derivative containing 2,2 -bipyridine-5-sulfonic acid as ligand gave the best results in terms of turnover number (46 turnovers for the metal catalyst, 101 for the cofactor), but was handicapped by slow reaction kinetics, with a maximum of five turnovers per day.50... 

Roth R, Boudet AM, Pont-Lezica R. Lignification and cinnamyl alcohol dehydrogenase activity in developing stems of tomato and popular a spatial and kinetic study through tissue printing. J Exp Bot 1997 48 247-254. 

TABLE 4.1 Kinetic Parameters for the Oxidation of Alcohols by Alcohol Dehydrogenase... 

In the following year, Cleland and his coworkers reported further and more emphatic examples of the phenomenon of exaltation of the a-secondary isotope effects in enzymic hydride-transfer reactions. The cases shown in Table 1 for their studies of yeast alcohol dehydrogenase and horse-liver alcohol dehydrogenase would have been expected on traditional grounds to show kinetic isotope effects between 1.00 and 1.13 but in fact values of 1.38 and 1.50 were found. Even more impressively, the oxidation of formate by NAD was expected to exhibit an isotope effect between 1.00 and 1/1.13 = 0.89 - an inverse isotope effect because NAD" was being converted to NADH. The observed value was 1.22, normal rather than inverse. Again the model of coupled motion, with a citation to Kurz and Frieden, was invoked to interpret the findings. 

The best-known exception to exponential kinetics is the elimination of alcohol (ethanol), which obeys a linear time course (zero-order kinetics), at least at blood concentrations > 0.02 %. It does so because the rate-limiting enzyme, alcohol dehydrogenase, achieves half-saturation at very low substrate concentrations, i.e at about 80 mg/L (0.008 %). Thus, reaction velocity reaches a plateau at blood ethanol concentrations of about 0.02 %, and the amount of drug eliminated per unit of time remains constant at concentrations above this level. 

The rate of ethanol degradation in the liver is limited by alcohol dehydrogenase activity. The amount of NAD" available is the limiting factor. As the maximum degradation rate is already reached at low concentrations of ethanol, the ethanol level therefore declines at a constant rate (zero-order kinetics). The calorific value of ethanol is 29.4 kj g Alcoholic drinks—particularly in alcoholics—can therefore represent a substantial proportion of dietary energy intake. 

This zinc metalloenzyme [EC 1.1.1.1 and EC 1.1.1.2] catalyzes the reversible oxidation of a broad spectrum of alcohol substrates and reduction of aldehyde substrates, usually with NAD+ as a coenzyme. The yeast and horse liver enzymes are probably the most extensively characterized oxidoreductases with respect to the reaction mechanism. Only one of two zinc ions is catalytically important, and the general mechanistic properties of the yeast and liver enzymes are similar, but not identical. Alcohol dehydrogenase can be regarded as a model enzyme system for the exploration of hydrogen kinetic isotope effects. 

Isotope effects have also been applied extensively to studies of NAD+/NADP+-linked dehydrogenases. We typically treat these enzymes as systems whose catalytic rates are limited by product release. Nonetheless, Palm clearly demonstrated a primary tritium kinetic isotope effect on lactate dehydrogenase catalysis, a finding that indicated that the hydride transfer step is rate-contributing. Plapp s laboratory later demonstrated that liver alcohol dehydrogenase has an intrinsic /ch//cd isotope effect of 5.2 with ethanol and an intrinsic /ch//cd isotope effect of 3-6-4.3 with benzyl alcohol. Moreover, Klin-man reported the following intrinsic isotope effects in the reduction of p-substituted benzaldehydes by yeast alcohol dehydrogenase kn/ko for p-Br-benzaldehyde = 3.5 kulki) for p-Cl-benzaldehyde = 3.3 kulk for p-H-benzaldehyde = 3.0 kulk for p-CHs-benzaldehyde = 5.4 and kn/ko for p-CHsO-benzaldehyde = 3.4. 

Ethanol is metabolized primarily in the liver by at least two enzyme systems. The best-studied and most important enzyme is zinc dependent alcohol dehydrogenase. Salient features of the reaction can be seen in Fig. 35.1. The rate of metabolism catalyzed by alcohol dehydrogenase is generally linear with time except at low ethanol concentrations and is relatively independent of the ethanol concentration (i.e., zero-order kinetics). The rate of metabolism after ingestion of different amounts of ethanol is illustrated in Fig. 35.2. 

Horse liver alcohol dehydrogenase (HLADH (E.C. 1.1.1.1), commercially available) is a well-documented enzyme capable of catalyzing the enantioselective oxidation of acyclic and cyclic meso-configurated dimethanol derivatives to chiral lactols and further to the corresponding chiral lactones with high enantioselectivity and in high yield (Table 11) 162 ,69. Incases where the two enantiomeric lactols are formed, a kinetic enantiomer separation can occur in the second oxidation step166. 

Kemper and Elfarra (1996) demonstrated the oxidation of butenediol by hepatic alcohol dehydrogenase (ADH), yielding 1-hydroxy-2-butanone as a single stable metabolite various intermediates have been proposed. For the ADH-dependent oxidation of racemic butenediol in liver cytosol of male B6C3Fj mice, male Sprague-Dawley rats and three humans, saturation kinetics were found. The ratio was similar in these... 

For example, liver alcohol dehydrogenase was crystallized as the enzyme N AD1 p-bromobenzyl alcohol complex with saturating concentrations of substrates in an equilibrium mixture51b and studied at low resolution. Transient kinetic studies or direct spectroscopic determinations led to the conclusion that the internal equilibrium (E NAD alcohol = E NADH aldehyde) favors the NAD1 alcohol complex.52 Subsequently, the complex was studied at higher resolution, and the basic structural features were confirmed with a... 

The reduction of ( )-2-, ( )-3- and ( )-4-cinnamoylpyridines by 1,4-dihydropyridines to give dihydro ketones has also been shown to be catalyzed by zinc(II) and magnesium(II).527 Kinetic measurements show that the rate of reduction is fastest in the case of the 2-isomer where the metal is simultaneously complexed with the nitrogen and oxygen donors. A very fast zinc-catalyzed reduction of pyridine-2-carbaldehyde by the alcohol dehydrogenase coenzyme model JV,JV -diethyl-N-benzyl-l,4-dihydronicotinamide (170) has also been described.528... 

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