Dehydrogenase oxidative dehydrogenation

In order to assess the synthetic potential of enzymatic oxidations for organosilicon chemistry, the (hydroxyalkyl)silanes 95, 97 and 99 have been studied for their oxidation (dehydrogenation) with horse liver alcohol dehydrogenase (HLADH E.C. l.l.l.l)79. For this purpose, these compounds were incubated with HLADH in a TRIS-HC1 buffer/THF system in the presence of NAD+. As monitored spectrophotometrically (increase of absorbance of the NADH formed), the (2-hydroxyethyl)silane 97 and the (3-hydroxypropyl)silane 99 were better substrates for HLADH than ethanol, whereas the related (hydroxymethyl)silane 95 was not a substrate under the experimental conditions used. Interestingly, the corresponding carbon analogue 101 was found to be accepted by HLADH. On the other hand, the (2-hydroxyethyl)silane 97 was found to be a better... 

A single enzyme is sometimes capable of many various oxidations. In the presence of NADH (reduced nicotinamide adenine dinucleotide), cyclohexanone oxygenase from Acinetobacter NCIB9871 converts aldehydes into acids, formates of alcohols, and alcohols ketones into esters (Baeyer-Villiger reaction), phenylboronic acids into phenols sulfides into optically active sulfoxides and selenides into selenoxides [1034], Horse liver alcohol dehydrogenase oxidizes primary alcohols to acids (esters) [1035] and secondary alcohols to ketones [1036]. Horseradish peroxidase accomplishes the dehydrogenative coupling [1037] and oxidation of phenols to quinones [1038]. Mushroom polyphenol oxidase hydroxylates phenols and oxidizes them to quinones [1039]. 

Dehydrogenases/reductases involved in reactions of oxidation (dehydrogenation) and/or reduction (hydrogenation) are ... 

A modified form of P-oxidation is found in peroxisomes and leads to the formation of acetyl-CoA and H2O2 (from the flavoprotein-linked dehydrogenase step), which is broken down by catalase. Thus, this dehydrogenation in peroxisomes is not linked directly to phosphorylation and the generation of ATP. The system facilitates the oxidation of very long chain fatty acids (eg, Cjq, C22). These enzymes are induced by... 

Oxoreductases include enzymes such as dehydrogenases, oxidases and peroxidases which catalyse transformations such as oxidation of alcohols to carbonyls and dehydrogenation of functionalized alkanes to alkenes. 

The metabolite but-3-ene-l,2-diol (10.104, Fig. 10.24) is of particular interest since further oxidation by alcohol dehydrogenase yields reactive products such as a,)3-unsaturated ketones [166] [167], Dehydrogenation of the primary alcoholic group to the a-hydroxyaldehyde followed by fast rearrange-... 

The NAD /NADH concentration ratio in the cytosol of the liver is maintained at a value of about 1000 but oxidation of ethanol can lower this ratio by at least tenfold. Many dehydrogenase reactions are close to equilibrium so that, for those that react with NAD /NADH, the concentrations of all the other substrates and products will be affected by a change in the NAD /NADH concentration ratio. Hence, a decrease in the NAD /NADH concentration ratio will lower the concentration of the oxidised reactant and raise that of the reduced reactant of aU the dehydrogenation reactions in the cytosol ... 

The enzyme isocitrate dehydrogenase is one of the enzymes of the Krebs or citric acid cycle, a major feature in carbohydrate metabolism (see Section 15.3). This enzyme has two functions, the major one being the dehydrogenation (oxidation) of the secondary alcohol group in isocitric acid to a ketone, forming oxalosuccinic acid. This requires the cofactor NAD+ (see Section 11.2). For convenience, we are showing non-ionized acids here, e.g. isocitric acid, rather than anions, e.g. isocitrate. 

Dimethylhydrazine is metabolized by a sequence of oxidation steps, first dehydrogenation to azomethane, A -oxidation of this to azoxymethane and finally a C-oxidation to methylazoxymethanol (Fiala, 1975, 1977). This last metabolite decomposes to give the highly reactive methyldiazonium ion to which the carcinogenicity of the compound has been attributed. The sequential nature of these oxidation steps has been shown in the isolated perfused rat liver (Wolter Frank, 1982). Fiala (1977) showed that the C-oxidation of azoxymethane to methylazoxymethanol is catalysed by hepatic microsomes, while Schoental (1973) found that methylazoxymethanol was converted to the corresponding aldehyde by an NAD-dependent dehydrogenase. 

RGURE 7 An oxidation-reduction reaction. Shown here is the oxidation of lactate to pyruvate. In this dehydrogenation, two electrons and two hydrogen ions (the equivalent of two hydrogen atoms) are removed from C-2 of lactate, an alcohol, to form pyruvate, a ketone. In cells the reaction is catalyzed by lactate dehydrogenase and the electrons are transferred to a cofactor called nicotinamide adenine dinucleotide. This reaction is fully reversible pyruvate can be reduced by electrons from the cofactor. In Chapter 13 we discuss the factors that determine the direction of a reaction. 

Figure 16-6 shows schematically how the pyruvate dehydrogenase complex carries out the five consecutive reactions in the decarboxylation and dehydrogenation of pyruvate. Step CD is essentially identical to the reaction catalyzed by pyruvate decarboxylase (see Fig. 14-13c) C-l of pyruvate is released as C02, and C-2, which in pyruvate has the oxidation state of an aldehyde, is attached to TPP as a hydroxyethyl group. This first step is the slowest and therefore limits the rate of the overall reaction. It is also the point at which the PDH complex exercises its substrate specificity. In step (2) the hydroxyethyl group is oxidized to the level of a car-...

Linked oxidation and decarboxylation. Metabolic pathways often make use of oxidation of a (3-hydroxy acid to a (3-oxoacid followed by decarboxylation in the active site of the same enzyme. An example is conversion of L-malate to pyruvate (Eq. 13-45). The Mg2+ or Mn2+-dependent decarboxylating malic dehydrogenase that catalyzes the reaction is usually called the malic enzyme. It is found in most organisms.237-240 While a concerted decarboxylation and dehydrogenation may sometimes occur,241-242 the enzymes of this group appear usually to operate with bound oxoacid intermediates as in Eq. 13-45. 

Some enzymes contain bound NAD+ which oxidizes a substrate alcohol to facilitate a reaction step and is then regenerated. For example, the malolactic enzyme found in some lactic acid bacteria and also in Ascaris decarboxylates L-malate to lactate (Eq. 15-12). This reaction is similar to those of isocitrate dehydrogenase,110-112 6-phosphogluconate dehydrogenase,113 and the malic enzyme (Eq. 13-45)114 which utilize free NAD+ to first dehydrogenate the substrate to a bound oxoacid whose (3 carbonyl group facilitates decarboxylation. Likewise, the bound NAD+ of the malolactic... 

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