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.     

Characterization of a new endogenous vitamin A metabolite

Here, we describe the discovery of a new major endogenous vitamin A metabolite with particularly high hepatic concentrations. This metabolite was isolated from mouse livers and was characterized as 9-cis-4-oxo-13,14-dihydro-retinoic acid (RA) based on mass spectral, ultraviolet, and nuclear magnetic resonance analyses. It was also detected in one human liver. To gain further insight into endogenous retinoid metabolism, mice were fed over a period of 14 days ad libitum with diets enriched with different amounts of retinyl palmitate [15,000, 45,000 or 150,000 international units (IU)/kg diet]. Higher retinyl palmitate amounts in the diet resulted surprisingly in a dose-dependent decrease in all-trans-RA levels in serum, kidney, and brain, whereas levels of 9-cis-4-oxo-13,14-dihydro-RA, retinol, and retinyl esters were dose-dependently elevated in serum, kidney, and liver. 13-cis-RA levels could be detected in serum, liver, and kidney, but were unaffected by the dietary vitamin A status. 9-cis-RA levels were below the detection limit of 0.2 ng/ml serum or 0.4 ng/g tissue. This study indicates that the oxidation at C4 of the cyclohexenyl ring, isomerization of the C9/C10 double bond, and reduction of the C13/C14 double bond are major endogenous metabolic pathways of vitamin A.     

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.     

Effects of a high-fat diet and global aryl hydrocarbon receptor deficiency on energy balance and liver retinoid status in male Sprague-Dawley rats

The physiological functions of the aryl hydrocarbon receptor (AHR) are only beginning to unfold. Studies in wildtype and AHR knockout (AHRKO) mice have recently disclosed that AHR activity is required for obesity and steatohepatitis to develop when mice are fed with a high-fat diet (HFD). In addition, a line of AHRKO mouse has been reported to accumulate retinoids in the liver. Whether these are universal manifestations across species related to AHR activity level is not known yet. Therefore, we here subjected wildtype and AHRKO male rats (on Sprague-Dawley background) to HFD feeding coupled with free access to 10% sucrose solution and water; controls received a standard diet and water. Although the HFD-fed rats consumed more energy throughout the 24-week feeding regimen, they did not get overweight. However, relative weights of the brown and epididymal adipose tissues were elevated in HFD-fed rats, while that of the liver was lower in AHRKO than wildtype rats. Moreover, the four groups exhibited diet- or genotype-dependent differences in biochemical variables, some of which suggested marked dissimilarities from AHRKO mice. Expression of pro- and anti-inflammatory genes was induced in livers of HFD-fed AHRKO rats, but histologically they did not differ from others. HFD reduced the hepatic concentrations of retinyl palmitate, 9-cis-4-oxo-13,14-dihydroretinoic acid and (suggestively) retinol, whereas AHR status had no effect. Hence, the background strain/line of AHRKO rat is resistant to diet-induced obesity, and AHR does not modulate this or liver retinoid concentrations. Yet, subtle AHR-dependent differences in energy balance-related factors exist despite similar weight development.     

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.     

Regulation of alpha 2(I) collagen expression in stellate cells by retinoic acid and retinoid X receptors through interactions with their cofactors

Retinoic acid (RA) suppresses alpha 2(I) collagen expression in hepatic stellate cells through the binding of retinoic acid receptor beta (RAR beta) and retinoid X receptor alpha (RXR alpha) to RA response elements (RAREs) in the alpha 2(I) collagen promoter. This study determined the influence of coactivators and corepressors to RAR beta and RXR alpha on the regulation of the alpha 2(I) collagen promoter. The coactivators, steroid receptor coactivator-1 (SRC-1) and growth hormone receptor interacting protein-1 (GRIP-1), enhanced, while the nuclear receptor corepressor (N-CoR) abolished the inhibitory effect of RAR beta and RXR alpha on the promoter activity. In the presence of RA, the coactivators SRC-1 and GRIP-1 formed complexes with RAR beta and RXR alpha which are bound to an oligonucleotide specifying a RARE site in the promoter. In conclusion, this study shows that in the presence of retinoic acid, the coactivators SRC-1 and GRIP-1 augment, while the corepressor N-CoR abolishes, the suppressive effects of RAR beta and RXR alpha on alpha 2(I) collagen promoter activity.     

Influence of retinoid nutritional status on cellular retinol- and cellular retinoic acid-binding protein concentrations in various rat tissues

Studies were conducted to explore the effects of differences in retinoid nutritional status and of sex on the tissue distribution and levels of cellular retinol-binding protein (CRBP) and of cellular retinoic acid-binding protein (CRABP) in the rat. Sensitive and specific radioimmunoassays were developed and employed to measure the levels of both CRBP and CRABP. Four groups of six male rats each were fed experimental diets that differed greatly in the amount and kind of retinoids provided, but were otherwise identical. These groups were comprised of rats that were normal controls, retinoid-deficient, retinoic acid-fed, and excess retinol-fed. A fifth group of six female rats was fed the control diet. Immunogens identical with rat testis CRBP and CRABP, as assessed by radioimmunoassay displacement curves, were found in every rat tissue examined (21 tissues in males, 18 in females). The highest levels of CRBP were found in the proximal portion of the epididymis, the liver, and kidney. The highest levels of CRABP were found in the seminal vesicles, vas deferens, and skin. A significant (p less than 0.01) inverse relationship was found between CRBP and CRABP levels in the different tissues of the male reproductive tract. In both males and females, CRBP levels were highest in the gonads and proximal portion of the reproductive tract and decreased distally, whereas the opposite was true for CRABP. Retinoid-deficient rats showed reduced tissue levels of CRBP; thus, tissue CRBP levels are influenced by diet and retinoid availability. No differences in tissue CRBP levels were found in the rats fed the control, the retinoic acid, or the excess retinol diets. Female control rats had higher CRBP levels than male controls in 4 of 15 tissues compared (liver, lung, thymus, and fat). In contrast, tissue CRABP levels showed no diet- or sex-dependent differences. Only in one tissue, the skin, were differences observed (lower CRABP in retinoid-deficient and in female rats). Thus, CRABP metabolism and levels appear to be minimally influenced by the amount or kind of retinoid ligand available or by sex.     

Effects of dietary retinoic acid on cellular retinol- and retinoic acid-binding protein levels in various rat tissues

A study was conducted to explore the effects of retinoic acid, fed to retinol-deficient rats, on the tissue distribution and levels of cellular retinol-binding protein (CRBP) and cellular retinoic acid-binding protein (CRABP). Sensitive and specific radioimmunoassays were employed to measure the levels of both CRBP and CRABP. Two groups of six male rats each were fed a purified retinoid-deficient diet supplemented with either: i) retinyl acetate (control group); or ii) retinoic acid (30 mg/kg diet) (retinol deficient-retinoic acid group). The retinoic acid supplementation was begun after 38 days on the retinoid-deficient diet alone, and was continued for 52-54 days. Analysis of the data indicated that only the CRBP level of the proximal epididymis in the retinol-deficient/retinoic acid group differed significantly from (was lower than) the corresponding control level, at the 1% confidence level. CRABP tissue levels did not differ significantly between the two groups. Thus, a moderately large intake of retinoic acid, as the only source of retinoids, had very little effect on the tissue distribution or levels of either its own cellular binding protein (CRABP) or of CRBP. This study provides further information showing that the tissue levels of the cellular retinoid-binding proteins are highly regulated and maintained in rats, even in the presence of marked changes in retinoid nutritional status.     

Cellular retinol-binding protein type III is needed for retinoid incorporation into milk

The physiologic role(s) of cellular retinol-binding protein (CRBP)-III, an intracellular retinol-binding protein that is expressed solely in heart, muscle, adipose, and mammary tissue, remains to be elucidated. To address this, we have generated and characterized CRBP-III-deficient (CRBP-III(-/-)) mice. Mice that lack CRBP-III were viable and healthy but displayed a marked impairment in retinoid incorporation into milk. Milk obtained from CRBP-III(-/-) dams contains significantly less retinyl ester, especially retinyl palmitate, than milk obtained from wild type dams. We demonstrated that retinol bound to CRBP-III is an excellent substrate for lecithin-retinol acyltransferase, the enzyme responsible for catalyzing retinyl ester formation from retinol. Our data indicated that the diminished milk retinyl ester levels arise from impaired utilization of retinol by lecithin-retinol acyltransferase in CRBP-III(-/-) mice. Interestingly, CRBP-I and CRBP-III each appeared to compensate for the absence of the other, specifically in mammary tissue, adipose tissue, muscle, and heart. For CRBP-III(-/-) mice, CRBP-I protein levels were markedly elevated in adipose tissue and mammary gland. In addition, in CRBP-I(-/-) mice, CRBP-III protein levels were elevated in tissues that normally express CRBP-III but were not elevated in other tissues that do not normally express CRBP-III. Our data suggested that CRBP-I and CRBP-III share some physiologic actions within tissues and that each can compensate for the absence of the other to help maintain normal retinoid homeostasis. However, under conditions of high demand for retinoid, such as those experienced during lactation, this compensation was incomplete.     

An immortalized rat liver stellate cell line (HSC-T6): a new cell model for the study of retinoid metabolism in vitro

Hepatocytes and hepatic stellate cells play important roles in retinoid storage and metabolism. Hepatocytes process postprandial retinyl esters and are responsible for secretion of retinol bound to retinol-binding protein (RBP) to maintain plasma retinol levels. Stellate cells are the body's major cellular storage sites for retinoid. We have characterized and utilized an immortalized rat stellate cell line, HSC-T6 cells, to facilitate study of the cellular aspects of hepatic retinoid processing. For comparison, we also carried out parallel studies in Hepa-1 hepatocytes. Like activated primary stellate cells, HSC-T6 express myogenic and neural crest cytoskeletal filaments. HSC-T6 cells take up and esterify retinol in a time- and concentration-dependent manner. Supplementation of HSC-T6 culture medium with free fatty acids (up to 300 micrometer) does not affect retinol uptake but does enhance retinol esterification up to 10-fold. RT-PCR analysis indicates that HSC-T6 cells express all 6 retinoid nuclear receptors (RARalpha, -beta, -gamma, and RXRalpha, -beta, -gamma) and like primary stellate cells, HSC-T6 stellate cells express cellular retinol-binding protein, type I (CRBP) but fail to express either retinol-binding protein (RBP) or transthyretin (TTR). Addition of retinol (10(-8)-10(-5) m) or all-trans-retinoic acid (10(-10)-10(-6) m) rapidly up-regulates CRBP expression. Using RAR-specific agonists and antagonists and an RXR-specific agonist, we show that members of the RAR-receptor family modulate HSC-T6 CRBP expression.Thus, HSC-T6 cells display the same retinoid-related phenotype as primary stellate cells in culture and will be a useful tool for study of hepatic retinoid storage and metabolism.     

Retinoids, retinoid-binding proteins, and retinyl palmitate hydrolase distributions in different types of rat liver cells

A study was conducted to determine the levels and distributions of retinoids, retinol-binding protein (RBP), retinyl palmitate hydrolase (RPH), cellular retinol-binding protein (CRBP), and cellular retinoic acid-binding protein (CRABP) in different types of isolated liver cells. Highly purified fractions of parenchymal, fat-storing (stellate), endothelial, and Kupffer cells were isolated in high yield from rat livers. The retinoid content of each fraction was measured by HPLC analysis. RBP, CRBP, and CRABP were measured by sensitive and specific radioimmunoassays, and RPH activity was measured by a sensitive microassay. The concentrations of each parameter expressed per 10(6) parenchymal or fat-storing cells were, respectively: retinoids, 1.5 and 83.9 micrograms of retinol equivalents; RBP, 138 and 7.4 ng; RPH, 826 and 1152 pmol FFA formed hr-1; CRBP, 470 and 236 ng; and CRABP, 5.6 and 8.7 ng. When these data were expressed on the basis of per unit mass of cellular protein, the concentrations of RPH, CRBP, and CRABP in the fat-storing cells, which contain 10-fold less protein than the large parenchymal cells, were seen to be greatly enriched over parenchymal cells. The parenchymal cells contained approximately 9% of the total retinoids, 98% of the total RBP, 90% of the total RPH activity, 91% of the total CRBP, and 71% of the total CRABP found in the liver. The fat-storing cells accounted for approximately 88% of the total retinoids, 0.7% of the total RBP, 10% of the RPH activity, 8% of the total CRBP, and 21% of the CRABP in the liver. The endothelial and Kupffer cell fractions contained very low levels of all of these parameters. Thus, the large and abundant parenchymal cells account for greater than 70% of the liver's RBP, RPH, CRBP, and CRABP; but the much smaller and less abundant fat-storing cells contain the majority of hepatic retinoids and greatly enriched concentrations of RPH, CRBP, and CRABP.     

Combined RAR alpha- and RXR-specific ligands overcome N-myc-associated retinoid resistance in neuroblastoma cells

Retinoids induce human neuroblastoma cells to undergo growth inhibition and neuritic differentiation in vitro, through interactions with nuclear retinoid receptor proteins. In this study, we found that three different neuroblastoma cell lines exhibited wide variation in their responsiveness to the growth inhibitory effects of the retinoic acid receptor (RAR) agonist, all-trans-retinoic acid (aRA). Resistance to the growth inhibitory effect of aRA correlated with the presence of N-myc gene amplification and not aRA-induced RAR beta levels. Over-expression of N-myc in a neuroblastoma cell line with no endogenous N-myc expression caused a marked reduction in retinoid-induced growth inhibition. Combination of receptor-specific retinoid agonists for RXR and RAR alpha significantly enhanced the sensitivity of N-myc-amplified neuroblastoma cells to the growth inhibitory effects of aRA. Our results indicate that combination receptor-specific retinoid therapy can overcome N-myc-mediated retinoid resistance and may be a more effective chemo-preventive strategy in the disease.     

Metabolism and transactivation activity of 13,14-dihydroretinoic acid

The metabolism of vitamin A is a highly regulated process that generates essential mediators involved in the development, cellular differentiation, immunity, and vision of vertebrates. Retinol saturase converts all-trans-retinol to all-trans-13,14-dihydroretinol (Moise, A. R., Kuksa, V., Imanishi, Y., and Palczewski, K. (2004) J. Biol. Chem. 279, 50230-50242). Here we demonstrate that the enzymes involved in oxidation of retinol to retinoic acid and then to oxidized retinoic acid metabolites are also involved in the synthesis and oxidation of all-trans-13,14-dihydroretinoic acid. All-trans-13,14-dihydroretinoic acid can activate retinoic acid receptor/retinoid X receptor heterodimers but not retinoid X receptor homodimers in reporter cell assays. All-trans-13,14-dihydroretinoic acid was detected in vivo in Lrat-/- mice supplemented with retinyl palmitate. Thus, all-trans-13,14-dihydroretinoic acid is a naturally occurring retinoid and a potential ligand for nuclear receptors. This new metabolite can also be an intermediate in a retinol degradation pathway or it can serve as a precursor for the synthesis of bioactive 13,14-dihydroretinoid metabolites.     

Importance of vitamin-A for lung function and development

Vitamin-A is essential for growth and development of cells and tissues. In its active form, retinoic acid, it controls the regular differentiation as a ligand for retinoic acid receptors (RAR, RXR) and is involved in the integration (gap junction formation) of cell formations [Nature 37 (1994) 528; International Review of Cytology. San Diego Academic Press, 1–31]. Vitamin-A plays a substantial role, especially in the respiratory epithelium and the lung. During moderate vitamin-A-deficiency, the incidence for diseases of the respiratory tract is considerably increased and repeated respiratory infections can be influenced therapeutically by a moderate vitamin-A-supplementation [Aust. Paediatr. J. 22 (1986) 95; Lancet 338 (1991) 67]. In addition to the importance of the vitamin for the lung function, vitamin-A is also responsible for the development of many tissues and cells as well as for the embryonic lung development. Recent studies proved that the control occurs by different expressions of retinoid receptors as well as by time-dependent changes of the vitamin-A-metabolism respectively via cellular vitamin-A-binding proteins (CRBP: cytoplasmatic retinol binding protein; CRABP: cytoplasmatic retinoic acid binding protein).