Zebrafish cerebrospinal fluid mediates cell survival through a retinoid signaling pathway

Cerebrospinal fluid (CSF) includes conserved factors whose function is largely unexplored. To assess the role of CSF during embryonic development, CSF was repeatedly drained from embryonic zebrafish brain ventricles soon after their inflation. Removal of CSF increased cell death in the diencephalon, indicating a survival function. Factors within the CSF are required for neuroepithelial cell survival as injected mouse CSF but not artificial CSF could prevent cell death after CSF depletion. Mass spectrometry analysis of the CSF identified retinol binding protein 4 (Rbp4), which transports retinol, the precursor to retinoic acid (RA). Consistent with a role for Rbp4 in cell survival, inhibition of Rbp4 or RA synthesis increased neuroepithelial cell death. Conversely, ventricle injection of exogenous human RBP4 plus retinol, or RA alone prevented cell death after CSF depletion. Zebrafish rbp4 is highly expressed in the yolk syncytial layer, suggesting Rbp4 protein and retinol/RA precursors can be transported into the CSF from the yolk. In accord with this suggestion, injection of human RBP4 protein into the yolk prevents neuroepithelial cell death in rbp4 loss‐of‐function embryos. Together, these data support the model that Rbp4 and RA precursors are present within the CSF and used for synthesis of RA, which promotes embryonic neuroepithelial survival. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 75–92, 2016     

Liver Retinol Transporter and Receptor for Serum Retinol-binding Protein (RBP4)

Vitamin A (retinol) is absorbed in the small intestine, stored in liver, and secreted into circulation bound to serum retinol-binding protein (RBP4). Circulating retinol may be taken up by extrahepatic tissues or recycled back to liver multiple times before it is finally metabolized or degraded. Liver exhibits high affinity binding sites for RBP4, but specific receptors have not been identified. The only known high affinity receptor for RBP4, Stra6, is not expressed in the liver. Here we report discovery of RBP4 receptor-2 (RBPR2), a novel retinol transporter expressed primarily in liver and intestine and induced in adipose tissue of obese mice. RBPR2 is structurally related to Stra6 and highly conserved in vertebrates, including humans. Expression of RBPR2 in cultured cells confers high affinity RBP4 binding and retinol transport, and RBPR2 knockdown reduces RBP4 binding/retinol transport. RBPR2 expression is suppressed by retinol and retinoic acid and correlates inversely with liver retinol stores in vivo. We conclude that RBPR2 is a novel retinol transporter that potentially regulates retinol homeostasis in liver and other tissues. In addition, expression of RBPR2 in liver and fat suggests a possible role in mediating established metabolic actions of RBP4 in those tissues.     

Interactions of retinol with binding proteins: implications for the mechanism of uptake by cells

The kinetic parameters of the interaction of retinol with retinol binding protein (RBP) were studied. The rate constant for association of retinol with the protein (ka) was found to be 1.5 X 10(6) M-1 min-1. The rate constant for dissociation (kd) from the protein was determined by studying the transfer of retinol from RBP to lipid bilayers. It was found that such transfer proceeds via the aqueous phase and its rate-limiting step is the dissociation of retinol from the binding protein. The rate of transfer therefore represents the rate of dissociation. The kd was 0.112 min-1. These values were validated further by the following consideration. The equilibrium dissociation constant of RBP and retinol can be calculated from the expression Kd = kd/ka. The calculated value was 7.5 X 10(-8) M. Kd was also measured directly by fluorometric titration and was found to be 7 X 10(-8) M. The relative avidities of retinol for RBP, the complex RBP-transthyretin (RBP-TTR), and serum albumin were also studied. It was found that binding of RBP to TTR increased its avidity for retinol by about 2-fold. The avidity of albumin for retinol was 30-fold lower than that of RBP. The data imply that retinol spontaneously and rapidly dissociates from sites on binding proteins, which indicates that the vitamin can freely move in vivo between physiologic compartments with avidities for it.     

Vaginal hydrolysis of retinyl acetate: increase in plasma retinol and retinol binding protein in women with cervical dysplasias

We previously reported the clinical feasibility of a Phase I trial involving the topical administration of a RA gel applied cervicovaginally in women with mild or moderate cervical dysplasia. Now, we report hydrolysis and systemic absorption of the RA gel from the vagina. HPLC analysis of samples of residual gel obtained from the cervical canal after topical bolus application indicate that the RA undergoes prompt in vivo hydrolysis yielding retinol as a major metabolite. Venous blood samples of 41 subjects, who self-administered a RA gel, were analyzed for plasma retinol and RBP concentrations prior to and upon completion of a 7-day treatment course and upon return for follow-up examinations. An increase in both the concentrations of plasma retinol and RBP were detected after topical application of the RA gel. These elevated values receded after the gel administration was discontinued. No significant changes were observed in plasma retinol or RBP concentrations in placebo-treated subjects. The efficacy of RA as a chemopreventive agent in treating cervical dysplasias remains to be determined.     

Extraction and recombination studies of the interaction of retinol with human plasma retinol-binding protein

Methods have been developed for the removal of retinol from human plasma retinol-binding protein (RBP), so as to form the retinol-free apoprotein, and for the recombination of apo-RBP with retinol to again form the holoprotein. Retinol is removed from RBP by gently shaking a solution of RBP with heptane under controlled conditions. During the shaking, retinol is gradually extracted from the RBP and into the heptane phase. The reassociation of apo-RBP with retinol is achieved by exposing a solution of apo-RBP to Celite coated with a thin film of retinol, followed by isolation of the RBP by gel filtration on Sephadex G-100. This procedure results in the recombination of apo-RBP with an amount of retinol almost identical with that previously removed by extraction. The two-phase extraction procedure was used to explore some of the factors which affect the interaction of retinol with RBP. The retinol-RBP complex was most stable in the lower portion of the pH range 5.6 to 10. The rate of removal of retinol from the RBP-prealbumin complex (the form in which RBP normally circulates in plasma) was markedly less than the rate of its removal from RBP alone. The interaction of retinol with RBP appears to be stabilized by the formation of the RBP-prealbumin complex. The recombination procedure was employed to examine the specificity of the binding of retinol to RBP, by determining whether compounds other than all-trans-retinol would effectively bind to apo-RBP. Apo-RBP did not bind cholesterol, but displayed a slight affinity for phytol. The affinity of RBP for beta-carotene was minimal, whereas both retinyl acetate and retinal were bound about one-third as effectively as all-trans-retinol. In contrast, retinoic acid bound to apo-RBP almost as effectively as did retinol. Each of two isomers of retinol, 13-cis and 11,13-di-cis-retinol, bound to apo-RBP to some extent. The 13-cis isomer appeared to bind somewhat less effectively than did the 11,13-di-cis isomer. The binding of retinol to RBP is highly but not absolutely specific.     

Application of an allosteric model to describe the interactions among retinol binding protein 4, transthyretin, and small molecule retinol binding protein 4 ligands

Retinol binding protein 4 (RBP4) is a serum protein that serves as the major transport protein for retinol (vitamin A). Recent reports suggest that elevated levels of RBP4 are associated with insulin resistance and that insulin sensitivity may be improved by reducing serum RBP4 levels. This can be accomplished by administration of small molecules, such as fenretinide, that compete with retinol for binding to RBP4 and disrupt the protein-protein interaction between RBP4 and transthyretin (TTR), another serum protein that protects RBP4 from renal clearance. We developed a fluorescence resonance energy transfer (FRET) assay that measures the interaction between RBP4 and TTR and can be used to determine the binding affinities of RBP4 ligands. We present an allosteric model that describes the pharmacology of interaction among RBP4, TTR, retinol, and fenretinide, and we show data that support the model. We show that retinol increases the affinity of RBP4 for TTR by a factor of 4 and determine the affinity constants of fenretinide and retinyl acetate. The assay may be useful for characterizing small molecule ligands that bind to RBP4 and disrupt its interaction with TTR. In addition, such a model could be used to describe other protein-protein interactions that are modulated by small molecules.     

Real-time Analyses of Retinol Transport by the Membrane Receptor of Plasma Retinol Binding Protein

Vitamin A is essential for vision and the growth/differentiation of almost all human organs. Plasma retinol binding protein (RBP) is the principle and specific carrier of vitamin A in the blood. Here we describe an optimized technique to produce and purify holo-RBP and two real-time monitoring techniques to study the transport of vitamin A by the high-affinity RBP receptor STRA6. The first technique makes it possible to produce a large quantity of high quality holo-RBP (100%-loaded with retinol) for vitamin A transport assays. High quality RBP is essential for functional assays because misfolded RBP releases vitamin A readily and bacterial contamination in RBP preparation can cause artifacts. Real-time monitoring techniques like electrophysiology have made critical contributions to the studies of membrane transport. The RBP receptor-mediated retinol transport has not been analyzed in real time until recently. The second technique described here is the real-time analysis of STRA6-catalyzed retinol release or loading. The third technique is real-time analysis of STRA6-catalyzed retinol transport from holo-RBP to cellular retinol binding protein I (CRBP-I). These techniques provide high sensitivity and resolution in revealing RBP receptor''s vitamin A uptake mechanism.     

The mechanism of uptake of retinol by plasma-membrane vesicles.

The mechanism of retinol uptake by human placental brush-border membrane vesicles was investigated using initial-velocity studies of [3H]retinol uptake from the [3H]retinol-RBP (retinol-binding protein) complex. The process was rapid and time- and temperature-dependent. The uptake was specifically reversed by the addition of native or apo-RBP, but not by serum albumin. By contrast, uptake of free [3H]retinol was temperature-independent, partially reversible and showed no requirement for a specific protein for reversibility. Treatment of membrane vesicles with p-chloromercuribenzenesulphonate (PCMBS), which inhibited 125I-RBP binding, also inhibited the uptake of retinol from RBP, but the uptake of free retinol was unaffected. Addition of PCMBS after the attainment of steady-state uptake equilibrium abolished the binding of RBP, but did not affect the retinol already taken up from RBP. The results suggest that binding of RBP to its specific receptor is obligatory for the subsequent delivery of retinol to the membrane. Since the studies were carried out on isolated membrane vesicles, endocytosis of RBP is most unlikely to be involved in the placental transport of retinol. A double-reciprocal plot of initial velocity versus [3H]retinol-RBP concentration gave an apparent Km of 116 +/- 13 nM. Transthyretin decreased the rate of uptake of [3H]retinol from RBP without substantially altering the steady-state uptake levels, suggesting that membranes take up retinol from uncomplexed RBP. High-pressure gel-filtration chromatography showed that [3H]retinol is largely transferred to a membrane component with an apparent molecular mass of 125 kDa.     

Interactions of retinol with binding proteins: studies with retinol-binding protein and with transthyretin.

The interactions within the molecular complex in which retinol circulates in blood were studied. To monitor binding between retinol-binding protein (RBP) and transthyretin (TTR), TTR was labeled with a long-lived fluorescence probe (pyrene). Changes in the rotational volume of TTR following its association with RBP were monitored by fluorescence anisotropy of the probe. Titration of TTR with holo-RBP revealed the presence of 1.5 binding sites characterized by a dissociation constant Kd = 0.07 microM. At 0.15 M NaCl, binding of RBP to TTR showed an absolute requirement for the native ligand, retinol. At higher ionic strength (0.5 M NaCl), RBP complexed with retinal also bound to TTR with high affinity (Kd = 0.134 microM). RBP containing retinoic acid did not bind to TTR even at the high salt concentration. The data suggest that the TTR binding site on RBP is in close proximity to the retinoid binding site and that the head group of retinoic acid, when bound to RBP, presents steric hindrance for the interactions with TTR. The implications of the data for selectivity in retinoid transport in the circulation are discussed. The kinetics of the steps leading to complete dissociation of the retinol-RBP-TTR complex was also studied. The first step of this process was dissociation of retinol, which had a rate constant of 0.06/min. Following loss of retinol, the two proteins dissociate. The rate of dissociation is slow (k = 0.055/h), however, indicating that the complex apo-RBP-TTR will be an important factor in regulating serum levels of retinol.     

Vitamin A transport: in vitro models for the study of RBP secretion

Retinol-binding protein (RBP) is the specific plasma carrier of retinol, encharged of the vitamin transport from the liver to target cells. Ligand binding influences the RBP affinity for transthyretin (TTR), a homotetrameric protein involved in the RBP/TTR circulating complex, and the secretion rate of RBP. In fact, in vitamin A deficiency, the RBP release from the hepatocytes dramatically decreases and the protein accumulates in the cells, until retinol is available again. The mechanism is still not clear and new cellular models are needed to understand in detail how the soluble RBP can be retained inside the cell. In fish, a vitamin A transport system similar to that of higher vertebrates is emerging, although with significant differences.     

Comparative ligand-binding analysis of ten human lipocalins

At least ten different lipocalins occur in the human body: retinol-binding protein (RBP), alpha1-acid glycoprotein, alpha1-microglobulin, apolipoprotein D, beta-trace protein, complement component 8gamma, glycodelin, neutrophil gelatinase-associated lipocalin, odorant-binding protein, and tear lipocalin. Although many of these lipocalins seem to play an important physiological role, their precise biological function is not always clear. Especially the interpretation of their diverse ligand-binding activities has been hampered by the fact that the natural lipocalins were prepared from different sources and with varying purity. Here we present a generic expression and purification strategy for the recombinant lipocalins, which is based on secretion into the periplasm of E. coli, where disulphide bonds are readily formed, followed by affinity purification via the Strep-tag II and gel filtration. The ten human lipocalins were successfully prepared and their ligand-binding activities were compared via fluorescence titration with a set of typical ligands: retinol, retinoic acid (RA), 11-(5-(dimethylamino)-1-naphthalene-sulfonylamino)undecanoic acid (DAUDA), and 8-anilino-1-naphtalene-sulfonic acid (ANS). As result, merely two lipocalins, RBP and beta-trace, revealed high affinities both for retinol and for RA, which probably reflects a specialized physiological function in retinoid complexation. Surprisingly, the strongest retinol affinity was detected for apolipoprotein D, whereas this lipocalin exhibits much weaker binding activity for retinoic acid. Binding studies with the two spectroscopic probes DAUDA and ANS revealed mixed patterns, which demonstrates that the affinity for lipophilic substances varies considerably among human lipocalins. Notably, RBP with its perfectly moulded retinol-binding site did not show any detectable binding activity for both compounds. Hence, our recombinant expression and purification system should be useful for further structural and functional studies of lipocalins from human origin and beyond.     

Interactions of retinol with binding proteins: studies with rat cellular retinol-binding protein and with rat retinol-binding protein

The interactions of retinol with rat cellular retinol-binding protein (CRBP) and with rat serum retinol-binding protein (RBP) were studied. The equilibrium dissociation constants of the two retinol-protein complexes (Kd) were found to be 13 x 10(-9) and 20 x 10(-9) M for CRBP and for RBP, respectively. The kinetic parameters governing the interactions of retinol with the two binding proteins were also studied. It was found that although the equilibrium dissociation constants of the two retinol-protein complexes were similar, retinol interacted with CRBP 3-5-fold faster than with RBP; the rate constants for dissociation of retinol from CRBP and from RBP (koff) were 0.57 and 0.18 min-1, respectively. The rate constants for association of retinol with the two proteins (kon) were calculated from the expression: Kd = koff/kon. The kon's for retinol associating with CRBP and with RBP were found to be 4.4 x 10(7) and 0.9 x 10(7) M-1 min-1, respectively. The data suggest that the initial events of uptake of retinol by cells are not rate-limiting for this process and that the rate of uptake is probably determined by the rate of metabolism of this ligand. The data indicate further that the distribution of retinol between RBP in blood and CRBP in cytosol is at equilibrium and that intracellular levels of retinol are regulated by the levels of CRBP.     

Mouse retinol binding protein gene: Cloning,expression and regulation by retinoic acid

A full-length cDNA clone encoding the retinol binding protein (RBP) was isolated from a mouse liver cDNA library by hybridization screening. The nucleotide sequence of murine RBP is 85 and 95% homologous to that of human and rat RBP, respectively, with a deduced amino acid sequence 83% homologous to both species. Analysis of the tissue expression pattern of RBP mRNA in the female mouse indicated relatively abundant expression in the liver, with lesser amounts in extrahepatic tissues including adipose, kidney, spleen and uterus, suggesting that these tissues may have a significant role in retinol homeostasis. Mouse liver cell RBP regulation by retinoids was also investigated. Both all-trans retinoic acid (AT-RA) and 9-cis retinoic acid (9c-RA) induced RBP mRNA expression in a dose- and time-dependent manner. Maximal levels (up to 4-fold above controls) were observed at 48h following treatment of both mouse hepatoma cells in vitro and in vivo in mice receiving a single, oral dose of either retinoid. Interestingly, 9c-RA was more potent at RBP induction in both in vivo and in vitro systems. Given the extent and temporal pattern of RBP induction, we suggest that the RA-mediated increase in liver RBP is part of a cellular protection mechanism. Increased levels of RBP would facilitate sequestration and possibly cellular export of RA in cells receiving prolonged exposure to high levels of RA, thus minimizing toxicity.     

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.     

Regulation of plasma retinol binding protein secretion in human HepG2 cells

Retinol binding protein (RBP) is the plasma transport protein of retinol. Mobilization of RBP from the liver stores is stimulated by retinol. During vitamin A deficiency, RBP secretion is specifically inhibited while its rate of biosynthesis is unaffected. As a consequence, RBP, as apoprotein, accumulates inside the endoplasmic reticulum (ER) of the hepatocyte, and a new elevated steady-state concentration is reached. We have studied the role of degradation on the regulation of RBP metabolism in retinol deficient HepG2 cells and determined the intracellular site where RBP degradation takes place. Pulse-chase experiments show that RBP half-life is ca.9 h in retinol-depleted cells. RBP degradation is slow and is insensitive to the treatment with NH4Cl, which inactivates lysosomal proteases and to the drug brefeldin A, which prevents protein export from the ER. The data obtained suggest that RBP degradation occurs, at least in part, in a pre-Golgi compartment. 2-Mercaptoethanol, at millimolar concentration, induces RBP secretion, suggesting a possible role for sulfhydryl-mediated apo-RBP retention by resident ER proteins.     

Effect of renal and liver failure on blood levels of vitamin A, its precursor (beta-carotene) and its carrier proteins (prealbumin and retinol binding protein)

Plasma beta-carotene and retinol assay was performed by high pressure liquid chromatography (HPLC) in subjects with chronic renal failure or liver cirrhosis. In the same subjects blood prealbumin (PA) and retinol binding protein (RBP) were determined by immunological technique. A considerable increase of retinol and in a lesser extent of beta-carotene was noted in the blood of patients with renal insufficiency. In cirrhotic patients it was shown a marked decrease both of beta-carotene and retinol plasma concentrations. PA and RBP there were greatly increased in renal failure and decreased in liver cirrhosis. This results suggest that kidney and liver chronic failure interfere with vitamin A metabolism throughout their action on metabolic processes of synthesis and elimination of PA and RBP.     

Demonstration of immunoreactive retinol-binding protein and prealbumin in developing chicken embryo.

The immunoreactive retinol-binding protein (RBP) and prealbumin (PA) were identified in chicken embryo by the method of double immunodiffusion using antisera against purified chicken serum RBP and PA, respectively. The embryonic RBP studied by a fluorospectrophotometric analysis showed presence of vitamin A (retinol) within the molecule. The RBP and PA fractionated on a column of Sephadex G-200 had molecular weight of approximately 20,000 and 56,000, respectively. RBP and PA formed a complex with vitamin A which had a molecular weight of approximately 76,000. The developmental changes of RBP and PA in the chicken embryo were determined in the eye, brain, serum and liver by the single radial immunodiffusion. In the brain and eye, the maxima for the concentration of RBP and PA were detected at day 6 for RBP, and day 6 and day 13 for PA during development. However, these proteins were not detected in the tissues of young chicken. The concentration of the serum embryonic RBP and PA showed a maximum at day 6. With regard to the liver, the PA was observed in the embryo only at day 13, but the RBP only after hatching.