Dennis V. Parke

Interaction of a series of nitriles with the alcohol-inducible isoform of P450: computer analysis of structure-activity relationships.

1. Structural studies are reported on a series of 20 nitriles of varying rates of P4502E-mediated oxidative metabolism. 2. Parameters of molecular and electronic structure have been calculated for the generation of quantitative structure-activity relationships (QSARs) with the rates of oxidative metabolism of the nitriles, and with their acute toxicity. 3. Correlations between molecular polarizability, excitation energy and biological activity are presented as a result of QSAR analysis.

Mechanism of induction of hepatic microsomal drug metabolizing enzymes by a series of barbiturates

The inducing effect of certain barbiturates (secobarbitone, thiopentone, pentobarbitone, allobarbitone, phenobarbitone and barbitone) on the levels of the hepatic microsomal drug‐metabolizing enzymes has been studied in the rat both in vivo and in vitro. The extent of induction was related to the plasma half‐lives of the barbiturates; compounds with low rates of metabolism and long half‐lives were the most potent inducing agents. The latter (phenobarbitone, pentobarbitone and allobarbitone) were shown by spectral technique to interact with cytochrome P‐450 suggesting that their mechanism of enzyme induction was ‘substrate induction’ in type. Barbiturates containing an allyl group (secobarbitone and allobarbitone) had a weaker inducing effect than expected, possibly due to their destruction of cytochrome P‐450. Despite its short plasma half‐life of 0·5 h thiopentone was a relatively potent inducer probably due to its metabolism to pentobarbitone, which has a much longer plasma half‐life (1·3 h). Barbitone is an effective inducer of the drug‐metabolizing enzymes, yet does not interact spectrally with cytochrome P‐450; this is in accord with the observations that although there are increases in NADPH‐cytochrome c reductase and cytochrome b5, following administration of barbitone there is no increase in cytochrome P‐450. Barbiturate pretreatment does not affect the activities of glucose‐6‐phosphatase, glucose‐6‐phosphate dehydrogenase or 6‐phosphogluconate dehydrogenase.

Interactions of imidazole antifungal agents with purified cytochrome P-450 proteins.

The imidazole N-substituted antifungal agents ketoconazole, miconazole and clotrimazole have been shown to be potent inhibitors of oxidative metabolism by both a phenobarbital-induced cytochrome P-450 (P-450b) and a 3-methylcholanthrene-induced cytochrome P-448-protein (P-450c) in reconstituted systems. All three compounds inhibited the cytochrome P-450b-dependent 7-pentoxyresorufin-O-dealkylase and the cytochrome P-450c-dependent 7-ethoxyresorufin-O-deethylase activities. When 7-benzyloxyresorufin and 7-ethoxycoumarin were employed as substrates with both cytochrome preparations, all three antifungal compounds exhibited selective inhibition of the cytochrome P-450b preparation; ketoconazole was always the weakest inhibitor. The three antifungal agents were also shown to elicit a type II difference spectral interaction with both isoenzymes, the magnitude of the spectral interaction being greater with the cytochrome P-450b preparation.

Molecular dimensions of the substrate binding site of cytochrome P-448.

The molecular geometries of specific substrates, inhibitors and inducers of cytochrome P-448 activity were determined using computer-graphic techniques for use in defining the molecular dimensions of the substrate binding site of this enzyme. Specific substrates of cytochrome P-448 are essentially planar molecules characterised by a small depth and a large area/depth ratio. In contrast, compounds that do not serve as substrates of cytochrome P-448 are bulky, non-planar molecules characterised by small area/depth ratios and greater flexibility in molecular conformation. Specific inhibitors of cytochrome P-448 whose effect is mediated through interaction with the haem still meet the dimensional criteria for substrates indicating that they must also interact with the substrate binding-site, which is probably located in proximity to the haem. Inducers of cytochrome P-448 activity exhibit similar molecular geometries to the substrates from which it may be inferred that the cytosolic receptor associated with the induction of cytochrome P-448 activity is structurally related to the active site of the cytochrome.

Cytochrome P-448 and the activation of toxic chemicals and carcinogens.

The metabolic activation of carcinogens and some toxic chemicals appears to involve oxygenation in conformationally hindered positions in the chemical molecules. Oxygenation of xenobiotics in hindered positions is effected by cytochrome P-448 (LM4) but not by cytochrome P-450 (LM2). Substrate-interaction spectra show that cytochrome P-448 has an active site with a conformation different from that of cytochrome P-450. Induction of cytochrome P-448, as specifically measured by ethoxyresorufin O-deethylase activity, occurs in rat liver, kidney and lung after administration of the carcinogens, 3-methylcholanthrene, Aroclor 1254, 2-anthramine, safrole, 7,12-dimethylbenz[a]anthracene, MNNG and 2-acetamidofluorene. The doubtful carcinogens, saccharin, DDT and aldrin, resulted in no significant induction. The drugs paracetamol, antipyrine, imipramine and rifampicin resulted in diminished enzyme activity, indicating the absence of any induction of cytochrome P-448. In studies with the matched pairs of carcinogens and non-carcinogens, benzo[a]pyrene and benzo[e]pyrene, and 1,2,5,6-dibenzanthracene and anthracene, only the carcinogenic analogue resulted in induction of cytochrome P-448. With alpha- and beta-naphthylamine, both resulted in marked induction of cytochrome P-448 in liver, kidney and lung, indicating that both isomers might be carcinogenic.

SAFROLE - ITS METABOLISM, CARCINOGENICITY AND INTERACTIONS WITH CYTOCHROME-P-450

Abstract A review of studies on safrole metabolism shows that the compound gives rise to a large number of metabolites by two major pathways, oxidation of the allyl side chain and oxidation of the methylenedioxy group with subsequent cleavage to form a catechol. The mechanism by which safrole exerts the weak hepatocarcinogenicity that has been demonstrated in rats and mice is considered on the basis of published work and recent studies by the authors. Metabolic conversion of the allyl group gives rise to intermediates capable of covalent binding with DNA and protein, and recent findings are compatible with conversion of the methylenedioxy group to a carbene, which forms ligand complexes with the haem moiety of cytochromes P -450 and P -448. It is suggested that while the allyl group is responsible for the mutagenic potential of safrole, the methylenedioxy moiety may be associated with epigenetic aspects of carcinogenicity.

Effects of pregnancy on the metabolism of drugs in the rat and rabbit

Abstract In rats 19–20 days pregnant, liver weight is increased by 40 per cent, cytochrome P-450 concentration is decreased by 25 per cent and the specific activities of 4-methylumbelliferone glucuronyl transferase and biphenyl-4-hydroxylase are reduced by 25 and 30 per cent, respectively; biphenyl-2-hydroxylase and p-nitrobenzoic acid reductase are not changed. In rats, 15–16 days pregnant, liver weight is increased by 33 per cent but the concentration of cytochrome P-450 and the specific activities of the drug microsomal enzymes are unchanged. Expressed as total amounts per whole liver, there is an increase in microsomal protein and nitro-reductase in both 15–16 and 19–20 day pregnant animals but no changes occur in cytochrome P-450, glucuronyl transferase or biphenyl hydroxylases. Hexobarbital administered to rats at doses related to pregnant body weight increases the sleeping-time from 50 min in non-pregnant animals to 110 min at full-term, but when administered on the basis of the non-pregnant body weight the duration of anaesthesia remains unchanged. Pretreatment of pregnant (19–20 days) and non-pregnant rats with phenobarbital leads to similar increases in microsomal protein (25 per cent) and nitroreductase activity (40 per cent); cytochrome P-450 is increased in non-pregnant animals (30 per cent) but not in the pregnant, although biphenyl-4-hydroxylase is increased in both to such extents as to annul the inhibitory effect of pregnancy. Pretreatment with methylcholanthrene gives rise to similar increases in cytochrome P-450 (30 per cent) and biphenyl-2-hydroxylase (10-fold increase) in both pregnant and non-pregnant rats and again increases biphenyl-4-hydroxylase so as to annul the effect of pregnancy. With rabbits, no change occurs in liver weight, microsomal protein, nitro-reductase, cytochrome P-450, or biphenyl-4-hydroxylase at full-term pregnancy, but glucuronyl transferase is reduced by 20 per cent, and coumarin-7-hydroxylase by 60 per cent. Pretreatment of rabbits with phenobarbital increases microsomal protein (15, 25 per cent), nitro-reductase (70, 80 per cent), cytochrome P-450 (130, 90 per cent), biphenyl-4- hydroxylase (50, 60 per cent), coumarin-7-hydroxylase (40, 150 per cent), and glucuronyl transferase (65, 15 per cent) in both non-pregnant and pregnant animals, respectively. The decrease during pregnancy of hepatic glucuronyl transferase is attributed to competitive inhibition by high levels of endogenous estrogenic and progestational steroids, but the decrease in the activities of the microsomal hydroxylating enzymes is attributed to the decrease in P-450, which may result from high levels of growth factors.

Activation mechanisms to chemical toxicity

The pathobiology of chemical toxicity may involve “acute lethal injury” (necrosis), “autoxidative injury” (oxygen toxicity), “immunological injury” (neoantigen formation), and malignancy. Toxic chemicals may be activated by reduction, conjugation, radical formation, or oxidation. Oxidative activation may be effected by cytochromes P-450/P-448, flavoprotein monooxygenases, or hydroxyl radicals. The alternative pathways of oxidative metabolism of toxic chemicals, namely, detoxication and activation, are catalysed by the phenobarbital-induced cytochromes P-450 and by the 3-methylcholanthrene-induced cytochromes P-448 respectively. Oxidative metabolism by cytochromes P-450 is followed by conjugation and detoxication, whereas oxidative metabolism by cytochromes P-448 yields reactive intermediates which are not readily conjugated, and thus react with vital intracellular macromolecules, resulting in necrosis, redox cycling and oxygen radical formation, neoantigen production, and mutations. The molecular dimensions of specific substrates, inhibitors and inducers of the PB-cytochromes P-450 indicate that they are globular and are different from those of the cytochromes P-448 which are planar, suggesting that the active sites of the two families of enzymes are different. Oxidative metabolism of planar substrates of cytochromes P-448 results in conformationally-hindered oxygenations, which inhibits subsequent conjugations. Cytochrome P-448 activity may be quantified by the oxidative deethylation of 7-ethoxyresorufin which, unlike benzo(a)pyrene hydroxylation (AHH) is a specific reaction for this family of enzymes. Oxidative metabolism of chemicals varies inversely with the body weight of the animal species, so that chemical toxicity involving oxidative activation, redox cycling, and reactive oxygen is greater the smaller the animal species.

Safety aspects of food preservatives

The use of food preservatives, such as benzoic acid, nitrites, and sulphites, as antimicrobials, and butylated hydroxyanisole (BHA), butylated hydroxytoluene (BHT), ascorbic acid and tocopherols, as antioxidants, has probably changed food production patterns and eating habits more than has the use of any other class of food additive. These food preservative chemicals confer substantial benefits on man, not only by the preservation and increased palatability of food, but also by affording protection against the pathological effects of reactive oxygen species (ROS) which are associated with cancer, cardiovascular disease and aging. Nevertheless, although most preservatives are now considered to be without potential adverse effects and are classified as GRAS, there have been problems concerning the safety of some of these chemicals, including the possibility of allergies from benzoic acid and sulphites, the formation of carcinogenic nitrosamines from nitrites, and the possible rodent carcinogenicity of BHA and BHT. The mechanisms of this toxicity at high dosage, the roles of the cytochromes P450, and the generation and scavenging of ROS in the toxicity of these chemicals, are reviewed and discussed.

Structural requirements for substrates of cytochromes P-450 and P-448

Distinct and different molecular structural features are manifested by substrates, inhibitors and inducers of the two families of liver microsomal enzymes, the phenobarbital-induced cytochromes P-450 and the 3-methylcholanthrene-induced cytochromes P-448. In a theoretical study based on molecular orbital calculations and molecular graphics, it is established that cytochrome P-448 substrates contain fused aromatic or heteroaromatic rings giving rise to overall molecular planarity with relatively small molecular depth. In contrast, substrates of the cytochromes P-450 have greater conformational freedom and an ability to bind at more than one point of attachment, as a result of possession of certain characteristic functions, namely, a carbonyl and/or amine moiety coupled with an iso-propyl group, or similar function of equivalent shape and hydrophobicity. The implications are that the binding sites of cytochromes P-448 contain a number of hydrophobic aromatic amino acid residues orientated so as to allow occupation by similar substrates containing co-planar aromatic rings, whereas those of the phenobarbital-induced cytochromes P-450 contain hydrophilic amino acid residues capable of hydrogen bonding to greater than C = O moieties and at least one leucine or valine residue, as these contain the complementary isopropyl function. The corollary of these findings is the possibility of prediction of the toxicity of new chemicals on the basis of their molecular dimensions.