Metabolism and excretion of atorvastatin in rats and dogs.

Atorvastatin (AT) is a second-generation potent inhibitor of 3-hydroxy-3-methylglutaryl-CoA reductase, clinically approved for lowering plasma cholesterol. Using a mixture of [D(5)/D(0)] AT and/or [(14)C]AT, the metabolic fate and excretion of AT were examined in rats and dogs following single and multiple oral doses. Limited biliary recycling was examined in one dog after a single dose of AT. AT-derived metabolites in bile samples were identified by metabolite screening of the [D(5)/D(0)] AT molecular clusters using tandem mass spectrometry. Bile was a major route of [(14)C] drug-derived excretion, accounting for 73 and 33% of the oral dose in the rat and dog, respectively. The remaining radioactivity was recovered in the feces; only trace amounts were excreted in urine. Radioactive components identified in rat and dog bile were the para- and ortho-hydroxy metabolites, a glucuronide conjugate of ortho-hydroxy AT, and unchanged AT. Two minor radioactive components were identified as beta-oxidation products of AT with one confirmed as a beta-oxidized AT derivative. The reappearance of AT and major metabolites in bile from a dog administered a sample of its previously excreted bile indicated biliary recycling is an important component in AT metabolism. Multiple dose administration in rats did not alter biliary metabolic profiles. Rat and dog plasma profiles after multiple dose administration were similar and showed no additional metabolites not found in bile. Examination of rat and dog bile and plasma indicates that AT primarily undergoes oxidative metabolism.

Development and validation of a high-performance liquid chromatography tandem mass spectrometry assay for atorvastatin, ortho-hydroxy atorvastatin, and para-hydroxy atorvastatin in human, dog, and rat plasma.

A liquid chromatographic/mass spectrometric method to quantitate atorvastatin (AT) and its active metabolites ortho-hydroxy (o-AT) and para-hydroxy (p-AT) atorvastatin in human, dog, and rat plasma was validated. The method consisted of washing plasma samples at high pH with diethyl ether and subsequently extracting the analytes and two internal standards, [d5]-atorvastatin ([d5]-AT) and [d5]-ortho-hydroxy atorvastatin ([d5]-o-AT), from acidified plasma by using diethyl ether. The ether layer was evaporated to dryness and the residue reconstituted in ammonium acetate (20 mM, pH 4.0)-acetonitrile-isopropanol (60:40:1, v/v/v). Chromatographic separation of analytes was achieved by using a YMC J'Sphere H80 (C-18) 150 x 2 mm, 4 microns particle size, column with a mobile phase consisting of acetonitrile-0.1% acetic acid, (70:30, v/v). Analytes were detected by using MS/MS. Sample introduction and ionization was by electrospray ionization in the positive ion mode. The method proved suitable for routine quantitation of AT, o-AT, and p-AT over the concentration range of 0.250 to 25.0 ng/mL. Approximate retention time ranges of p-AT, o-AT, [d5]-o-AT, AT, and [d5]-AT were 2.27 +/- 0.21, 3.36 +/- 0.23, 3.54 +/- 0.46, 4.12 +/- 0.61, and 4.65 +/- 0.65 min, respectively. No peaks interfering with quantitation were observed throughout the validation processes. Mean recoveries of AT, o-AT, and p-AT from plasma ranged 100%-107%, 70.6%-104%, and 47.6%-85.6%, respectively. Mean recoveries of the [d5]-AT and [d5]-o-AT internal standards ranged 98.0%-99.9% and 97.3%, respectively. Interassay precision, based on the percent relative deviation for replicate quality controls for AT, o-AT, and p-AT, was < or = 7.19%, 8.28%, and 12.7%, respectively. Interassay accuracy for AT, o-AT, and p-AT was +/- 10.6%, 5.86%, and 15.8%, respectively. AT, o-AT, and p-AT in human, dog, and rat plasma quality controls were stable to three freeze-thaw cycles. AT, o-AT, and p-AT were stable frozen for 127, 30 and 270 days in human, dog, and rat plasma quality control samples, respectively. Human plasma quality control samples containing AT, o-AT, and p-AT were stable for at least 4 days at ambient room temperature and 37 degrees C. The lower limit of quantitation for all analytes was 0.250 ng/mL for a 1.0-mL sample aliquot.

Validated HPLC/MS/MS assay for CI-1011 in rat plasma and a comparison with an HPLC/UV assay.

A liquid chromatographic/mass spectrometric (LC/MS/MS) method to quantitate CI-1011 in rat plasma has been validated and compared to an LC/UV assay. The analyte and internal standard were isolated from the plasma matrix by using liquid/liquid extraction with diethyl ether. The ether layer was evaporated to dryness and the residue reconstituted in acetonitrile-water (70:30, v/v). A 2.1 x 150 mm x 5 microns Zorbax RX-C18 column with a mobile phase of acetonitrile-ammonium acetate (pH 8.0; 5 mM)-triethylamine (70:30:0.03, v/v/v) delivered at a flow rate of 0.2 ml min-1 was used for chromatography. Analyte and internal standard ion chromatograms were obtained by operating the mass spectrometer in the negative ion multiple reaction monitoring mode to detect the presence of a precursor-product ion pair for both the analyte and the internal standard. Samples were introduced into the mass spectrometer using electrospray ionization. Retention times of CI-1011 and of the internal standard (IS), [13C6]CI-1011, were approximately 4.2 min. No peaks interfering with the quantitation of CI-1011 were observed throughout the validation process. Mean recoveries of CI-1011 from rat plasma ranged from 98.2 to 105%. The recovery of the IS was 100%. Assay precision for CI-1011, based on the percent relative standard deviation of replicate quality controls, was less than or equal to 5.60% with an accuracy of +/- 8.80%. The lower limit of quantitation for CI-1011 was 0.500 ng ml-1 for a 0.2-ml sample aliquot. CI-1011 is stable in rat plasma for 24 h at room temperature and for at least 34 days at -20 degrees C. This assay has been proven suitable for routine quantitation of CI-1011 in rat plasma at concentrations from 0.500 (100 pg on-column) to 500 ng ml-1. The applicability of this method to determine CI-1011 concentrations in rat plasma is reported in this manuscript. CI-1011 concentrations, in plasma samples from cholesterol- and chow-fed rats administered single daily oral doses of CI-1011 in a CMC/Tween suspension, obtained using a validated LC/UV assay were compared to concentrations obtained using the reported LC/MS/MS assay over the concentration range 0.0806-12.3 micrograms ml-1. The concordance correlation coefficient determined for this comparison was 0.9977, suggesting that the CI-1011 concentrations obtained by the two assays are in excellent agreement.

Metabolism and excretion studies in mouse after single and multiple oral doses of the 3-hydroxy-3-methylglutaryl-CoA reductase inhibitor atorvastatin.

Atorvastatin, [(R-(R,R)]-2-(4-fluorophenyl)-beta, delta-dihydroxy-5-(1-methylethyl)-3-phenyl-4-[(phenyl-amino)carbonyl] -1H-pyrrole-1-heptanoic acid calcium salt (CI-981, AT), is a second generation 3-hydroxy-3-methylglutaryl-CoA reductase inhibitor approved for clinical use as a cholesterol lowering agent. The disposition and metabolism of AT, including potential CYP450 induction, was investigated in mice administered an oral dose of [14C]AT (free acid) on study days 1 and 14. Peak plasma radioactivity concentrations occurred 1 hr postdose after both single- and multiple-dose administration and declined rapidly thereafter. Total plasma radioactivity levels in mice receiving the multiple dose were approximately 50% of levels observed after single-dose administration. Plasma metabolic profiles, which provided evidence of extensive metabolism, remained similar. Feces was the major route of AT-derived radioactivity elimination. Fecal profiles showed extensive metabolism with qualitatively similar profiles after single- and multiple-dose administration; however, quantitative differences were apparent. Metabolites identified in plasma and feces include hydroxylated, beta-oxidized, and unsaturated derivatives of AT. Most metabolites had undergone beta-oxidation. In mice receiving multiple 1 mg/kg doses of AT, no effect on spectral P450 concentration was found, and only a minor increase was observed at the 200 mg/kg dose level. Catalytic activities of CYP4501A, -2B, and -3A were not significantly affected; CYP4A activity decreased in a dose-dependent manner. Administration of multiple doses resulted in lower systemic plasma levels of total AT-derived radioactivity not readily explained by these studies. In mice, the majority of metabolites are formed primarily through the beta-oxidation pathway.

Inactivation of cytochrome P450 3A4 by bergamottin, a component of grapefruit juice.

Grapefruit juice has been found to significantly increase oral bioavailability of several drugs metabolized by cytochrome P450 3A4 (P450 3A4) through inhibiting the enzymatic activity and decreasing the content of intestinal P450 3A4. HPLC/MS/MS and HPLC/UV analyses of ethyl acetate extracts from grapefruit juice revealed the presence of several furanocoumarins of which bergamottin (BG) is the major one. BG was shown to inactivate P450 3A4 in a reconstituted system consisting of purified P450 3A4, NADPH-cytochrome P450 reductase, cytochrome b5, and phospholipids. Inactivation was time- and concentration-dependent and required metabolism of BG. The loss of catalytic activity exhibited pseudo-first-order kinetics. The values of kinactivation and KI calculated from the inactivation studies were 0.3 min-1 and 7.7 microM, respectively. While approximately 70% of the erythromycin N-demethylation activity was lost during incubation with BG in the reconstituted system, P450 3A4 retained more than 90% of the heme as determined either by UV-visible spectroscopy or by HPLC. However, approximately 50% of the apoP450 in the BG-inactivated P450 3A4 incubation mixture could not be recovered from a reverse-phase HPLC column when compared with the -NADPH control. The mechanism of the inactivation appears to involve modification of the apoP450 in the active site of the enzyme instead of heme adduct formation or heme fragmentation. These results indicate that BG, the primary furanocoumarin extracted from grapefruit juice, is a mechanism-based inactivator of P450 3A4. BG was also found to inhibit the activities of P450s 1A2, 2A6, 2C9, 2C19, 2D6, 2E1, and 3A4 in human liver microsomes.

In vitro assessment of oral delivery for hexapeptide endothelin antagonists.

Endothelin (ET-1) is a 21-amino acid, vasoconstrictive peptide originally isolated from endothelial cells. It is one member of a class of potent, purportedly paracrine substances that act at receptors in multiple target organs. Antagonists to the receptor subtypes, ETA and ETB, have been designed around the hydrophobic carboxy-terminus of ET-1. The resulting hexapeptides possess low nanomolar receptor affinity, but face formidable challenges to oral delivery, given their peptidic nature. Hence, it was important to discriminate between analogs, as well as to optimize structural features combining binding potency with stability in intestinal fluids and permeability across biological membranes. PD 142893 (Ac-DDip16-Leu-Asp-Ile-Trp21) and PD 145065 (Ac-DBhg16-Leu-Asp-Ile-Ile-Trp21), as well as the N-methyl-isoleucine20 analogs were studies, where DDip = 3,3diphenylalanine and DBhg = 10,11-dihydro-5H-dibenzo[a,d]cycloheptene glycine. Analyses were conducted with specific HPLC methods. Permeabilities across CACO-2 cell monolayers ranged from 2.0x10(-4) to 6.3x10(-4)cm/min. The results suggested that these compounds can be absorbed in vivo, based on comparison of permeabilities with those obtained with reference compounds. Much greater differences were observed between the analogs when stability half-lives were compared after incubation in rat intestinal perfusate. The parent peptides, PD 142893 and PD 145065, were unstable, with half-lives less than 20 min. N-Methylation of Ile20 resulted in large increases in stability half-lives to greater 500 min. Enzyme inhibition studies demonstrated the involvement of carboxypeptidase A in production of the primary metabolite, the des-Trp derivative. Identification of the primary metabolite of the parent peptide was made by differential UV scanning at 214/280 nm and mass spectral analyses.

Identification, characterization and pharmacological profile of three metabolites of (R)-(+)-1,2,3,6-tetrahydro-4-phenyl-1-[(3-phenylcyclohexen-1- yl)methyl]pyridine (CI-1007), a dopamine autoreceptor agonist and potential antipsychotic agent.

Liquid chromatographic-mass spectrometric (LC-MS) analysis of plasma taken from cynomolgus monkeys dosed orally with (R)-(+)-1,2,3,6-tetrahydro-4-phenyl-1-[(3-phenylcyclohexen-1- yl)methyl]pyridine (1), a dopamine (DA) autoreceptor agonist and potential antipsychotic agent, revealed several metabolites. The molecular masses of three major metabolites suggested that they were mono- and dihydroxylated derivatives of 1. We synthesized compounds 2 and 3, the two possible mono-p-hydroxyphenyl derivatives of 1, along with the bis-p-hydroxyphenyl derivative 4. These compounds coeluted by HPLC with the three hydroxylated metabolites of 1. Compounds 2-4 all had high affinities for DA D2 and D3 receptors and moderate affinities for D4 receptors. Like 1, compound 2 decreased DA synthesis and neuronal firing in rat brain, indicative of DA autoreceptor activation. Compound 2 inhibited exploratory locomotor activity in rodents and was active in the Sidman avoidance test in squirrel monkeys, predictive of antipsychotic activity in humans. Compounds 3 and 4 showed weak activity in all these tests. After squirrel monkeys were dosed with 1 orally at the ED100 dose of the Sidman avoidance test, the plasma concentration of 2 was below the limit of quantitation. Therefore, these metabolites are unlikely to contribute greatly to the potent activity seen with 1 in the Sidman avoidance test.

Species variation in the bioactivation of tacrine by hepatic microsomes.

1. The metabolite profile of tacrine (1,2,3,4-tetrahydro-9-amino acridine) was similar in hepatic microsomes from man, rat, dog, rabbit, mouse and hamster. Major metabolites were 1-, 2-, 4- and 7-OH tacrine. Only quantitative differences in metabolite profile were evident between species. 2. Bioactivation to protein-reactive metabolite(s) was seen in microsomes from all species. 3. 7-Methyl tacrine was found to undergo significantly less bioactivation than either 7-OH tacrine or tacrine itself. 4. In the presence of hepatic microsomes and thiol-containing agents protein-reactive metabolite formation was significantly reduced. With mercaptoethanol present a stable thioether adduct was generated from both tacrine and 7-OH tacrine. 5. Analysis of the thioether adduct by mass spectrometry yielded a molecular ion of m/z 290 consistent with the presence of a covalent adduct of 7-OH tacrine complexed in a 1:1 molar ratio with mercaptoethanol. 6. We have therefore provided further evidence for a two-step mechanism in the bioactivation of tacrine involving an initial 7-hydroxylation followed by a postulated 2-electron oxidation to yield a reactive quinone methide. This mechanism of bioactivation appears to be identical in human and animal hepatic microsomes.

Isolation and Preliminary Characterization of Hydroxamic Acids Formed by Nitrogen-Fixing Azotobacter chroococcum B-8.

The free-living diazotroph Azotobacter chroococcum B-8 responded to iron-limited growth conditions by forming hydroxamic acids and an 85,000-dalton outer membrane protein. The Fe(III)-binding hydroxamate compounds stimulated the growth of Arthrobacter flavescens JG-9 and gave a positive Csaky reaction for bound hydroxylamines. The hydroxamates were isolated from liquid cultures by benzyl alcohol extraction and purified by size exclusion chromatography and high-performance liquid chromatography. Four high-performance liquid chromatography fractions, designated A, B, C, and D, had the characteristic hydroxamate absorption maximum at 420 to 423 nm, which did not shift over a pH range from 3.0 to 9.0. Cyclic voltammograms of the iron-hydroxamate complexes exhibited reduction potentials of -0.426 to -0.442 V for fractions A, B, and D and of -0.56 V for fraction C versus the normal hydrogen electrode at pH 8.0. Based on mass spectra, nominal molecular weights of 800 and 844 were assigned to ferrated compounds A and B, respectively. Reductive hydrolysis of compounds A and B in 57% hydriodic acid yielded ornithine as detected by gas chromatography-mass spectrometry. All of these physiological and chemical data strongly support the hypothesis that the high-affinity iron-binding compounds isolated from A. chroococcum B-8 are hydroxamic acids and probably function as siderophores for this diazotroph.

Structural determination of a cyclic metabolite of NAD+ with intracellular Ca2+-mobilizing activity.

Incubation of NAD+ with extracts from sea urchin eggs resulted in production of a metabolite which could mobilize intracellular Ca2+ stores of the eggs. In this study we present structural evidence indicating that the metabolite is a cyclized ADP-ribose having an N-glycosyl linkage between the anomeric carbon of the terminal ribose unit and the N6-amino group of the adenine moiety. In view of this structure we propose cyclic ADP-ribose as the common name for the metabolite. The purification procedure for the metabolite consisted of deproteinizing the incubated egg extracts and sequentially chromatographing the extracts through three different high pressure liquid chromatography (HPLC) columns. The homogeneity of the purified metabolite was further verified by HPLC on a Partisil 5 SAX column. Using radioactive precursor NAD+ with label at various positions it was demonstrated that the metabolite was indeed derived from NAD+ and that the adenine ring as well as the adenylate alpha-phosphate were retained in the metabolite whereas the nicotinamide group was removed. This was confirmed by 1H NMR and two-dimensional COSY experiments, which also allowed the identification of all 12 protons on the two ribosyl units as well as the two protons on the adenine ring. From the chemical shifts of the two anomeric protons it was concluded that the C-1 carbons of both ribosyl units were still bonded to nitrogen. The positive and negative ion fast atom bombardment mass spectra showed (M + Na)+, (M - H + 2Na)+, (M - H)-, and (M - 2H + Na)- peaks at m/z 564, 586, 540, and 562, respectively. Exact mass measurements indicated a molecular weight of 540.0526 for (M - H)-. This together with the constraints imposed by the results from NMR, radioactive labeling, and total phosphate determination uniquely specified a molecular composition of C15H21N5O13P2. Analysis by 1H NMR and mass spectroscopy of the only major breakdown product of the metabolite after prolonged incubation at room temperature established that it was ADP-ribose, thus providing strong support for the cyclic structure.

Identification of the V factor needed for synthesis of the iron-molybdenum cofactor of nitrogenase as homocitrate.

Nitrogenase catalyses the ATP-dependent reduction of N2 to NH3, and is composed of two proteins, dinitrogenase (MoFe protein or component I) and dinitrogenase reductase (Fe protein or component II). Dinitrogenase contains a unique prosthetic group (iron-molybdenum cofactor, FeMoco) comprised of Fe, Mo and S, which has been proposed as the site of N2 reduction. Biochemical and genetic studies of Nif- (nitrogen fixation) mutants of Klebsiella pneumoniae which are defective in nitrogen fixation, have shown that the nifB, nifQ, nifN, nifE and nifV genes are required for the biosynthesis of FeMo-co. Recently, a system for in vitro synthesis of FeMoco was described. The assay requires at least the nifB, nifN and nifE gene products, and a low-molecular-weight factor (V factor) produced in the presence of the nifV gene product. We have used this system to study FeMoco biosynthesis. We report here the isolation of V factor and identify it as homocitric acid ([R]2-hydroxy-1,2,4-butanetricarboxylic acid).