Flavin metabolites

Cocaine-mediated hepatotoxicity has been associated with the conversion of cocaine to norcocaine and further oxidation products. The enzymes involved in in vitro hepatic oxidative N-demethylation of cocaine (192) were investigated (237), and two different enzymatic pathways appear to be important in the formation of the hepatotoxic metabolite. Cytochrome P-450 monooxygenases accomplish the direct N-demethylation of cocaine to norcocaine (194) as confirmed by induction and inhibition studies (Scheme 42). The second pathway for cocaine N-demethylation involves formation of cocaine /V-oxide (193) as an intermediate and two enzymes. A flavin-containing monooxygenase is first thought to convert cocaine to cocaine /V-oxide, followed by cytochrome P-450-... 

Disulfoton causes neurological effects in humans and animals. The mechanism of action on the nervous system depends on the metabolism of disulfoton to active metabolites. The liver is the major site of metabolic oxidation of disulfoton to disulfoton sulfoxide, disulfoton sulfone, demeton S-sulfoxide and demeton S-sulfone, which inhibit acetylcholinesterase in nervous tissue. These four active metabolites are more potent inhibitors of acetylcholinesterase than disulfoton. Cytochrome P-450 monooxygenase and flavin adenine dinucleotide monooxygenase are involved in this metabolic activation. The active metabolites ultimately undergo nonenzymatic and/or enzymatic hydrolysis to more polar metabolites that are not toxic and are excreted in the urine. 

Rebeccamycin is an antitumor or antibiotic agent isolated from bacteria " and contains a maleimide indolocarbazole framework. The Trp units in this molecule are chlorinated at the C-7 position and a flavin-dependent halogenase was identified as the enzyme that carries out this chlorination (Scheme 10). " There are many other halogenating enzymes known in the literature and these enzymes are responsible for the syntheses of metabolites containing bromine, chlorine, and fluorine. ... 

It is highly protein bound (approx. 96%), metabolised in the liver by N-oxidation to inactive metabolites by the enzyme flavin-containing monooxygenase. It is excreted mainly by the kidneys in the form of metabolites and as unchanged drug. 

Reduced flavins, unlike reduced nicotinamides, are reactive towards molecular oxygen, and an intermediate produced in this reaction is a more potent oxygenating agent than molecular oxygen is itself. A number of enzymes have evolved which utilize this intermediate to oxygenate certain metabolites. These reactions usually entail monooxygenation (Scheme 5). There are, however, at least two examples of dioxygenation that have been reported... 

When taken up by the body, riboflavin is converted into its coenzyme forms (Chapter 25) and any excess is quickly excreted in the urine. Urine also contains smaller amounts of metabolites. The ribityl group may be cut by the action of intestinal bacteria acting on riboflavin before it is absorbed. The resulting 10-hydroxyethyl flavin may sometimes be a major urinary product.c d The related 10-formylmethyl flavin is also excreted,0 as are small amounts of 7a- and 8a- hydroxyriboflavins, apparently formed in the body by hydroxylation. These may be degraded farther to the 7a- and 8a- carboxylic acids of lumichrome (riboflavin from which the ribityl side chain is totally missing).6 A riboflavin glucoside has also been found in rat urine.f... 

Pyruvate oxidase. The soluble flavoprotein pyruvate oxidase, which was discussed briefly in Chapter 14 (Fig. 14-2, Eq. 14-22), acts together with a membrane-bound electron transport system to convert pyruvate to acetyl phosphate and C02.319 Thiamin diphosphate is needed by this enzyme but lipoic acid is not. The flavin probably dehydrogenates the thiamin-bound intermediate to 2-acetylthiamin as shown in Eq. 15-34. The electron acceptor is the bound FAD and the reaction may occur in two steps as shown with a thiamin diphosphate radical intermediate.3193 Reaction with inorganic phosphate generates the energy storage metabolite acetyl phosphate. 

Aromatic compounds arise in several ways. The major mute utilized by autotrophic organisms for synthesis of the aromatic amino acids, quinones, and tocopherols is the shikimate pathway. As outlined here, it starts with the glycolysis intermediate phosphoenolpyruvate (PEP) and erythrose 4-phosphate, a metabolite from the pentose phosphate pathway. Phenylalanine, tyrosine, and tryptophan are not only used for protein synthesis but are converted into a broad range of hormones, chromophores, alkaloids, and structural materials. In plants phenylalanine is deaminated to cinnamate which yields hundreds of secondary products. In another pathway ribose 5-phosphate is converted to pyrimidine and purine nucleotides and also to flavins, folates, molybdopterin, and many other pterin derivatives. 

Toxicants may also be detoxified by xenobiotic-metabolizing enzymes such as cytochrome P450 or the flavin-containing monooxygenase. It should be borne in mind, however, that these enzymes may also activate toxicants to more reactive, and potentially more toxic, metabolites. 

The essential difference between nicotinamide and flavin is in the nature of the acceptor site, i.e., CH for nicotinamide as compared with N for flavoquinone. This explains why 5-deazaflavins appear to be interesting flavin (anti)metabolites since they are expected to be functional analogs of nicotinamide, exhibiting at the same time the steric shape of a flavin. Indeed it turns out that incorporation of 5-deazaflavin into apo-flavoproteins blocks the electron transfer and oxygen activation properties (32,33,34,35,36). Retaining at least partially the (de) hydro-... 

Indices of Vitamin E Nutritional Status Reference Intakes of Vitamin K Indices of Thiamin Nutritional Status Reference Intakes of Thiamin Tissue Flavins in the Rat Urinary Excretion of Riboflavin Metabolites... 

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