Lactate dehydrogenase reactions involving

L-Amino acid oxidase has been used to measure L-phenylalanine and involves the addition of a sodium arsenate-borate buffer, which promotes the conversion of the oxidation product, phenylpyruvic acid, to its enol form, which then forms a borate complex having an absorption maximum at 308 nm. Tyrosine and tryptophan react similarly but their enol-borate complexes have different absorption maxima at 330 and 350 nm respectively. Thus by taking absorbance readings at these wavelengths the specificity of the assay is improved. The assay for L-alanine may also be made almost completely specific by converting the L-pyruvate formed in the oxidation reaction to L-lactate by the addition of lactate dehydrogenase (EC 1.1.1.27) and monitoring the oxidation of NADH at 340 nm. 

Figure 6.1 Pathways involved in glucose oxidation by plant cells (a) glycolysis, (b) Krebs cycle, (c) mitochondrial cytochrome chain. Under anoxic conditions. Reactions 1, 2 and 3 of glycolysis are catalysed by lactate dehydrogenase, pyruvate decarboxylase and alcohol dehydrogenase, respectively. ATP and ADP, adenosine tri- and diphosphate NAD and NADHa, oxidized and reduced forms of nicotinamide adenine dinucleotide PGA, phosphoglyceraldehyde PEP, phosphoenolpyruvate Acetyl-CoA, acetyl coenzyme A FP, flavoprotein cyt, cytochrome e, electron. (Modified from Fitter and Hay, 2002). Reprinted with permission from Elsevier...

Amplification of the sensitivity of substrate or co-en me recycling is especially efficient in thermometric analysis since all the reactions involved frequently contribute to increasing the overall temperature change. One case in point is the determination of lactate or pyruvate by substrate recycling using co-immobilized lactate oxidase and lactate dehydrogenase [160]. 

Fig. 5.4. Two types of energy metabolism in cestodes. (a) Type 1 homolactate fermentation, (b) Type 2 Malate dismutation. Reaction 3 involves a carboxylation step decarboxylation occurs at 6, 7 and 10. Reducing equivalents are generated at reactions 6 and 7 one reducing equivalent is used at reaction 9. Thus, when the mitochondrial compartment is in redox balance and malate is the sole substrate, twice as much propionate as acetate is produced. Key 1, pyruvate kinase 2, lactate dehydrogenase 3, phosphoenolpyruvate carboxykinase 4, malate dehydrogenase 5, mitochondrial membrane 6 malic enzyme 7, pyruvate dehydrogenase complex 8, fumarase 9, fumarate reductase 10, succinate decarboxylase complex. indicates reactions at which ATP is synthesised from ADP cyt, cytosol mit, mitochondrion. (After Bryant Flockhart, 1986.)...

Enzyme catalyzed reactions have also been studied at the single molecule level. Earlier work involved measurement of beta-galactosidase activity in droplets after a 10-15 h incubation. In a recent study, detection of fluorescent product generated by individual molecules of lactate dehydrogenase after a 1 hr incubation has been achieved using capillary electrophoresis . The activity of individual molecules were reproducible but activity of different molecules showed a 5-fold range. The differences in activity were suggested to reflect differences in conformation. 

Scheme 11. Idealized sketch showing the electroen matic oxidation of L-lactate at gold modified electrode surfaces, (a) Lactate dehydrogenase bound to CB-terminated alkylthiol SAMs prepared by covalent attachment of CB to 3-mercaptopropionic acid SAM derivatized with 1,4-diaminobutane. The electroenzymatic oxidation of lactate is observed only in the presence of soluble coenzyme (NAD" ") and a redox mediator (phenazine methosulfate) [215]. (b) Lactate deh3tdrogenase bound to NAD-terminated alkylthiol SAMs prepared by covalent attachment of Af -(2-aminoethyl)-NAD to a cystamine SAM derivatized with pjrrroloquinoline quinone. The reconstituted enzyme is electrically wired to the electrode surface via two NAD" -binding pockets involved in the affinity-binding surface reaction [242].

Lactate dehydrogenase is a pyridine nucleotide oxidoreductase, a tetramer of 140 kD molecular weight, which has been extensively investigated (Bloxham et al., 1975 Eventoff et al., 1977). It catalyses the reversible oxidation of L-lactate to pyruvate using NAD+ as a coenzyme. The reaction scheme with a view of the active site with bound substrate and essential amino-acid side chains are depicted in Equation (3) and in Figure 17. The probable reaction mechanism, involving proton and hydride transfers,... 

It was discovered in 1958 that anaerobically grown yeast contains a form of lactate dehydrogenase which is different from the d- and L-lac-tate cytochrome c reductases of aerobic yeast (306, 319). The enzyme has been partially purified (320, 321), and shown to contain flavin (320-322). Gel filtration studies have suggested a molecular weight of about 100,000 (320, 321). Preparations of the enzyme oxidize several d-2-hydroxyacids to the respective keto acids in a reversible manner (320). For the forward reaction, ferricyanide, 2,6-dichloroindophenol, menadione, and methylene blue have been used as electron acceptors, and for the reverse reaction leucomethyl viologen and FMNHa are effective electron donors (320). A number of L-2-hydroxyacids and 2-keto acids have been shown to be competitive inhibitors. Oxalate, cyanide, o-phenanthro-line, and EDTA are also potent inhibitors (320, 321, 323, 324). The inhibition by metal chelators develops slowly and is reversed by addition of Zn, Co, Mn +, or Fe + (320, 323-326). Substrates prevent the inhibition by chelators at concentrations considerably lower than their respective Km values (327). It has been suggested that EDTA inactivation involves the removal of a metal, most probably Zn +, from the substrate binding site of the enzyme (325, 326, 328, 329). However, others have... 

Another approach involves the addition of lactate dehydrogenase to the reaction that reduces the pyruvate to lactate. In addition, the use of an ion exchange resin allows in situ product recovery of the product amine that reduces product inhibition of the transaminase. 

The immunoglobulins have been extensively studied by ITP (in serum and csf see Section 2.4.4) and in particular the subclasses of IgG have been studied (H8, HIO, Hll, Z3). An extension of this work has been the demonstration of soluble immune complex formation in vitro (H9), which has obvious implications, particularly for the assessment of immune complex diseases. Preparative work has involved the isolation of, for example, antibodies to pig lactate dehydrogenase (B21, PI) and IgD myeloma protein (Jl). ITP has also been applied in the field of en-zymology, not for the direct measurement of enzymes as proteins, but for the determination of enzyme reaction substrates and products, and hence has been of use in enzyme kinetics. This work is summarized in Table 1. 

Figure 22.5 An example of reactions involved in an enzyme-catalyzed recycling processes for amplification of the sensitivity. In the left part (A) of the figure the enzyme-pair hexokinase and pyruvate kinase is used for recycling of the coenzyme ATP/ADP. In the right part (B), substrate recycling of pymvate or lactate is accomplished using the enzyme-pair lactate oxidase/lactate dehydrogenase. A multiplication effect is obtained by combination of A and B resulting in a very high sensitivity [27], The calorimetric sensitivity is further inreased by including catalase (cat).

Both in eukaryotic cells and in lactic acid bacteria, the mechanisms involves pyruvate being reduced to lactate. The enzyme catalyzing this reaction is lactate dehydrogenase. The equilibrium for this reaction lies far in favor of formation of lactate. 

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