Oxidation-reduction enzyme activities

The cell metabolism is based on the oxidation-reduction enzyme activity. These enzymes are called oxidoreductases and divided into the following groups ... 

The essentiality of copper arises from its specific incorporation into a large number of enzymatic and structural proteins. The role of copper in oxidation-reduction enzyme activities is the consequence of its ability to function as an electron transfer intermediate. Thus, copper is present in enzymes involved in cellular respiration, free radical defense, neurotransmitter function, connective tissue biosynthesis, and cellular iron metabolism. 

The first examples of mechanism must be divided into two principal classes the chemistry of enzymes that require coenzymes, and that of enzymes without cofactors. The first class includes the enzymes of amino-acid metabolism that use pyridoxal phosphate, the oxidation-reduction enzymes that require nicotinamide adenine dinucleotides for activity, and enzymes that require thiamin or biotin. The second class includes the serine esterases and peptidases, some enzymes of sugar metabolism, enzymes that function by way of enamines as intermediates, and ribonuclease. An understanding of the mechanisms for all of these was well underway, although not completed, before 1963. 

The answer is b. (Murray, pp 627-661. Scriver, pp 3897-3964. Sack, pp 121-138. Wilson, pp 287-320.) Nicotinamide adenine dinucleotide (NAD+) is the functional coenzyme derivative of niacin. It is the major electron acceptor in the oxidation of molecules, generating NADH, which is the major electron donor for reduction reactions. Thiamine (also known as vitamin Bi) occurs functionally as thiamine pyrophosphate and is a coenzyme for enzymes such as pyruvate dehydrogenase. Riboflavin (vitamin B2) functions in the coenzyme forms of flavin mononucleotide (FMN) or flavin adenine dinucleotide (FAD). When concentrated, both have a yellow color due to the riboflavin they contain. Both function as prosthetic groups of oxidation-reduction enzymes or flavoproteins. Flavoproteins are active in selected oxidation reactions and in electron transport, but they do not have the ubiquitous role of NAD+. 

Tabushi s interest in biomimetic processes extended also to oxidation-reduction enzymes. His success in this field can be gauged from these quotations taken from an article published in Japan Chemical Week (April 17, 1986) under the heading Efficient Proc. for Oxygen Activation Pioneered . 

Disulfides. As shown in Figure 4, the and h-chains of insulin are connected by two disulfide bridges and there is an intrachain cycHc disulfide link on the -chain (see Insulin and other antidiabetic drugs). Vasopressin [9034-50-8] and oxytocin [50-56-6] also contain disulfide links (48). Oxidation of thiols to disulfides and reduction of the latter back to thiols are quite common and important in biological systems, eg, cysteine to cystine or reduced Hpoic acid to oxidized Hpoic acid. Many enzymes depend on free SH groups for activation—deactivation reactions. The oxidation—reduction of glutathione (Glu-Cys-Gly) depends on the sulfhydryl group from cysteine. 

Identification, isolation, and removal of (polyhydroxy)benzenes from the environment have received increased attention throughout the 1980s and 1990s. The biochemical activity of the benzenepolyols is at least in part based on thek oxidation—reduction potential. Many biochemical studies of these compounds have been made, eg, of enzymic glycoside formation, enzymic hydroxylation and oxidation, biological interactions with biochemically important compounds such as the catecholamines, and humic acid formation. The range of biochemical function of these compounds and thek derivatives is not yet fully understood. 

The reactions of carbon dichalcogenides other than C02 with Ni° have also been studied quite intensively.2460,2461 Inter alia, Ni polymeric complexes with metallic properties have been prepared using CS2 as the starting material.2462 Some further impetus was given by the observation that CS2 can mimic the binding of CO to the CODH enzyme active site, although CS2 itself does not undergo oxidation/reduction and does not appear to bind to center C (the site of CO oxidation and C02 reduction).2463... 

The activity of PK and NRPSs is often precluded and/or followed by actions upon the natural products by modifying enzymes. There exists a first level of diversity in which the monomers for respective synthases must be created. For instance, in the case of many NRPs, noncanonical amino acids must be biosynthesized by a series of enzymes found within the biosynthetic gene cluster in order for the peptides to be available for elongation by the NRPS. A second level of molecular diversity comes into play via post-synthase modification. Examples of these activities include macrocyclization, heterocyclization, aromatization, methylation, oxidation, reduction, halogenation, and glycosylation. Finally, a third level of diversity can occur in which molecules from disparate secondary metabolic pathways may interact, such as the modification of a natural product by an isoprenoid oligomer. Here, we will cover only a small subsection of... 

Electrochemical cofactor reduction can be achieved by direct reduction of the cofactor at the electrode surface, or indirectly by using a mediator molecule to shuttle electrons between the electrode and the cofactor. For details on the direct approach the reader is referred elsewhere [31, 32], since here no transition-metal complexes are involved. One point to be considered in the direct approach is the issue of selectivity. Whereas direct cofactor oxidation can be successfully achieved, special care must be taken to produce enzyme active reduced cofactors by direct electrolysis. 

Indicine IV-oxide (169) (Scheme 36) is a clinically important pyrrolizidine alkaloid being used in the treatment of neoplasms. The compound is an attractive drug candidate because it does not have the acute toxicity observed in other pyrrolizidine alkaloids. Indicine IV-oxide apparently demonstrates increased biological activity and toxicity after reduction to the tertiary amine. Duffel and Gillespie (90) demonstrated that horseradish peroxidase catalyzes the reduction of indicine IV-oxide to indicine in an anaerobic reaction requiring a reduced pyridine nucleotide (either NADH or NADPH) and a flavin coenzyme (FMN or FAD). Rat liver microsomes and the 100,000 x g supernatant fraction also catalyze the reduction of the IV-oxide, and cofactor requirements and inhibition characteristics with these enzyme systems are similar to those exhibited by horseradish peroxidase. Sodium azide inhibited the TV-oxide reduction reaction, while aminotriazole did not. With rat liver microsomes, IV-octylamine decreased... 

Reviewing the criteria for inclusion of components into the electron transport chain, Slater (1958) highlighted considerations previously advanced by H.A. Krebs as necessary to establish a pathway, namely that the amounts of enzyme present must be commensurate with enzymic activity in the preparation, activity should be fully restored by the reintroduction of the postulated component into an inhibited or depleted preparation, and that the rates of oxidation and reduction of components must be at least as great as those in the system overall. Reduction of cytochrome b by the systems then in use was thought by Chance (1952) and Slater (1958) to be too slow for the inclusion of this cytochrome into the main chain. 

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