5,6-epoxyretinoic acid is a physiological metabolite of retinoic acid in the rat

One-Step, Low-Cost, Operator-Friendly, and Scalable Procedure to Synthetize Highly Pure N-(4-ethoxyphenyl)-retinamide in Quantitative Yield without Purification Work-Up

It is widely reported that N-(4-hydroxyphenyl)-retinamide or fenretinide (4-HPR), which is a synthetic amide of all-trans-retinoic acid (ATRA), inhibits in vitro several types of tumors, including cancer cell lines resistant to ATRA, at 1–10 µM concentrations. Additionally, studies in rats and mice have confirmed the potent anticancer effects of 4-HPR, without evidencing hemolytic toxicity, thus demonstrating its suitability for the development of a new chemo-preventive agent. To this end, the accurate determination of 4-HPR levels in tissues is essential for its pre-clinical training, and for the correct determination of 4-HPR and its metabolites by chromatography, N-(4-ethoxyphenyl)-retinamide (4-EPR) has been suggested as an indispensable internal standard. Unfortunately, only a consultable old patent reports the synthesis of 4-EPR, starting from dangerous and high-cost reagents and using long and tedious purification procedures. To the best of our knowledge, no article existed so far describing the specific synthesis of 4-EPR. Only two vendors worldwide supply 4-ERP, and its characterization was incomplete. Here, a scalable, operator-friendly, and one-step procedure to synthetize highly pure 4-EPR without purification work-up and in quantitative yield is reported. Additionally, a complete characterization of 4-EPR using all possible analytical techniques has been provided.

Uptake and metabolism of β-apo-8'-carotenal, β-apo-10'-carotenal, and β-apo-13-carotenone in Caco-2 cells

β-Apocarotenoids are eccentric cleavage products of carotenoids formed by chemical and enzymatic oxidations. They occur in foods containing carotenoids and thus might be directly absorbed from the diet. However, there is limited information about their intestinal absorption. The present research examined the kinetics of uptake and metabolism of β-apocarotenoids. Caco-2 cells were grown on 6-well plastic plates until a differentiated cell monolayer was achieved. β-Apocarotenoids were prepared in Tween 40 micelles, delivered to differentiated cells in serum-free medium, and incubated at 37°C for up to 8 h. There was rapid uptake of β-apo-8'-carotenal into cells, and β-apo-8'-carotenal was largely converted to β-apo-8'-carotenoic acid and a minor metabolite that we identified as 5,6-epoxy-β-apo-8'-carotenol. There was also rapid uptake of β-apo-10'-carotenal into cells, and β-apo-10'-carotenal was converted into a major metabolite identified as 5,6-epoxy-β-apo-10'-carotenol and a minor metabolite that is likely a dihydro-β-apo-10'-carotenol. Finally, there was rapid cellular uptake of β-apo-13-carotenone, and this compound was extensively degraded. These results suggest that dietary β-apocarotenals are extensively metabolized in intestinal cells via pathways similar to the metabolism of retinal. Thus, they are likely not absorbed directly from the diet.

Macular degeneration: a possible biochemical mechanism

The possible role of labile endogenous metabolites in the cause of various chronic debilitating diseases such as macular degeneration has not been adequately explored. In the metabolism of the various retinoids, namely retinal (vitamin A aldehyde), retinol (vitamin A alcohol) and retinoic acid, each has the potential for generating labile intermediates, such as their corresponding 5,6-epoxides by the action of various cytochrome P(450)s. Such retinoid epoxides may well have the capacity for acting as toxins upon the neurons in the macula unless they are rapidly hydrolyzed by epoxide hydrolases. Since the cytochrome P(450)s responsible for epoxide formation and the various epoxide hydrolases involved in their hydrolysis are determined genetically, this may serve to explain a genetic component being involved in the causation of age-related macular degeneration.

4-hydroxyretinoic acid, a novel substrate for human liver microsomal UDP-glucuronosyltransferase(s) and recombinant UGT2B7

It is suggested that formation of more polar metabolites of all-trans-retinoic acid (atRA) via oxidative pathways limits its biological activity. In this report, we investigated the biotransformation of oxidized products of atRA via glucuronidation. For this purpose, we synthesized 4-hydroxy-RA (4-OH-RA) in radioactive and nonradioactive form, 4-hydroxy-retinyl acetate (4-OH-RAc), and 5,6-epoxy-RA, all of which are major products of atRA oxidation. Glucuronidation of these retinoids by human liver microsomes and human recombinant UDP-glucuronosyltransferases (UGTs) was characterized and compared with the glucuronidation of atRA. The human liver microsomes glucuronidated 4-OH-RA and 4-OH-RAc with 6- and 3-fold higher activity than atRA, respectively. Analysis of the glucuronidation products showed that the hydroxyl-linked glucuronides of 4-OH-RA and 4-OH-RAc were the major products, as opposed to the formation of the carboxyl-linked glucuronide with atRA, 4-oxo-RA, and 5,6-epoxy-RA. We have also determined that human recombinant UGT2B7 can glucuronidate atRA, 4-OH-RA, and 4-OH-RAc with activities similar to those found in human liver microsomes. We therefore postulate that this human isoenzyme, which is expressed in human liver, kidney, and intestine, plays a key role in the biological fate of atRA. We also propose that atRA induces its own oxidative metabolism via a cytochrome P450 (CYP26) and is further biotransformed into glucuronides via UGT-mediated pathways.

Regiospecificity of peroxyl radical addition to (E)-retinoic acid

The regiochemistry of peroxyl radical addition to (E)-retinoic acid (RA) was investigated. Peroxyl radicals, generated by reaction of 13-hydroperoxy-(9Z,11E)-octadecadienoic acid with hydroxo(porphyrinato)iron(III) in Tween 20 micelles, were reacted with RA. The major, and virtually exclusive, RA oxidation product was 5,6-epoxy-RA which was identified on the basis of cochromatography with the synthetic synthetic oxirane (in a reverse phase HPLC system), electronic absorption spectroscopy, high-field 1H-NMR, and EI mass spectrometry. These results suggest that peroxyl radicals react with RA by regioselective addition to either C5 or C6 yielding an endocyclic tertiary allylic or tertiary carbon-centered radical adduct, respectively. Subsequent beta-elimination of an alkoxyl radical yields the oxirane. Computational studies were carried out in order to gain mechanistic insights into the observed regiospecificity of the peroxyl radical-dependent epoxidation reaction; molecular mechanics and semiempirical quantum mechanical calculations were carried out using Tripos force field parameters and AM1, respectively. The results suggest that the regiospecific epoxidation may be influenced by the 5,6-olefinic function behaving as a partially-isolated double bond as well as inherent allylic A1,2 strain in the substituted cyclohexene ring as a consequence of substitutions at C1 and C6. In addition, calculated heats of formation indicated preferential peroxyl radical addition to C5 versus C6; this may reflect differences in the geometries of sp2-orbitals containing the radical densities rather than resonance contributions by the highly conjugated polyene system.

Metabolism in vivo of all-trans-[11-3H]retinoic acid after an oral dose in rats. Characterization of retinoyl beta-glucuronide in the blood and other tissues

Soon after [11-3H]retinoic acid (RA) (1.1 x 10(8) d.p.m.) was administered orally to rats either as a large dose (115 micrograms = 0.38 mumol/rat) or mixed with unlabelled RA as a huge dose (22 mg = 73.33 mumol/rat), retinoyl beta-glucuronide (RAG) was identified and characterized as a significant metabolite in the serum and small intestine. Of the administered dose, 70% remained unchanged as retinoic acid in the stomach up to 1 h. Significant amounts of 5,6-epoxyretinoic acid, 4-hydroxyretinoic acid, esters of retinoic acid and several polar retinoids, including 4-oxoretinoic acid, were also detected in the stomach. No significant difference was observed in the nature of the retinoids found after a large or a huge dose; however, the ratio of RAG/RA was higher after a huge dose than after a large dose. Thus RAG, which is biologically active in vivo and in vitro, is formed quickly in significant amounts in tissues after a dose of RA.

Chromatography of retinoids

This article reviews the determination of retinoic acids and their metabolites (first-generation retinoids), aromatic retinoids (second generation) and arotinoids (third generation) in biological samples. Because of the sensitivity of the retinoids to isomerization and oxidation, special care has to be taken from sample collection and storage, throughout extraction, till the final chromatographic separation. High and strong protein binding, and insolubility in aqueous solutions hamper the extraction from biological samples. Various extraction procedures are discussed, mainly involving liquid-liquid extraction of biological fluids or lyophilized tissue samples. The new technique involving direct injection of biological fluids or tissue homogenates, using high-performance liquid chromatography (HPLC) with automated column switching, provides full protection from light and simplifies sample work-up. HPLC with ultraviolet detection is the method of choice for the determination of retinoids, because it is rapid, sensitive and allows separation of geometric isomers and metabolites within a wide polarity range. Gas chromatography-mass spectrometry is not appropriate for first- and second-generation retinoids because of isomerization, but allows very sensitive determination of third-generation retinoids, although very extensive sample clean-up and derivatization are necessary. However, direct injection of large volumes of biological fluids into HPLC systems, using on-line solid-phase extraction and automated column-switching, results in very sensitive methods even with simple ultraviolet detection and may become the method of choice for routine analyses.

Synthesis and metabolism of all-trans-[11-3H]retinyl beta-glucuronide in rats in vivo

All-trans-[11-3H]retinyl beta-glucuronide (all-trans-[11-3H]ROG) was synthesized from [3H]retinol by an improved synthetic procedure. After its intraperitoneal injection into rats, ROG is initially found as the predominant labelled component in the serum, but then is distributed to the liver, intestine, kidney and other organs of the body. Esters of vitamin A, which constituted the major metabolite of ROG, were detected in the liver as well as in other tissues. Of the labelled vitamin A esters derived from tritiated ROG in the liver and intestine, about 50% contained 5,6-epoxyretinol, which was characterized by its chromatographic behaviour, formation of an acetyl ester and lack of reactivity with diazomethane. Thus ROG, although converted to retinol in vivo, might also act physiologically in an intact form.

Lack of biological activity of physiological metabolites of all-trans-retinoic acid on vaginal epithelial differentiation

It has been of interest to determine whether the metabolites of physiological doses of retinoic acid represent active forms of vitamin A. Previous work (Biochem. J. 206, 33-41, 1982) studied the metabolites produced from 2-micrograms doses of all-trans-retinoic acid in the vitamin A-deficient rat. Four major metabolites common to all of the tissues studied were discovered. In the present work, three of these metabolites are isolated from vitamin A-deficient rats given physiological doses (5 micrograms) of all-trans-retinoic acid and from vitamin A-sufficient rats given high doses (1 mg) of all-trans-retinoic acid. Cochromatography on anion-exchange and reverse-phase high-performance liquid chromatography showed that metabolites resulting from high doses of retinoic acid contained the metabolites generated from physiological doses of retinoic acid. Quantities of these metabolites were isolated, purified, and tested for their epithelial-differentiating activity in the vitamin A-deficient rat vagina. The metabolites were inactive at all dose levels tested. These metabolites have less than 10% the biological activity of all-trans-retinoic acid. Therefore, these metabolites appear to be products of the inactivation of all-trans-retinoic acid. Based upon these and previous data, it seems likely that all-trans-retinoic acid or its beta-glucuronide derivative is the most likely active form of vitamin A in the maintenance of normal epithelial differentiation.

In vivo metabolism of topically applied retinol and all-trans retinoic acid by the rabbit cornea

Corneas of normal and vitamin A-deficient rabbits were treated topically with [11, 12-3H] retinol or [11, 12-3H] all-trans retinoic acid. Methanol extracts of these corneas were analyzed by high pressure liquid chromatography. Radiolabeled compounds were extracted from the corneas which co-migrated chromatographically with known retinoid standards. In agreement with studies on other tissues and organs, retinol was metabolized to retinoic acid and more polar compounds by corneas of normal and vitamin A-deficient rabbits. All-trans retinoic acid was isomerized to 13-cis retinoic acid in normal rabbit corneas; however, this trans-cis isomerization did not occur in vitamin A-deficient, xerophthalmic corneas.

Metabolism of retinoic acid in vivo in the vitamin A-deficient rat

Sample preparation and high-pressure liquid-chromatography separation methods useful for the study of retinoic acid metabolism are reported. The sample preparation procedure does not cause significant degradation of retinoic acid, and the gradient high-pressure liquid-chromatography separation method gives excellent separation of the major metabolites of retinoic acid. These methods were used to examine the metabolites of retinoic acid in blood, trachea and lung, testes, kidneys and small intestine of vitamin A-deficient rats dosed subcutaneously with 2 micrograms of [11,12-3H] retinoic acid. At 6h after dosing, a total of eight metabolites of retinoic acid produced in vivo were found in the tissues examined. Of these, four were found in most of the epithelial tissues examined, and therefore may be of interest as possible active metabolites in the epithelial functions of vitamin A.

Tissue dependence of retinoic acid metabolism in vivo

Metabolites formed in vivo from [3H]retinoic acid dosed intrajugularly to vitamin A-deficient rats and to vitamin A-deficient rats supplemented orally with unlabeled retinoic acid were investigated. Extracts of liver, small intestinal mucosa, kidney, testes and serum were separated into charged uncharged fractions by DEAE-Sephadex. This allowed the direct application of 20-40% of the combined charged extracts from up to six organs to be loaded onto a high-performance liquid chromatography column. The large aliquot size plus the use of relatively high specific activity [3H]retinoic acid resulted in detection of nanomolar metabolite quantities. The substantial resolution achieved with the high-performance liquid chromatography gradient system aided in demonstrating the complexity, extent and variations of retinoic acid metabolism in vivo, The metabolic profiles changed with retinoic acid pretreatment, time after dose and tissue source. Some 3H-labeled metabolites were predominant in vitamin A-deficient animals; others appeared to be predominant in the retinoic acid-supplemented animals. The gross effect of retinoic acid supplementation was to both accelerate retinoic acid metabolism and cause an accumulation of more polar metabolites. It appears that retinoic acid metabolism in vivo is a complex process that occurs through multiple metabolites, which are, at least partially, tissue-specific.

The metabolism of retinoic acid to 5,6-epoxyretinoic acid, retinoyl-beta-glucuronide, and other polar metabolites

A description of the enzyme that produces 5,6-epoxyretinoic acid from all-trans-retinoic acid has been presented. This enzyme system is found in highest concentrations in the kidney followed by intestine, liver and spleen. The enzyme requires molecular oxygen, magnesium ions, ATP, and NADPH. In the kidney, it is found in the mitochondrial and microsomal fractions and has a Michaelis constant of 3.2 X 10(-6) M and 3.7 X 10(-6) M for 13-cis and all-trans-retinoic acid, respectively. The resultant product, 5,6-epoxyretinoic acid, has minimal activity in supporting growth of vitamin A-deficient rats, its activity estimated to be 0.5% that of retinoic acid. An investigation of the biliary excretion products of tritiated retinoic acid has revealed several unknown metabolites. A glucuronidase sensitive metabolite from these products has been isolated and identified as retinoyl-beta-glucuronide by ultraviolet absorption spectrometry and mass spectrometry. The retinoyl-beta-glucuronide originally discovered by Olson and collaborators accounts for only 12% of the total excreted biliary products of retinoic acid. At least four to six major unknown retinoic acid metabolites, in addition to retinoyl-beta-glucuronide, have been detected and will shortly be identified.