Biogenesis of retinoic acid from beta-carotene. Differences between the metabolism of beta-carotene and retinal

The ability of beta-carotene to serve as precursor to retinoic acid was examined in vitro with cytosol prepared from rat tissues. The rate of retinoic acid synthesis from 10 microM beta-carotene ranged from 120 to 224 pmol/h/mg of protein with intestinal cytosol, and from 344 to 488 pmol/h/mg of protein with cytosols prepared from kidney, lung, testes, and liver. Retinol generated during beta-carotene metabolism was not the major substrate for retinoic acid synthesis. At low substrate concentrations (2.5 microM), the rates of retinoic acid synthesis in intestinal cytosol from beta-carotene or retinol were equivalent, and at higher concentrations (10 microM) the rates of retinoic acid synthesis from beta-carotene or retinol in intestine, testes, lung, and kidney were comparable. Thus, beta-carotene metabolism may be an important source of retinoic acid in retinoid target tissues, particularly in species such as humans that are capable of accumulating high concentrations of tissue carotenoids. Retinal, considered an initial retinoid product of beta-carotene metabolism, was not detected as a product of beta-carotene metabolism in vitro. A ratio of retinol and retinoic acid different from that observed during beta-carotene metabolism in vitro was observed with incubations of retinal under identical conditions. These data indicated that beta-carotene metabolism is not merely a simple process of producing retinal and releasing it into solution to be metabolized independently.     

Distribution of endogenous retinoids,retinoid binding proteins (RBP,CRABPI) and nuclear retinoid X receptor beta (RXRbeta) in the porcine embryo

Retinoids are important signalling molecules in the development of limbs and in the determination of the anterior-posterior orientation of the embryo. The present study examined the content and distribution of retinoic acid, retinol and retinyl esters in porcine embryos during early gestation (gestation days 22-30) macroscopically and microscopically by its autofluorescence and by HPLC. Macroscopically, the yellowish-greenish autofluorescence characteristic of vitamin A was observed in tissues affected by morphogenesis, such as the limbs, in a spatial and temporal manner. Changes in the intensity of autofluorescence in the limbs paralleled changes in the concentration of retinoids in these structures. In the limbs and the body, retinol, retinyl palmitate, and all-trans-retinoic acid but neither the isomers of all-trans retinoic acid nor other retinoid metabolites were detected. In addition, the distribution of specific retinoid-binding proteins was investigated; these are involved in vitamin A transport, metabolism and signal transduction. Immunoreactive retinol-binding protein as well as cellular retinoic acid binding protein type I were only localised in the mesonephros, while the retinoid X receptor beta was widely distributed in most of the tissues and organs of the embryo throughout the time period investigated. The combination of autofluorescence and HPLC analysis allowed for the first time to attribute the yellowish-greenish autofluorescence in specific regions of the embryo to vitamin A, and offers a method to study the local cellular distribution of retinol and/or retinyl esters as well as their concentrations in embryonic tissues.     

Characterization of retinoid metabolism in the developing chick limb bud

Retinoids (vitamin A derivatives) have been shown to have striking effects on developing and regenerating vertebrate limbs. In the developing chick limb, retinoic acid is a candidate morphogen that may coordinate the pattern of cellular differentiation along the anteroposterior limb axis. We describe a series of investigations of the metabolic pathway of retinoids in the chick limb bud system. To study retinoid metabolism in the bud, all-trans-[3H]retinol, all-trans-[3H]retinal and all-trans-[3H]retinoic acid were released into the posterior region of the limb anlage, the area that contains the zone of polarizing activity, a tissue possibly involved in limb pattern formation. We found that the locally applied [3H]retinol is primarily converted to [3H]retinal, [3H]retinoic acid and a yet unidentified metabolite. When [3H]retinal is locally applied, it is either oxidized to [3H]retinoic acid or reduced to [3H]retinol. In contrast, local delivery of retinoic acid to the bud yields neither retinal nor retinol nor the unknown metabolite. This flow of metabolites agrees with the biochemical pathway of retinoids that has previously been elucidated in a number of other animal systems. To find out whether metabolism takes place directly in the treated limb bud, we have compared the amount of [3H]retinoid present in each of the four limb anlagen following local treatment of the right wing bud. The data suggest that retinoid metabolism takes place mostly in the treated limb bud. This local metabolism could provide a simple mechanism to generate in a controlled fashion the biologically active all-trans-retinoic acid from its abundant biosynthetic precursor retinol. In addition, local metabolism supports the hypothesis that retinoids are local chemical mediators involved in pattern formation.     

The biosynthesis of retinoic acid from retinol by rat tissues in vitro

This report shows that a spectrum of vitamin A-dependent tissues can produce retinoic acid by synthesis in situ, indicates that cellular retinol and retinoic acid binding proteins are not obligatory to retinoic acid synthesis, and provides initial characterization of retinoic acid synthesis by rat tissues. Retinoic acid synthesis from retinol was detected in homogenates of rat testes, liver, lung, kidney, and small intestinal mucosa, but not spleen. Zinc did not stimulate the conversion of retinol into retinoic acid by liver homogenates. Retinoic acid synthesis was localized in cytosol of liver and kidney, where its rate of synthesis from retinol was fourfold (liver) and sevenfold (kidney) slower than from retinal. The synthesis of retinoic acid from retinol required NAD and was not supported by NADP. NADH (0.5 mM) reduced retinoic acid synthesis from retinol, supported by NAD (2 mM), by 50-70%, but was fivefold less potent in reducing retinoic acid synthesis from retinal. Dithiothreitol enhanced the conversion of retinol, but not retinal, into retinoic acid. EDTA inhibited the conversion of retinol into retinoic acid slightly (13%, liver; 29%, kidney). A high ethanol concentration (100 mM), relative to retinoid substrate (10 microM), inhibited retinoic acid synthesis from retinol (liver, 54%; kidney, 30%) and from retinal (30%, liver; 9%, kidney). 4'-(9-Acridinylamino)methansulfon-m-anisidine, an inhibitor of aldehyde oxidase, and disulfiram, a sulfhydryl-group crosslinking agent, were potent inhibitors of retinoic acid synthesis at 10 microM or less, and seemed equipotent in liver and kidney. 4-Methylpyrazole, an inhibitor of ethanol metabolism, also inhibited retinoic acid synthesis from retinol, but was less potent than the former two inhibitors, and affected liver to a greater extent than kidney, particularly with retinal as substrate.     

Retinol metabolism in LLC-PK1 Cells. Characterization of retinoic acid synthesis by an established mammalian cell line

Specific assays, based on gas chromatography-mass spectrometry and high-performance liquid chromatography, were used to quantify the conversion of retinol and retinal into retinoic acid by the pig kidney cell line LLC-PK1. Retinoic acid synthesis was linear for 2-4 h as well as with graded amounts of either substrate to at least 50 microM. Retinoic acid concentrations increased through 6-8 h, but decreased thereafter because of substrate depletion (t1/2 of retinol = 13 h) and product metabolism (1/2 = 2.3 h). Retinoic acid metabolism was accelerated by treating cells with 100 nM retinoic acid for 10 h (t1/2 = 1.7 h) and was inhibited by the antimycotic imidazole ketoconazole. Feedback inhibition was not indicated since retinoic acid up to 100 nM did not inhibit its own synthesis. Retinol dehydrogenation was rate-limiting. The reduction and dehydrogenation of retinal were 4-8-fold and 30-60-fold faster, respectively. Greater than 95% of retinol was converted into metabolites other than retinoic acid, whereas the major metabolite of retinal was retinoic acid. The synthetic retinoid 13-cis-N-ethylretinamide inhibited retinoic acid synthesis, but 4-hydroxylphenylretinamide did not. 4'-(9-Acridinylamino)methanesulfon-m-anisidide, an inhibitor of aldehyde oxidase, and ethanol did not inhibit retinoic acid synthesis. 4-Methylpyrazole was a weak inhibitor: disulfiram was a potent inhibitor. These data indicate that retinol dehydrogenase is a sulfhydryl group-dependent enzyme, distinct from ethanol dehydrogenase. Homogenates of LLC-PK1 cells converted retinol into retinoic acid and retinyl palmitate and hydrolyzed retinyl palmitate. This report suggests that substrate availability, relative to enzyme activity/amount, is a primary determinant of the rate of retinoic acid synthesis, identifies inhibitors of retinoic acid synthesis, and places retinoic acid synthesis into perspective with several other known pathways of retinoid metabolism.     

Retinoid metabolism during development of liver cirrhosis

The changes in retinoid metabolism have been documented in liver cirrhosis. However, the dynamic alterations in levels of this vitamin between circulation and liver during development of the liver cirrhosis are not well understood. The aim of this study was to measure retinoids in the liver and circulation in parallel, during and after development of cirrhosis induced by carbon tetrachloride and thioacetamide. Retinoid levels were measured by HPLC. A decrease in retinaldehyde and total retinol, together with an increase in retinoic acid was evident in liver from both carbon tetrachloride or thioacetamide treated rats within a month after initiation of treatment. Activity of enzymes involved in retinoid metabolism such as retinaldehyde oxidase, retinaldehyde dehydrogenase, and retinaldehyde reductase were decreased in the liver. In parallel, levels of retinol and retinaldehyde in the serum were increased while retinoic acid was decreased. This study indicates that during development of cirrhosis, there is reciprocal transfer of retinoid metabolites between the circulation and the liver.     

Immunohistochemical localization of retinoid binding proteins at the materno-fetal interface of the porcine epitheliochorial placenta

Retinol and retinoic acid that are potent modulators of gene expression are vital for development and growth of the conceptus. Apart from being transported across the placenta, retinol and retinoic acid may also be active in the placenta per se. Three proteins involved in 1) serum transport of retinol (retinol binding protein [RBP]), 2) cellular transport and metabolism of retinol (cellular RBP [CRBP] I), and 3) retinoic acid (cellular retinoic acid binding protein [CRABP] I), respectively, have been located by immunohistochemistry during gestation in the porcine placenta. This is a diffuse epitheliochorial placenta composed of areolar-gland subunits, where transport of larger molecules takes place, and interareolar regions, where gas-exchange and trophoblast absorption of hemotroph occur. Immunoreactive-RBP (ir-RBP) as well as CRBP I (ir-CRBP) was detected in uterine glands and in areolar trophoblasts, suggesting that RBP-retinol is secreted by the glands and absorbed by the trophoblasts. Both proteins were present also at the interareolar regions, with ir-CRBP in both the uterine epithelium and the apposing trophoblasts, but ir-RBP only in the former. The localization of ir-CRABP was, in contrast, strictly limited to interareolar trophoblasts. Together these findings suggest that 1) the areolar gland subunits are important for transport of retinol and retinol-RBP, and 2) retinoid binding proteins are involved in the development and growth of the porcine placenta.     

Differences in the action and metabolism between retinol and retinoic acid in B lymphocytes

We have previously reported on the dependency of activated B lymphocytes for retinol. Here we confirm and extend these findings that cells deprived of retinol perish in cell culture within days, displaying neither signs of apoptosis nor of cell cycle arrest. Cell death can be prevented by physiological concentrations of retinol and retinal, but not by retinoic acid or three synthetic retinoic acid analogues. To exclude the possibility that retinoic acid is so rapidly degraded as to escape detection, we have tested its stability in intra- and extracellular compartments. Contrary to expectation, we find that retinoic acid persists for longer (t 1/2 3 d) in cultures than retinol (t 1/2 1 d). Furthermore, despite the use of sensitive trace-labeling techniques, we cannot detect retinoic acid or 3,4-didehydroretinoic acid among retinol metabolites. However, retinol is converted into several new retinoids, one of which has the ability to sustain B cell growth in the absence of an external source of retinol, supporting the notion of a second retinol pathway. We have also determined which of the known retinoid-binding proteins are expressed in B lymphoblastoid cells. According to results obtained with polymerase chain reaction-assisted mRNA detection, they transcribe the genes for cellular retinol- and cellular retinoic acid-binding proteins, for the nuclear retinoic acid receptors, RAR-alpha, -gamma, and RXR-alpha, but not RAR-beta. Our findings that B cells do not synthesize retinoic acid or respond to exogenous retinoic acid on the one hand, but on the other hand convert retinol to a novel bioactive form of retinol, suggest the existence of a second retinoid pathway, distinct from that of retinoic acids.     

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.     

Localization of retinoid binding proteins, retinoid receptors, and retinaldehyde dehydrogenase in the chick eye

Retinoids have many functions in the eye, including, perhaps, the visual guidance of ocular growth. Therefore, we identified where retinoid receptors, binding proteins, and biosynthetic enzymes are located in the ocular tissues of the chick as a step toward discovering where retinoids are generated and where they act. Using antibodies to interphotoreceptor retinoid binding protein (IRBP), cellular retinol binding protein (CRBP), cellular retinoic acid binding protein (CRABP), cellular retinaldehyde binding protein (CRALBP), retinaldehyde dehydrogenase (RALDH), and retinoic acid receptors (RAR and RXR), we localized these proteins to cells in the retina, retinal pigmented epithelium, choroid and sclera of the chick eye. IRBP was detected in the photoreceptor layer and pigmented epithelium; CRBP was in the pigmented epithelium; CRABP was in amacrine and bipolar cells in the retina; CRALBP was in Müller cells, pigmented epithelium, choroid, and fibrous sclera; RALDH was in retinal amacrine cells, pigmented epithelium, and choroid; RAR was in amacrine cells, choroid, and chondrocytes and fibroblasts in the sclera; and RXR was in amacrine and ganglion cells, bipolar cell nuclei, choroid, and chondrocytes. We also found that the growth-modulating toxins colchicine and quisqualate destroyed selectively different subsets of CRABP-containing amacrine cells. We conclude that the distribution of proteins involved in retinoid metabolism is consistent with a role of retinoids not only in phototransduction, but also in maintenance of cellular phenotype and visual guidance of ocular growth.     

Saturation analysis of cellular retinoid binding proteins: application to retinoic acid resistant human neuroblastoma cells and to human tumors

A method for saturation analysis of cellular retinoic acid and retinol binding proteins, CRABP and CRBP, respectively, in cultured cells and human tumor samples, and its application to a retinoic acid resistant subline of the human neuroblastoma LA-N-5 cell line is described. Assessment of retinoid binding was accomplished by incubation of cytosols with increasing concentrations of [3H]retinoid (28-43 Ci/mmol; 1 Ci = 37 GBq) for 24 h. Bound retinoid was separated from free retinoid by adsorption with dextran-coated charcoal. Nonspecific binding was quantitated in parallel incubations which had been treated with p-chloromercuribenzene sulfonate (PCMBS), resulting in selective elimination of sulfhydryl-dependent ligand binding to both CRABP and CRBP. Quantitation was accomplished by Scatchard analysis of specific (PCMBS sensitive) binding. Employing this technique, specific retinoid binding was attributed to the presence of 2S macromolecules which displayed the known properties of CRABP and CRBP, namely ligand specificity, saturability, high ligand affinity, and PCMBS sensitivity. The apparent dissociation constants (Kd) for retinoic acid binding in cytosols prepared from murine 3T6 fibroblasts, rat testes, and a human ovarian tumor were 7, 11, and 35 nM, respectively. These preparations also bound retinol with high affinity, exhibiting Kds of 12, 26, and 48 nM, respectively. A retinoic acid resistant subline of LA-N-5 cells designated LA-N-5-R9 was established by long-term culture in the presence of 10(-6) M retinoic acid. This subline is resistant to the effects of retinoic acid in that it requires a 10-fold higher concentration of retinoic acid for 50% inhibition of growth than the parent line and displays no retinoic acid induced morphologic differentiation. Saturation analysis of CRABP in the parent and resistant subline reveal no significant alteration in either CRABP content or affinity. These results indicate that resistance to retinoic acid induced differentiation in LA-N-5-R9 occurs distal to CRABP binding or that CRABP does not mediate this response to retinoic acid.     

Retinoids and retinoid-metabolic gene expression in mouse adipose tissues

Vitamin A and its analogs (retinoids) regulate adipocyte differentiation. Recent investigations have demonstrated a relationship among retinoids, retinoid-binding-protein 4 (RBP4) synthesized in adipose tissues, and insulin-resistance status. In this study, we measured retinoid levels and analyzed the expression of retinoid homeostatic genes associated with retinol uptake, esterification, oxidation, and catabolism in subcutaneous (Sc) and visceral (Vis) mouse fat tissues. Both Sc and Vis depots were found to contain similar levels of all-trans retinol. A metabolite of retinol with characteristic ultraviolet absorption maxima for 9-cis retinol was observed in these 2 adipose depots, and its level was 2-fold higher in Sc than in Vis tissues. Vis adipose tissue expressed significantly higher levels of RBP4, CRBP1 (intracellular retinol-binding protein 1), RDH10 (retinol dehydrogenase), as well as CYP26A1 and B1 (retinoic acid (RA) hydroxylases). No differences in STRA6 (RBP4 receptor), LRAT (retinol esterification), CRABP1 and 2 (intracellular RA-binding proteins), and RALDH1 (retinal dehydrogenase) mRNA expressions were discerned in both fat depots. RALDH1 was identified as the only RALDH expressed in both Sc and Vis adipose tissues. These results indicate that Vis is more actively involved in retinoid metabolism than Sc adipose tissue.     

Functional studies of newly synthesized benzoic acid derivatives: identification of highly potent retinoid-like activity

Three newly synthesized benzoic acid derivatives (terephthalic acid anilides, chalcone carboxylic acid, and azobenzene carboxylic acid), with a certain structural similarity to retinoic acid, were examined for their retinoid-like bioactivity and their capacity to bind to cellular retinoid binding proteins. Two in vitro systems were used to evaluate their retinoid-like bioactivity: inhibition of adipose conversion of ST 13 murine preadipose cells and growth promotion of murine sarcoma virus (MSV)-transformed 3T3 cells in serum-free culture. All three compounds tested inhibited ST 13 adipose conversion at nanomolar concentrations in a manner similar to classical retinoids such as retinoic acid. The growth-stimulating activity of these compounds on MSV-transformed 3T3 cells was one to two orders of magnitude greater than that of retinoic acid. Simultaneous treatment with these compounds and retinoic acid produced only a barely detectable additive effect, suggesting a common mechanism of action, whereas unrelated mitogens, thrombin, and insulin worked synergistically in combination with retinoic acid. None of the compounds competed with retinol for binding to cellular retinol binding protein. However, two of the three competed with retinoic acid for binding to cellular retinoic acid binding protein. This study provides evidence that the newly synthesized compounds should be included among the retinoids and that their strong biological activity will undoubtedly contribute to the biological and medical application of retinoids.     

细胞内视黄酸信号传递系统

视黄酸对基因表达的调控与肿瘤细胞的分化、胚胎的发育以及疾病的发生关系密切．视黄酸的基因调控作用是通过视黄酸信号传递系统实现的．视黄酸信号传递系统包括视黄酸、细胞液视黄醇（酸）结合蛋白、视黄酸细胞核受体及视黄酸反应元件等．视黄酸信号传递系统自成一体系,在这一系列调控的级联反应中存在着多级反馈调控环节,而且该系统还与视黄酸配体以外的信号系统相联系．     

Enzymes and binding proteins affecting retinoic acid concentrations

Free retinoids suffer promiscuous metabolism in vitro. Diverse enzymes are expressed in several subcellular fractions that are capable of converting free retinol (retinol not sequestered with specific binding proteins) into retinal or retinoic acid. If this were to occur in vivo, regulating the temporal-spatial concentrations of functionally-active retinoids, such as RA (retinoic acid), would be enigmatic. In vivo, however, retinoids occur bound to high-affinity, high-specificity binding proteins, including cellular retinol-binding protein, type I (CRBP) and cellular retinoic acid-binding protein, type I (CRABP). These binding proteins, members of the superfamily of lipid binding proteins, are expressed in concentrations that exceed those of their ligands. Considerable data favor a model pathway of RA biosynthesis and metabolism consisting of enzymes that recognize CRBP (apo and holo) and holo-CRABP as substrates and/or affecters of activity. This would restrict retinoid access to enzymes that recognize the appropriate binding protein, imparting specificity to RA homeostasis; preventing, e.g. opportunistic RA synthesis by alcohol dehydrogenases with broad substrate tolerances. An NADP-dependent microsomal retinol dehydrogenase (RDH) catalyzes the first reaction in this pathway. RDH recognizes CRBP as substrate by the dual criteria of enzyme kinetics and chemical crosslinking. A cDNA of RDH has been cloned, expressed and characterized as a short-chain alchol dehydrogenase. Retinal generated in microsomes from holo-CRBP by RDH supports cytosolic RA synthesis by an NAD-dependent retinal dehydrogenase (RalDH). RalDH has been purified, characterized with respect to substrate specificity, and its cDNA has been cloned. CRABP is also important to modulating the steady-state concentrations of RA, through sequestering RA and facilitating its metabolism, because the complex CRABP/RA acts as a low K_m substrate.     

Rapid characterization of cellular retinoid-binding proteins by high-performance size-exclusion chromatography

A high-performance size-exclusion chromatographic method was developed for the analysis of cellular retinol and retinoic acid-binding proteins. The chromatographic analysis of the retinol-retinol-binding protein complex or the retinoic acid-retinoic acid-binding protein complex requires 15 min. The use of high-specific-radioactivity retinoid ligand (30-40 Ci/mmol) allows routine detection of 25 fmol of retinoid-binding protein/mg of cytosolic protein. Thus, this method provides a rapid alternative to sucrose density gradient sedimentation analysis of the cellular retinoid-binding proteins. High-performance size-exclusion chromatography is well suited to screening novel tissues, tumors, and cell lines for the presence of retinoid-binding proteins and to the further characterization of these cellular proteins. This method was applied to the characterization of cellular retinol- and retinoic acid-binding proteins in fetal rabbit tissues. Both retinol- and retinoic acid-binding proteins were detected in fetal rabbit brain, intestine, kidney, and lung at a gestational age of 28 days. Neither retinoid-binding protein was detected in 28-day-old fetal rabbit placenta. Specific retinoic acid binding in fetal intestinal cytosol decreased as a function of increasing gestational age.     

Roles of vitamin A status and retinoids in glucose and fatty acid metabolism

The rising prevalence of metabolic diseases, such as obesity and diabetes, has become a public health concern. Vitamin A (VA, retinol) is an essential micronutrient for a variety of physiological processes, such as tissue differentiation, immunity, and vision. However, its role in glucose and lipid metabolism has not been clearly defined. VA activities are mediated by the metabolite of retinol catabolism, retinoic acid, which activates the retinoic acid receptor and retinoid X receptor (RXR). Since RXR is an obligate heterodimeric partner for many nuclear receptors involved in metabolism, it is reasonable to assume that VA status and retinoids contribute to glucose and lipid homeostasis. To date, the impacts of VA and retinoids on energy metabolism in animals and humans have been demonstrated in some basic and clinical investigations. This review summarizes the effects of VA status and retinoid treatments on metabolism of the liver, adipocytes, pancreatic β-cells, and skeletal muscle. It proposes a mechanism by which the dietary and hormonal signals converge on the promoter of sterol regulatory element-binding protein 1c gene to induce its expression, and in turn, the expression of lipogenic genes in hepatocytes. Future research projects relevant to the VA's roles in metabolic diseases are also discussed.     

2,3,7,8-tetrachlorodibenzo-p-dioxin induces lecithin: retinol acyltransferase transcription in the rat kidney

Vitamin A (retinoids) has an essential role in development and throughout life of humans and animals. Consequently, effects of the environmental pollutant 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) on retinoid metabolism may be contributory to its toxicity. This study was performed to clarify the mechanism behind dioxin-induced retinyl ester formation in the rat kidney. In addition we investigated the possible role of CYP1A1 in dioxin-induced all-trans-retinoic acid (atRA) formation. Male Sprague-Dawley rats were exposed to a single oral dose of TCDD in a combined dose-response and time-course study, with doses ranging from 0.1 to 100 microg/kg bw and time points from 1 to 28 days. Levels of atRA and the expression of two potentially retinoic acid (RA)-controlled proteins critically involved in retinoid storage regulation, lecithin: retinol acyltransferase (LRAT) and cellular retinol binding protein I (CRBP I), were analyzed in liver and kidney. The expression and activity of cytochrome P4501A1 (assayed as ethoxyresorufin-O-deethylase activity) was assessed to gain insight into its potential role in RA synthesis. There was a significant increase in LRAT mRNA expression in the kidney, whereas no such increase could be observed in the liver, despite significantly increased atRA levels in both tissues. This suggests a tissue-specific regulation of LRAT by TCDD that may be dependent on other factors than atRA. Neither CRBP I mRNA nor protein levels were altered by TCDD. The time-course relationship between CYP1A1 activity and atRA levels in liver and kidney does not exclude a role of CYP1A1 in TCDD-induced RA synthesis. The observed altered regulation of the retinoid-metabolizing enzyme LRAT, together with the low doses and short time required by TCDD to change tissue RA levels, suggest that enzymes involved in retinoid metabolism are specific and/or direct targets of TCDD.