Development of a versatile laboratory experiment to teach the metabolic transformation of hydrolysis

In this paper we describe an easy, reliable, versatile and inexpensive laboratory experiment to teach the metabolic transformation of hydrolysis to Pharmacy students. The experiment does not require the sacrifice of any experimental animal, or any work with organs or tissues, and so can be implemented in a typical university chemistry laboratory. We used acetylsalicylic acid (ASA), hexyl salicylate (HS) and two enzymes, a lipase and an esterase. Since both ASS and HS liberate salicylic acid (SA) upon hydrolysis, students can evaluate the different enzymatic transformations by monitoring the amount of SA liberated. The learning outcomes are an enhanced student understanding of: (1) the process of hydrolysis; (2) the application of enzymatic transformations of molecules from food to xenobiotics; (3) the differences between the general specificity of substrate of both enzymes; (4) the concepts of the lipophilic pocket; (5) the catalytic triad and its regioselectivity in relation to the ester bond. A questionnaire was administered to participating students at three points in time: at the beginning of the module, after enzymatic hydrolysis was taught in class, and after the laboratory experiment. From an analysis of the questionnaire data we conclude that this practical helped Pharmacy students to understand these concepts

Enzymatic methods for the determination of l-serine concentration and l-[14C]serine specific radioactivity in blood plasma

Methods are desribed for the use of l-serine dehydratase purified from Clostridium acidiurici for the determination of l-serine concentration and l[14C]serine specific radioactivity in sheep plasma. A spectrophotometric assay using this enzyme accurately measured the concentration of l-serine in standard solutions and in a commercially available mixture of amino acids and related compounds. This assay was shown to be suitable for measurement of plasma l-serine concentrations in excess of 30 μm. The reverse isotope dilution method was used for plasma l-[14C]serine specific radioactivity measurements. Carrier l-serine was added to plasma and separated from neutral and anionic compounds using ion-exchange chromatography. The l-serine was then converted to pyruvate with l-serine dehydratase and this was purified as the phenylhydrazone derivative. After recrystallization, drying and weighing, the derivative was assayed for radioactivity. The accuracy of this method was verified by adding l-[U-14C]serine to plasma and comparing the experimentally determined l-[14C]serine specific radioactivity with the calculated value. The method yielded a value which was 98.6 ± 0.8% (5) of this calculated value

Consequences of ligand bivalency in interactions involving particulate receptors: Equilibrium and kinetic studies with Sephadex-concanavalin A, butylagarose-phosphorylase b, and Fc receptor-IgG dimer interactions as model systems

Theoretical consideration is given to the interaction of a bivalent ligand with particulate receptor sites, not only from the viewpoint of quantitatively describing the binding behavior but also from that of the kinetics of ligand release upon infinite dilution of a receptor-ligand mixture. In the latter regard, a general expression is derived that describes the time dependence of the amount of ligand bound as a function of two rate constants for the stepwise dissociation of cross-linked ligand-receptor complex and a thermodynamic parameter expressing the initial ratio of singly linked to doubly linked ligand-receptor complexes. An experimental study of the interaction between Sephadex and concanavalin A is then used to illustrate application of this recommended theoretical approach for characterizing the binding behavior and dissociation kinetics of a bivalent ligand for a system in which all ligand-receptor interactions may be described by a single intrinsic association constant. Published results on the interaction of phosphorylase b with butylagarose are also shown to comply with this simplest model of the bivalent ligand hypothesis; but those for the interaction between immunoglobulin G (IgG) dimers and Fc receptors require modification of the model by incorporation of different intrinsic association constants for the successive binding of receptor sites to the bivalent ligand. These results emphasize the need to consider ligand bivalency as a potential phenomenon in studies of interactions between protein ligands and particulate receptors and illustrate procedures by which the effects of ligand bivalency may be identified and characterized

Mechanism-based inhibition of rat liver microsomal diazepam C3-hydroxylase by mifepristone associated with loss of spectrally detectable cytochrome P450

Since initial studies with the steroids norethindrone and ethynylestradiol, reported by White and Muller-Eberhard in 1977 (Biochem. J. 166, 57-64), there has been continuing interest in xenobiotics that bear terminal or sub-terminal acetylenic groups which can cause catalysis-dependent inhibition of CYP monooxygenases associated either with loss of prosthetic group heme or protein adduct formation. Mifepristone is a synthetic steroid bearing a propyne substitution on carbon 17 and this suggested to us that it may act as a mechanism-based inhibitor of the CYP isoforms responsible for its metabolism. In human and rat liver, CYP3A isoforms have been implicated in mifepristone clearance and mifepristone administration to rats has also been shown to induce CYP3A enzymes and the associated diazepam C-hydroxylase activity (Cheesman, Mason and Reilly, J. Steroid Biochem. Mol. Biol. 58, 1996, 447-454). With microsomes prepared from the livers of untreated female rats and others in which diazepam C-hydroxylase has been induced, we show here that mifepristone can cause catalysis-dependent inhibition of this monooxygenase. In addition, incubation of microsomes with mifepristone in the presence, but not in the absence, of NADPH caused loss of spectrally detectable cytochrome P450. These results suggest that heme adduct formation may result from mifepristone metabolism by CYP3A monooxygenases which undergo self-catalysed irreversible inactivation with this drug as substrate. Since mifepristone administration in vivo is able also to cause induction of the synthesis of hepatic CYP3A apoprotein, mifepristone may have the potential in human medicine for complex interactions with other co-administered drugs which are also substrates for CYP3A monooxygenases. Copyright (C) 1999 Elsevier Science Ireland Ltd

Evidence for lipid involvement in the high-affinity interaction between cimetidine and rat liver cytochrome P-450

The spectral interaction between cimetidine and a cytochrome P-450 fraction isolated from liver of untreated rats has been shown to be markedly affected by dilauroylphosphatidylcholine. In the absence of the lipid the pigment preparation yielded a binding curve characteristic of a single isoenzyme species with low affinity for the drug, whereas its inclusion led to the observation of a much stronger interaction with a dissociation constant close to that obtained for the high-affinity component(s) of the parent microsomes; material with lower affinity was also observed. Gel chromatography and partition equilibrium studies yielded results which precluded interpretation of this finding either in terms of incomplete incorporation of the pigment into the phospholipid or of disproportionate solvation of cimetidine into the lipid phase of the reconstituted phospholipid complex. In contrast, phospholipid caused only a minor change in the strength of cimetidine binding by the predominant liver cytochrome P-450 from phenobarbitone-pretreated rats. Pronounced lipid sensitivity of cimetidine-binding affinity is thus not a general feature of the microsomal cytochrome P-450 system but rather a specific characteristic of individual isoenzyme species

The interaction of cimetidine with rat liver microsomes

The binding of cimetidine to rat liver microsomes in M/15 phosphate buffer, pH 7.9, has been investigated by difference spectroscopy and also by equilibrium partition studies, the latter method providing the more definitive characterization of the interaction in the pharmacologically relevant, low micromolar range of drug concn. In addition, the effect of cimetidine on the rate of dilution-induced displacement of [3H]cimetidine from rat liver microsomes has been used to justify consideration of the binding results in terms of two distinct and independent classes of microsomal site, governed by dissociation constants of 8.3 and 104 μM under the above conditions. By demonstrating unequivocally the existence of the stronger interaction, this investigation has provided an acceptable experimental basis for considering the undesired side effect of cimetidine in concomitant use with a number of other drugs to be the consequence of its inhibition of their monooxygenase-dependent metabolism

Evaluation of monooxygenase induction as a means of enhancing the yield of the rat liver cytochrome P-450 isoenzyme with high affinity for cimetidine

The binding of cimetidine to liver microsomes prepared from untreated rats and rats pretreated with phenobarbitone or 3-methylcholanthrene has been investigated by difference spectroscopy and equilibrium partition methods. In M/15 phosphate buffer, pH 7.9, microsomes from each group of rats yielded markedly biphasic spectral binding curves, which have been interpreted in terms of two independent classes of cytochrome P-450 site with widely differing binding affinities for the drug. Support for such interpretation was provided by the finding that the spectral binding curve for a purified sample of the principal cytochrome P-450 isoenzyme from liver microsomes of phenobarbitone-pretreated rats could be described adequately by a single rectangular hyperbolic relationship, the spectral dissociation constant being indistinguishable experimentally from that for the weaker class of cytochrome P-450 binding site in the corresponding microsomes. The spectral dissociation constants were 2 μM and 80 μM for microsomes from untreated rats; 44 μM and 540 μM for those from phenobarbitone-pretreated rats; and 34 μM and 540 μM for microsomes from rats pretreated with 3-methylcholanthrene. On this basis, both classes of P-450 site in the microsomes from rats subjected to either pretreatment exhibited lower affinity for cimetidine than their counterparts in microsomes from untreated rats. Equilibrium partition studies of the higher-affinity class of microsomal binding site for cimetidine showed that the twofold increase in the cytochrome P-450 content of microsomes effected by 3-methylcholanthrene pretreatment was more than offset by a diminished proportion of the total cimetidine-binding capacity present as the higher-affinity, pharmacologically significant, receptor (18%, cf. 48% in control microsomes); and that phenobarbitone pretreatment resulted in replacement of the high-affinity receptor by one with a threefold weaker cimetidine-binding affinity. Thus the use of these monooxyginase inducers to enhance the cytochrome P-450 content of liver microsomes would seem to offer little potential in the isolation of the isoenzyme with high affinity for cimetidine