ADP release is the rate-limiting step of the MT activated ATPase of non-claret disjunctional and kinesin.

The motor protein non-claret disjunctional (ncd) moves towards the minus ends of microtubules (MTs), whereas its close relative kinesin moves in the opposite direction towards the plus ends of MTs. The mechanisms of movement and directional reversal for these motor proteins are unknown. Here we report the rate constants for MT activated ADP release from a recombinant double-headed ncd protein, GST-MC5, and a recombinant double-headed kinesin protein, K delta 401, measured using the fluorescent nucleotide analogues methylanthranilyol ATP (mantATP) and mantADP. Comparison of the maximal MT activated mantADP release rates for these proteins with their maximal MT activated mantATP turnover rates indicates that ADP release is the rate-limiting step for ATP turnover for both ncd and kinesin. This data supports the view that directional reversal may result from structural rather than chemical kinetic differences in the way the motors interact with MTs.

Effects of phenobarbitone and beta-naphthoflavone on hepatic microsomal drug metabolising enzymes of the male beagle dog.

Hepatic microsomes, prepared from male beagle dogs treated with phenobarbitone or beta-naphthoflavone, were compared with microsomes from control dogs and from control, phenobarbitone and beta-naphthoflavone treated rats with respect to various microsomal enzyme activities and for protein profiles generated on sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE). The concentration of total cytochrome P-450 (0.46 nmoles/mg protein) and aldrin epoxidase (0.44 nmoles/mg/min) was lower in control dogs than in the rat, although ethoxycoumarin O-deethylase (ECOD-1.03 nmoles/mg/min) was 2 times and ethoxyresorufin O-deethylase (EROD-0.10 nmoles/mg/min) 5 times higher in the control dogs examined. Possibly as a result of this difference, beta-naphthoflavone induced ECOD 10-fold and EROD 100-fold in the rat, while these enzymes were only increased 3-fold and 5-fold respectively in the two beta-naphthoflavone-treated dogs. Consistent with this, control dog microsomes were found to contain a 58,000 mol. wt protein band that was not present in the SDS-PAGE of control rat microsomes but which was induced in both species by beta-naphthoflavone. Although not identical, the effects of each inducer on the protein profiles were similar in both species. beta-Naphthoflavone produced a marked increase in relative liver weight and, in contrast to published work in the rat, also increased NADPH-cytochrome c reductase levels in the dog. In general, the effects of phenobarbitone were qualitatively and quantitatively similar in both the dog and the rat.

Different inhibition and induction profiles of hepatic drug metabolism in rats and dogs by two structurally related pyridyl diazinone cardiotonic agents.

ICI 153,110 and ICI 170,777, two pyridyl diazinone cardiotonic agents, produced a different profile of effects on hepatic microsomal mixed function oxidase enzymes following multiple oral dosing to rats and dogs; these differences may be related to the molecular dimensions of the two molecules. ICI 153,110 significantly increased levels of total P450, ethoxycoumarin O-deethylase and ethoxyresorufin O-deethylase in rat microsomes, indicating an induction profile (P448) similar to that of beta-naphthoflavone. This was supported by gel electrophoresis (SDS-PAGE) of microsomal proteins; a similar type of induction was observed in dog microsomes. In contrast, ICI 170,777 produced no changes indicating enzyme induction in either rat or dog. Instead, ICI 170,777 appeared to inhibit specifically the activity of aldrin epoxidase in the rat. Inhibitory activity was also indicated in the rat by prolongation of pentobarbitone sleeping time following single oral doses of either ICI 153,110 or ICI 170,777. The time-course of this effect appeared to correlate more closely with the profile of circulating metabolites, although both parent compounds were found to produce type II spectral changes on interaction with control rat microsomes. The molecular dimensions (area/depth2) of the compounds supported the finding that only ICI 153,110 should interact with or induce P448 isozymes.

Acute absorption of folic acid from a fortified low-fat spread.

OBJECTIVE: To explore the feasibility of low-fat spreads as vehicles for folic acid (FA) fortification by determining the acute absorption of FA from a fortified spread. DESIGN: Double blind, crossover study to test each of the following treatments administered at 1-weekly intervals: (A) 20 g low-fat (40%) spread fortified with 200 microg FA and a placebo tablet; (B) 20 g low-fat placebo spread and a 200 microg FA tablet; (C) 20 g low-fat placebo spread and a placebo tablet. SUBJECTS: A total of 13 male volunteers, aged 31.8+/-13.2 y. MAIN OUTCOME MEASURES: Plasma total folate concentrations, measured before and up to 10 h after each treatment (n=10 samples per treatment). RESULTS: Plasma folate concentrations were significantly increased compared with baseline values 1 h after administration of the FA tablet, and 1.5 h after the FA spread, and remained significantly higher than the baseline values for up to 7 h after both treatments. The maximum plasma folate response (R(max)), corrected for baseline values and 'placebo response', was established between 1 and 3 h postprandially in response to both FA spread and FA tablet, and no significant difference in R(max) was found between the two treatments (13.4 vs 14.4 nmol/l, P=0.9). The acute absorption of FA from fortified spread relative to that from the tablet, calculated on the basis of area under the plasma folate response curve, was 67% (P=0.04). CONCLUSION: The absorption of FA from fortified low-fat spread, although lower than from a tablet, is effective. These results suggest that low-fat spreads, typically associated with fat-soluble vitamin fortification, may also be considered feasible as vehicles for FA fortification.

Pharmacodynamics of ZM 241385, a potent A2a adenosine receptor antagonist, after enteric administration in rat, cat and dog.

4-(2-[7-Amino-2-(2-furyl)[1,2,4]triazolo[2,3-a][1,3,5] triazin-5-ylamino]ethyl)phenol (ZM 241385) is currently the most selective for the A2a adenosine receptor antagonist. This paper describes the in-vivo activity of ZM 241385 after administration by both oral and intraduodenal routes. In conscious spontaneously hypertensive rats, ZM 241385 (1-10 mg kg-1) selectively attenuated the mean arterial blood pressure response produced by exogenous adenosine (1 mg kg-1 min-1, i.v.) by up to 45% after oral administration. Activity of ZM 241385 was maintained for at least 6 h after 3 and 10 mg kg-1 (p.o.). In conscious normotensive cats, ZM 241385 attenuated the blood pressure responses to adenosine (0.6-1.0 mg kg-1, i.v.) by 94% after 10 mg kg-1 (p.o.) and by up to 74% after 0.3 mg kg-1 (i.v.). Duration of action of ZM 241385 up to 12 h (36% inhibition) was observed after 3 mg kg-1 (p.o.). In anaesthetized dogs and cats, ZM 241385, after intraduodenal administration (1-10 mg kg-1), produced a rapid (dose ratio 100-fold 15 min after administration of 10 mg kg-1 in the cat) and prolonged (dose ratio of 14 at 6 h after administration of 10 mg kg-1) attenuation of the vasodilatation responses to adenosine receptor stimulation. When administered by this route ZM 241385 was six times more potent than theophylline in the cat and at least twice as potent as theophylline in the dog. In conclusion, ZM 241385 is a potent, selective A2a adenosine receptor antagonist which is orally active, with a good duration of action by the enteric route in cat, rat and dog. It could therefore be used to evaluate the role of adenosine A2a receptors in the action of adenosine in-vivo.

The effects on rat thyroid function of an hepatic microsomal enzyme inducer.

1. Following daily administration to male albino rats for 2 weeks, beta-naphthoflavone (25 and 60 mg kg-1, i.p.) and phenobarbitone (100 mg kg-1, p.o.) produced their characteristic patterns of induction of P450-related enzyme activities. beta-naphthoflavone also induced p-nitrophenol glucuronidation by 160% over controls, while phenobarbitone produced only a 45% induction of this conjugation activity. 2. beta-Naphthoflavone produced significant reductions in plasma thyroxine (T4) concentrations on days 4 and 16 and also decreased tri-iodothyronine (T3) on day 4. Thyroid-stimulating hormone (TSH) was significantly increased on day 16 by the higher dose of beta-naphthoflavone. Thyroid weight was significantly increased at both dose levels on day 16 and liver weight was significantly increased on both days 4 and 16. No histopathological changes were seen in the liver or pituitary, but 30% of the animals showed minimal to mild follicular epithelial hypertrophy of the thyroid gland. 3. Phenobarbitone had no effect on T4 concentrations, but significantly decreased T3 on day 4. TSH increased by 60% on day 16, but was not statistically significantly compared with controls. Thyroid weight was significantly increased on day 16 and liver weight was significantly increased on days 4 and 16. Mild to moderate thyroid follicular epithelial hypertrophy and moderate hepatocyte hypertrophy occurred in all animals. No histopathological changes were seen in the pituitary. 4. The early changes in T4 and/or T3 were probably due to increased hepatic clearance by induction of thyroxine glucuronidation with both compounds. Thyroid hypertrophy would be expected to follow as a result of activation of the hypothalamic-pituitary-thyroid axis.(ABSTRACT TRUNCATED AT 250 WORDS)

In vitro metabolism of a triclyclic alkaloid (M445526) in human liver microsomes and hepatocytes.

The in vitro metabolism of M445,526 (ZD6,126 phenol) was investigated by incubating [(14)C]-M445,526 at a concentration of 10 microg ml(-1) with human hepatic microsomes (4 mg ml(-1)) or human hepatocytes (2 x 10(6) cells ml(-1)) for up to 180 min. Following incubation with microsomes and hepatocytes, up to 78% and 40% of [(14)C]-M445,526 was metabolized after 180 and 120 min, respectively. High-performance liquid chromatography (HPLC) with radiochemical detection confirmed extensive metabolism of [(14)C]-M445,526 by microsomes and hepatocytes. Mass spectrometry and (1)H-NMR spectroscopy enabled structural identification of up to eight metabolites. Human liver microsomes formed one major (O-desmethyl) and three minor (a further O-desmethyl and two different hydroxylated) phase I metabolites. Human hepatocytes produced one major metabolite, a sulphate conjugate of the major O-desmethyl metabolite formed by microsomes. Four minor metabolites were also formed, primarily by O-demethylation with subsequent glucuronidation. Taken collectively, [(14)C]-M445,526 underwent extensive in vitro metabolism by human liver fractions. These data were confirmed by subsequent human in vivo studies.

Minimal contribution of desmethyl-gefitinib, the major human plasma metabolite of gefitinib, to epidermal growth factor receptor (EGFR)-mediated tumour growth inhibition.

Desmethyl-gefitinib is a major metabolite of gefitinib observed in human plasma at concentrations similar to those of gefitinib. The epidermal growth factor receptor (EGFR)-related inhibitory effects of gefitinib and desmethyl-gefitinib have been compared both in vitro, using enzyme kinase assays and tumour cell growth inhibition, and in vivo by assessment of tumour xenografts growth inhibition in the mouse. Both gefitinib (IC(50) = 0.022 microM) and its desmethyl metabolite (0.036 microM) inhibited subcellular EGFR tyrosine kinase activity with a similar potency and selectivity. However, desmethyl-gefitinib (IC(50) = 0.76 microM) was 15 times less active than gefitinib (0.049 microM) against EGF-stimulated KB cell growth in a whole cell assay. Following a preliminary pharmacokinetic study to compare apparent oral bioavailability, gefitinib (75 mg kg(-1)) and desmethyl-gefitinib (150 mg kg(-1)) were administered orally for 15 days to female nude mice bearing LoVo tumour xenografts. Tumour concentrations of gefitinib (AUC = 300 microg h g(-1)) were much higher than those of desmethyl-gefitinib (44.3 microg h g(-1)), although plasma concentrations of gefitinib (48.4 microg h ml(-1)) and desmethyl-gefitinib (39.0 microg h ml(-1)) were quite similar at these dose levels. Gefitinib produced significant tumour growth inhibition throughout the course of the study ultimately resulting in a 50% decrease (compared with controls) by day 15. In contrast, although present at comparable plasma levels, desmethyl-gefitinib had little effect on tumour growth and is, therefore, considered unlikely to contribute significantly to the therapeutic activity of gefitinib in the clinical situation.

Cytochrome P450-dependent metabolism of gefitinib.

The in vitro metabolism of [(14)C]-gefitinib (1-3 microM) was investigated using human liver microsomes and a range of expressed human cytochrome P450 enzymes, with particular focus on the formation of O-desmethyl-gefitinib (M523595), the major metabolite observed in human plasma. High-performance liquid chromatography with ultraviolet light, radiochemical and mass spectral analysis, together with the availability of authentic standards, enabled quantification and structural identification of metabolites. On incubation with pooled human liver microsomes, [(14)C]-gefitinib underwent rapid and extensive metabolism to a number of metabolites, although M523595 was only a minor microsomal product. Formation of most metabolites was markedly decreased by ketoconazole, but M523595 production was inhibited only by quinidine. Gefitinib was metabolized extensively by expressed CYP3A4, producing a similar range of metabolites to liver microsomes, but M523595 was not formed. CYP1A2, 2C9 and 2C19 produced no measurable metabolism of gefitinib, while CYP3A5 produced a range of metabolites similar to CYP3A4, but to a much lower degree. In contrast, CYP2D6 catalysed rapid and extensive metabolism of gefitinib to M523595. While formation of M523595 was CYP2D6 mediated, the overall metabolism of gefitinib was dependent primarily on CYP3A4, and this was not obviously diminished in liver microsomes from CYP2D6 poor metabolizers.

The metabolism and binding of catecholamines by the hepatic microsomal mixed-function oxidase of the rat.

Noradrenaline and adrenaline were metabolized by an NADPH- and oxygen-dependent process located within the hepatic microsomal fraction of the rat. Metabolism was inhibited by CO and compound SKF 525A, but not by pargyline, an inhibitor of monoamine oxidase, or by 3,4-dimethoxy-5-hydroxybenzoic acid, an inhibitor of catechol O-methyltransferase. It is concluded that the enzyme system responsible for the metabolism of the catecholamines was the microsomal mixed-function oxidase. The Km for noradrenaline was 2.4 mM and for adrenaline 1.0 mM, and V 15.6 and 3.6 nmol/min per mg of microsomal protein respectively. Both catecholamines bound to the microsomal fraction, producing a type II spectral change, with a Ks for noradrenaline of 0.9 mM and for adrenaline of 1.0 mM, and showed other characteristics of type II compounds by inhibited the reduction of cytochrome P-450 by NADPH and exhibiting an enhanced metabolism in the presence of acetone. The major product of catecholamine metabolism was an as yet unidentified alkali-labile compound, which did not correspond to any of the recognized catecholamine metabolites.

Absence of hepatic enzyme induction in prostate cancer patients receiving 'Casodex' (bicalutamide).

The potential for hepatic enzyme induction by bicalutamide ('Casodex') was assessed in an open study in prostate cancer patients. A single, oral dose of antipyrine 1000 mg was given before and after 12 weeks' bicalutamide therapy [once daily 50 mg (n = 7) or 150 mg (n = 11)] and its pharmacokinetics and metabolism were determined. Plasma or saliva samples were taken for the measurement of antipyrine concentration. Urine samples were assayed for antipyrine and its three major metabolites. With bicalutamide 50 mg, plasma antipyrine concentrations were maximal between 2 and 4 h after administration, declined in a log-linear manner and were unaffected by bicalutamide therapy; with bicalutamide 150 mg, saliva antipyrine concentrations were maximal between 2 and 4 h, declined in a log-linear manner, and were also unaffected by bicalutamide therapy. Antipyrine half-life was 16.3% shorter after bicalutamide 50 mg (p < 0.05); a small decrease (13.5%) in half-life after bicalutamide 150 mg was not statistically significant. A small reduction (18.6%, p < 0.05) in the AUCinfinity for antipyrine was noted after bicalutamide 150 mg. A statistically significant reduction in antipyrine recovery was seen with the lower bicalutamide dose (23.7%, p < 0.05). The statistically significant changes were small in absolute terms and showed no dose-response relationship. Bicalutamide does not significantly induce the hepatic enzymes responsible for antipyrine metabolism and has no obvious potential for producing clinically significant drug interactions due to enzyme induction.

Regulation of the acto.myosin subfragment 1 interaction by troponin/tropomyosin. Evidence for control of a specific isomerization between two acto.myosin subfragment 1 states.

The co-operative binding of myosin subfragment 1 (S1) to reconstituted skeletal-muscle thin filaments has been examined by monitoring the fluorescence of a pyrene probe on Cys-374 of actin. The degree of co-operativity differs when phosphate, sulphate or ADP are bound to the S1 active site. Binding isotherms have been analysed according to the Geeves & Halsall [(1987) Biophys. J. 52, 215-220] model, which proposed that troponin and tropomyosin effected regulation of the actomyosin interaction by controlling an isomerization of the actomyosin complex. The data support the proposal that seven actin monomers associated with a single tropomyosin molecule act as a co-operative unit that can be in one of two states. In the 'closed' state myosin can bind to actin, but the subsequent isomerization is prevented. The isomerization is only allowed after the seven-actin unit is in the 'open' form. Ca2+ controls the proportion of actin filaments in the 'closed' and 'open' forms in the absence of myosin heads. The ratio of 'closed' to 'open' forms is approx. 50:1 in the absence of Ca2+ and 5:1 in its presence.

Regulation of the interaction between actin and myosin subfragment 1: evidence for three states of the thin filament.

Equilibrium titrations and kinetic experiments were used to define the cooperative binding of myosin subfragment 1 (S1) to actin-troponin-tropomyosin. Both types of experiment require an equilibrium between two states of the thin filament in which one state (the off state) binds S1 less readily than the other. Equilibrium titrations are compatible with > 95% of the actin7.Tn.Tm units being in the off state in the absence of calcium and 80% in the off state in the presence of calcium. Kinetic binding data suggest that the presence of calcium switches the thin filament from 70% in the off state to < 5%. The two experiments, therefore, define quite different populations of the off states. We propose a three-state model of the thin filament. A "blocked state" which is unable to bind S1, a "closed state" which can only bind S1 relatively weakly and an "open state" in which the S1 can both bind and undergo an isomerization to a more strongly bound rigor-like conformation. The equilibrium between the three states is calcium-dependent; KB = [closed]/[blocked] = 0.3 and > or = 16 and KT = [open]/[closed] = 0.09 and 0.25 in the absence and presence of calcium, respectively. This model can account for both types of experimental data.