Influence of palmitate and benzoate on the unidirectional chiral inversion of ibuprofen in isolated rat hepatocytes

Unidirectional inversion of ibuprofen in Caco-2 cells: developing a suitable model for presystemic chiral inversion study

Intestinal chiral inversion of ibuprofen is still lacking direct evidence. In a preliminary experiment, ibuprofen was found to undergo inversion in Caco-2 cells. This investigation was thus conducted to determine the characteristics and influence of some biochemical factors on the chiral inversion of ibuprofen in Caco-2 cells. The effects of substrate concentration (2.5-40 microg/ml), cell density (0.5-2 x 10(6) cells/well), content of serum (0-20%), coexistence of S ibuprofen (corresponding doses), sodium azide (10 mM), exogenous Coenzyme A (CoA) (0.1-0.4 mM), and palmitic acid (5-25 microM) on inversion were examined. A stereoselective HPLC method based on the Chromasil-CHI-TBB column was developed for quantitative analysis of the drug in cell culture medium. The inversion ratio (F(i)) and elimination rate constant were calculated as the indexes of inversion extent. Inversion of ibuprofen in Caco-2 cells was found to be both dose and cell density dependent, indicating saturable characteristics. Addition of serum significantly inhibited the inversion, to an extent of 2.7 fold decrease at 20% content. Preexistence of S enantiomer exerted a significant inhibitory effect (p<0.01 for all tests). Sodium azide decreased the inversion ratio from 0.43 to 0.32 (p<0.01). Exogenous CoA and palmitic acid significantly promoted the inversion at all tested doses (p<0.01 for all tests). This research provided strong evidence to the capacity and capability of intestinal chiral inversion. Although long incubation times up to 120 h were required, Caco-2 cells should be a suitable model for chiral inversion research of 2-APAs considering the human-resourced and well-defined characteristics from the present study.

Bioinversion ofR-flurbiprofen toS-flurbiprofen at various dose levels in rat, mouse, and monkey

Information about the potential and extent of bioinversion of chiral drugs in laboratory animal species and humans is critical to the interpretation of preclinical pharm-tox studies with these drugs. Unlike in the dog, guinea pig, and rabbit, in humans the 2-arylpropionic acid (APA) R-flurbiprofen (R-FB) undergoes very little bioinversion to S-flurbiprofen. The primary objective of this research was to identify laboratory animal species with an R- to S-bioinversion profile similar to humans. Detailed evaluations of the pharmacokinetics parameters of R-flurbiprofen in male and female rats and mice, and male nude rats and monkeys demonstrated R- to S-bioinversion of 30% (average) in monkeys, 15-24% in mice, and approximately 4% in rats. To date, no laboratory animal species has been identified with an R-flurbiprofen bioinversion profile identical to humans. However, the rat has a bioinversion profile sufficiently similar to humans to be useful for preclinical.

Microbial deracemization of alpha-substituted carboxylic acids: substrate specificity and mechanistic investigation

A new enzymatic method for the preparation of optically active alpha-substituted carboxylic acids is reported. This technique is called deracemization reaction, which provides us with a route to obtain the enantiomerically pure compounds, theoretically in 100% yield starting from the racemic mixture. This means that the synthesis of a racemate is almost equal to the synthesis of the optically active compound, and this concept is entirely different from the commonly accepted one in the asymmetric synthesis. Using the growing cell system of Nocardia diaphanozonaria JCM3208, racemates of 2-aryl- and 2-aryloxypropanoic acid are deracemized smoothly and (R)-form-enriched products are recovered in high chemical yield (>50%). In addition, using optically active starting compounds and deuterated derivatives as well as inhibitors, we have disclosed the fact that a new type of enzyme takes part in this biotransformation, and that the reaction proceeds probably via the same mechanism as that in rat liver.

Role of hepatic fatty acid:coenzyme A ligases in the metabolism of xenobiotic carboxylic acids

1. Formation of acyl-coenzymes (Co)A occurs as an obligatory step in the metabolism of a variety of endogenous substrates, including fatty acids. The reaction is catalysed by ATP-dependent acid:CoA ligases (EC 6.2.1.1-2.1.3; AMP forming), classified on the basis of their ability to conjugate saturated fatty acids of differing chain lengths, short (C2-C4), medium (C4-C12) and long (C10-C22). The enzymes are located in various cell compartments (cytosol, smooth endoplasmic reticulum, mitochondria and peroxisomes) and exhibit wide tissue distribution, with highest activity associated with liver and adipose tissue. 2. Formation of acyl-CoA is not unique to endogenous substrates, but also occurs as an obligatory step in the metabolism of some xenobiotic carboxylic acids. The mitochondrial medium-chain CoA ligase is principally associated with metabolism via amino acid conjugation and activates substrates such as benzoic and salicylic acids. Although amino acid conjugation was previously considered an a priori route of metabolism for xenobiotic-CoA, it is now recognized that these highly reactive and potentially toxic intermediates function as alternative substrates in pathways of intermediary metabolism, particularly those associated with lipid biosyntheses. 3. In addition to a role in fatty acid metabolism, the hepatic microsomal and peroxisomal long-chain-CoA-ligases have been implicated in the formation of the acyl-CoA thioesters of a variety of hypolipidaemic and peroxisome proliferating agents (e.g. clofibric acid) and of the R(-)-enantiomers of the commonly used 2-arylpropionic acid non-steroidal anti-inflammatory drugs (e.g. ibuprofen). In vitro kinetic studies using rat hepatic microsomes and peroxisomes have alluded to the possibility of xenobiotic-CoA ligase multiplicity. Although cDNA encoding a long-chain ligase have been isolated from rat and human liver, there is currently no molecular evidence of multiple isoforms. The gene has been localized to chromosome 4 and homology searches have revealed a significant similarity with enzymes of the luciferase family. 4. Increasing recognition that formation of a CoA conjugate increases chemical reactivity of xenobiotic carboxylic acids has led to an awareness that the relative activity, substrate specificity and intracellular location of the xenobiotic-CoA ligases may explain differences in toxicity. 5. Continued characterization of the human xenobiotic-CoA ligases in terms of substrate/inhibitor profiles and regulation, will allow a greater understanding of the role of these enzymes in the metabolism of carboxylic acids.

Mechanistic studies on metabolic chiral inversion of 4-(4-methylphenyl)-2-methylthiomethyl-4-oxobutanoic acid (KE-748), an active metabolite of the new anti-rheumatic agent 2-acetylthiomethyl-4-(4-methylphenyl)-4-oxobutanoic acid (KE-298), in rats

The chiral inversion properties of 4-(4-methylphenyl)-2-methylthiomethyl-4-oxobutanoic acid (KE-748), an active metabolite of 2-acetylthiomethyl-4-(4-methylphenyl)-4-oxobutanoic acid (KE-298), were compared with those of ibuprofen in rats. After administration of R(-)-[2 alpha-2H]KE-748, S(+)-KE-748 was present in the rat plasma, and the deuterium atoms of the S(+)-enantiomer were almost all replaced by hydrogen atoms. After administration of S(+)-[2 alpha-2H]KE-748, the deuterium content of S(+)-KE-748 in the plasma remained intact. In the in vitro study, using a cell-free system and rat liver homogenates, the chiral inversion of ibuprofen was apparent when both CoA and ATP were present; however, KE-748 was not inverted. In the study on isolated rat hepatocytes, the unidirectional chiral inversion from R(-)-to S(+)-enantiomer was observed for both ibuprofen and KE-748. When R(-)-ibuprofen was incubated with medium and long chain fatty acids (carbon chain length C6 to C16), using isolated hepatocytes, the chiral inversion decreased significantly. On the other hand, when R(-)-KE-748 was incubated with short and medium chain fatty acids (carbon chain length C3 to C8), chiral inversion was inhibited markedly. To induce hepatic microsomal long chain fatty acid CoA ligase, rats were treated with clofibric acid (CF rats). In both in vitro and in vivo experiments on CF rats, chiral inversion from R(-)-to S(+)-ibuprofen was enhanced significantly compared with that in controls, whereas the enhancement was not observed in the case of R(-)-KE-748. There was no influence of benzoic acid, a typical substrate on medium chain fatty acid CoA ligase in the mitochondrial matrix, on chiral inversion of R(-)-ibuprofen, using, isolated hepatocytes. In contrast, the chiral inversion from R(-)-to S(+)-KE-748 was strongly inhibited in the presence of benzoic acid. These results indicate that chiral inversion of R(-)-KE-748 may proceed via formation of the CoA-thioester intermediate with loss of the 2 alpha-methine proton, in a manner similar to that seem with R(-)-ibuprofen. However, the enzymes needed to form CoA-thioester of R(-)-KE-748 differ from those for R(-)-ibuprofen.

Lack of effect of gender and oral contraceptive steroids on the pharmacokinetics of (R)-ibuprofen in humans

The effects of gender and oral contraceptive steroids on the pharmacokinetics of (R)-ibuprofen were studied in groups of healthy adult males, females and oral contraceptive steroid (OCS) using females. The values of AUC, CLpo, t1/2 and Vss, app did not differ significantly between the groups. Similarly, the percentage unbound of (R)-ibuprofen in pooled plasma from the three groups was not statistically different. Since chiral inversion is the major determinant of (R)-ibuprofen clearance in humans, it may be inferred from these data that gender and OCS have little or no effect on conversion of (R)-ibuprofen to the pharmacologically active S-enantiomer. Moreover, it is unlikely that hormonal factors influence the activity of the human hepatic long-chain fatty-acid:CoA ligase, the enzyme mediating the rate limiting step of (R)-ibuprofen inversion.

Drug chirality: on the mechanism of R-aryl propionic acid class NSAIDs. Epimerization in humans and the clinical implications for the use of racemates

This review summarizes and comments on the current understanding of both the biochemical and clinical implications of the epimerization of R-aryl propionic (APA) class (1) nonsteroidal anti-inflammatory agents (NSAIDs) to S-enantiomers in humans. This article focuses principally on rac-ibuprofen and its enantiomers. In the United States, five commercialized NSAIDs are APAs. Only two of them, rac-ibuprofen and rac-fenoprofen, are subject to significant epimerization in humans. The remaining three, rac-flurbiprofen, rac-ketoprofen, and S-naproxen, are not of interest in this context.

Non-steroidal anti-inflammatory drugs and spinal nociceptive processing

Non-steroidal anti-inflammatory drugs have a direct action on spinal nociceptive processing in vivo with a relative order of potency which correlates with their capacity as inhibitors of cyclooxygenase activity. However, recent clinical surveys and new in vivo evidence strongly suggest that for some of these agents, centrally mediated analgesia may also be achieved by additional mechanisms, which are independent of prostaglandin synthesis inhibition. In this review we explore the likelihood for such mechanisms following an extensive survey of existing data. The implications of these mechanisms are discussed in the light of our current understanding of spinal nociceptive processing.

Is the formation of R-ibuprofenyl-adenylate the first stereoselective step of chiral inversion?

Coenzyme A thioester formation is reported to be the first step of chiral inversion of R-ibuprofen. In order to investigate the mechanism of this reaction adenylate derivatives of the ibuprofen enantiomers were synthesized chemically. R- and S-ibuprofenyl-adenylates as well as free acids were incubated with rat liver mitochondria in the presence of coenzyme A, MgCl2 with or without ATP. The optical antipodes formed by inversion and the coenzyme A thioester derivatives of both enantiomers were found after incubation of both R- or S-ibuprofenyl-adenylate and R-ibuprofen. By contrast, after incubation with S-ibuprofen neither R-enantiomer nor coenzyme A thioesters were detected. These experiments suggest that the formation of R-ibuprofenyl-adenylate may be the first stereoselective step of chiral inversion.

Is the inversion from R- to S-ketoprofen concentration dependent? Investigations in rats in vivo and in vitro

The effects of dose on the pharmacokinetics of ketoprofen (KT) enantiomers were investigated in rats in vivo and in hepatoma cells in continuous culture in vitro following administration of the optically pure enantiomers and the racemate of KT. With the exception of AUC (area under the curve) no pharmacokinetic differences could be found following i.v. administration of various doses of KT enantiomers (2.5, 5 and 10 mg/kg) and of racemic KT (5, 10 and 20 mg/kg) and between single enantiomer and racemate administration in rats in vivo. Independent of the dose administered the fraction inverted was about 66%. In line with the findings in vivo good correlation between incubation concentration and AUC of R- and S-KT was found in the hepatoma cells in vitro. The ratios of AUC(S)/AUC(R) were not significantly affected by concentration after R-KT (2.5-20 micrograms/mL) and racemate incubation (5-40 micrograms/mL) in the concentration ranges investigated. However, unlike in rats in vivo enhanced inversion was observed following racemate as compared to single enantiomer incubation in vitro.

Xenobiotic acyl-CoA formation: evidence of kinetically distinct hepatic microsomal long-chain fatty acid and nafenopin-CoA ligases

Multiplicity of hepatic microsomal coenzyme A ligases catalyzing acyl-CoA thioester formation is an important factor for consideration in relation to the metabolism of xenobiotic carboxylic acids. In this study the kinetic characteristics of rat hepatic microsomal nafenopin-CoA ligase were studied and compared with those of long-chain fatty acid (palmitoyl) CoA ligase. The high affinity component of palmitoyl-CoA formation was inhibited by nafenopin (Ki 53 microM) and ciprofibrate (Ki 1000 microM). Analagous to palmitoyl-CoA, nafenopin-CoA formation was catalyzed by an apparent high affinity low capacity isoform (Km 6 +/- 2.5 microM, Vmax 0.33 +/- 0.12 nmol/mg per min) which was inhibited competitively by palmitic acid (mean Ki 1.7 microM, n = 5) and R-ibuprofen (mean Ki 10.8 microM, n = 5) whilst ciprofibrate and clofibric acid were ineffective as inhibitors. The intrinsic metabolic clearance of nafenopin to nafenopin-CoA (Vmax/Km 0.057 +/- 0.011 nmol/mg/min/ +/- M) was similar to that reported recently for the formation of ibuprofenyl-CoA by rat liver microsomes. Evidence of both a substantial difference between the Km and Ki for nafenopin and lack of commonality with regard to xenobiotic inhibitors suggests that the high affinity microsomal nafenopin-CoA and long-chain fatty acid-CoA ligases are kinetically distinct. Thus until the current 'long-chain like' xenobiotic-CoA ligases are fully characterised in terms of substrate specificity, inhibitor profile, etc, it will be impossible to rationalize (and possibly predict) the metabolism and hence toxicity of xenobiotic carboxylic acids forming acyl-CoA thioester intermediates.