Rapid isolation of bovine interphotoreceptor retinol-binding protein

A large retinol-binding protein, interphotoreceptor retinol-binding protein, is found only in the interphotoreceptor matrix of the eye, and may function in vitamin A transport for the visual cycle. Interphotoreceptor retinol-binding protein is the major glycoprotein of this matrix, and can be isolated rapidly by affinity-adsorption onto concanavalin A-Sepharose. The yield is approx. 0.25 mg per bovine eye. Its apparent Mr is 250000 by gel-filtration chromatography, and 225000 by native polyacrylamide-gradient gel electrophoresis; this protein band displays endogenous retinol fluorescence on such gels. As measured by SDS-polyacrylamide gel electrophoresis, the apparent Mr is 140000. In the interphotoreceptor matrix most vitamin A-binding sites on this retinol-binding protein are unoccupied; however, addition of exogenous all-trans-retinol can saturate these sites. The apparent dissociation constant for retinol is 10(-6) M, as measured by fluorimetric titration.     

Rapid isolation of bovine interphotoreceptor retinol-binding protein

A large retinol-binding protein, interphotoreceptor retinol-binding protein, is found only in the interphotoreceptor matrix of the eye, and may function in vitamin A transport for the visual cycle. Interphotoreceptor retinol-binding protein is the major glycoprotein of this matrix, and can be isolated rapidly by affinity-adsorption onto concanavalin A-Sepharose. The yield is approx. 0.25 mg per bovine eye. Its apparent M_r is 250 000 by gel-filtration chromatography, and 225 000 by native polyacrylamide-gradient gel electrophoresis; this protein band displays endogenous retinol fluorescence on such gels. As measured by SDS-polyacrylamide gel electrophoresis, the apparent M_r is 140 000. In the interphotoreceptor matrix most vitamin A-binding sites on this retinol-binding protein are unoccupied; however, addition of exogenous all-trans-retinol can saturate these sites. The apparent dissociation constant for retinol is 10⁻⁶ M, as measured by fluorimetric titration.     

Synthesis and secretion of a novel binding protein for retinol by a cell line derived from Sertoli cells

An established cell line (TM-4) derived from murine Sertoli cells, the major supportive cell type of the testes, secretes a protein that binds retinol when grown in serum-free chemically defined medium. The protein that binds retinol is trypsin-sensitive and has an apparent Kd for retinol of 54 nM. Cholesterol, retinyl acetate, or UV-irradiated retinol at levels 100-fold in excess of retinol are poor competitors of [3H]retinol binding. Retinoic acid at a 100-fold molar excess inhibited [3H]retinol binding by 71%. In contrast, excess unlabeled retinol completely inhibits [3H]retinol binding. More than 80% of the total retinol-binding activity in confluent cultures is found in the culture medium. Prior to incubation with retinol, the protein that binds retinol has an apparent Mr of less than 150,000 by column chromatography; however, after incubation with retinol the protein that binds retinol exhibits an apparent Mr of 2 X 10(6) or greater and a sedimentation coefficient greater than 4 S. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis reveals that the major iodinatable component of the aggregated protein that binds retinol has an apparent Mr of 70,000. The secreted protein that binds retinol is not immunologically cross-reactive with either serum or cellular retinol-binding protein or transferrin. These findings suggest that Sertoli cells may secrete a protein that binds retinol. Such a protein could be involved in the transport of retinol either to the lumen of the seminiferous tubules or to the developing germ cells themselves.     

Transport of retinol in the duck plasma

Retinol-binding protein and prealbumin were isolated from duck plasma by chromatography on DEAE-cellulose-and DEAE-Sephadex A-50, gel filtration on Sephadex G-100 and preparative Polyacrylamide gel electrophoresis. The molecular weights of the retinol-binding protein-prealbumin complex, prealbumin and retinol-binding protein were found to be 75,000, 55,0000 and 20,000, respectively. On sodium dodecyl sulphate Polyacrylamide gel electrophoresis, prealbumin dissociated into identical subunits exhibiting a molecular weight of 13,500. Retinol-binding protein exhibited microheterogeneity on electrophoresis, whereas prealbumin moved as a single band unlike the multiple bands observed in chicken and rat. The ultraviolet and fluorescence spectra of the two proteins were similar to those isolated from other species. No carbohydrate moiety was detected in either retinol-binding protein or prealbumin. Duck retinol-binding protein and prealbumin showed cross-reactivity with their counterparts in chicken but differed immunologically from those of goat and man. Retinol-binding protein and prealbumin could be dissociated at low ionic strength, in 2M urea, by CM-sephadex chromatography or on preparative electrophoresis. Although the transport of retinol in duck plasma is mediated by carrier proteins as in other species, it is distinguished by the absence of microheterogeneity in prealbumin and of an apo-retinol-binding protein form that could be transported in the plasma.     

Vitamin A receptors. I. Comparison of retinol binding to serum retinol-binding protein and to tissue receptors in chick retina and pigment epithelium.

1. A simple, efficient three-step method for purification of serum retinol-binding-protein is described with homogeneity obtained after chromatography on DEAE-Sephadex, CM-Sephadex and Sephadex G-100. 2. Evidence is presented indicating that retinol receptors present in the cytosol fraction of chick retina and pigment epithelium are separate and distinct from purified retinol-binding protein. Fluorescence characteristics are different in tissue cytosol and serum as assessed by sucrose density gradient analysis. Tissue retinol receptors do not interact with human serum prealbumin although the prealbumin readily complexes with purified chicken retinol-binding protein. Likewise, no binding to serum retinol-binding protein antibody could be detected by sucrose density gradient analysis, in immunoprecipitation experiments or by double immunodiffusion. It thus appears that specific retinol receptors are present in neural retina and pigment epithelium that are different from serum retinol-binding protein.     

Purification and partial characterization of a cellular retinol-binding protein from human liver

A protein with binding specificity for retinol was purified from human liver. [³H]Retinol was added to liver extracts and the [³H]retinol-binding protein isolated by conventional chromatographic techniques including ion-exchange chromatography on DEAE-Sepharose, gel filtration on Sephadex G-75 and G-50 and preparative isoelectric focusing. The yield was 10–15% in different preparations and the degree of purification was about 3000-fold. The purified protein had a molecular weight of about 15 000 as estimated from both gel filtration and polyacrylamide gel electrophoresis in sodium dodecyl sulphate and was homogeneous in several electrophoretic systems. Isoelectric focusing of the purified protein gave a doublet band. Only one fluorescent band at pH 4.70 was seen if the protein solution was incubated with excess retinol prior to isoelectric focusing. The isolated protein did not react with antiserum to the retinol-binding protein of plasma. The amino acid composition and the amino terminal amino acid sequence for the first sixteen amino acids of the purified protein differed significantly from that of the plasma retinol-binding protein.     

Studies of the spontaneous transfer of retinol from the retinol: retinol-binding protein complex to unilamellar liposomes

The transfer of retinol from its complex with the retinol-binding protein to cell surfaces was studied using unilamellar liposomes as a cell surface model. The transfer of retinol to liposomes at 37°C was rapid and reached an apparent equilibrium within 60 min. The amount of retinol transferred to the liposomes at equilibrium was directly proportional to the starting concentration of retinol: retinol-binding protein over a wide range of retinol:retinol-binding protein concentrations and also directly proportional to the concentration of liposomal phospholipid in the system, when the concentration of retinol:retinol-binding protein was held constant. The transfer increased slightly with temperature. Transfer was increased by a factor of 1.8 at pH 4.5 compared to pH around 7. Prealbumin in amounts sufficient to complex all retinol:retinol-binding protein, decreased retinol transfer to liposomes indicating that prealbumin increases the affinity of retinol-binding protein for retinol. Addition of apo retinol-binding protein to the system decreased the transfer of retinol to liposomes considerably probably through competition with the liposomes for retinol. In similarly designed experiments delipidated bovine serum albumin competed much less with liposomes for retinol. The results show that spontaneous transfer of retinol from the retinol:retinol-binding protein complex to liposomal membranes occurs in vitro and suggests that a similar transfer may occur in vivo from retinol:retinol-binding protein to cell surface membranes.     

Studies of the spontaneous transfer of retinol from the retinol:retinol-binding protein complex to unilamellar liposomes

The transfer of retinol from its complex with the retinol-binding protein to cell surfaces was studied using unilamellar liposomes as a cell surface model. The transfer of retinol to liposomes at 37 degrees C was rapid and reached an apparent equilibrium within 60 min. The amount of retinol transferred to the liposomes at equilibrium was directly proportional to the starting concentration of retinol:retinol-binding protein over a wide range of retinol:retinol-binding protein concentrations and also directly proportional to the concentration of liposomal phospholipid in the system, when the concentration of retinol:retinol-binding protein was held constant. The transfer increased slightly with temperature. Transfer was increased by a factor of 1.8 at pH 4.5 compared to pH around 7. Prealbumin in amounts sufficient to complex all retinol:retinol-binding protein, decreased retinol transfer to liposomes indicating that prealbumin increases the affinity of retinol-binding protein for retinol. Addition of apo retinol-binding protein to the system decreased the transfer of retinol to liposomes considerably probably through competition with the liposomes for retinol. In similarly designed experiments delipidated bovine serum albumin competed much less with liposomes for retinol. The results show that spontaneous transfer of retinol from the retinol:retinol-binding protein complex to liposomal membranes occurs in vitro and suggests that a similar transfer may occur in vivo from retinol:retinol-binding protein to cell surface membranes.     

Acyl-CoA-independent esterification of retinol bound to cellular retinol-binding protein (type II) by microsomes from rat small intestine

Cellular retinol-binding protein (type II) (CRBP(II)), a newly described retinol-binding protein, is present in the small intestinal absorptive cell at high levels. Retinol (vitamin A alcohol) presented as a complex with CRBP(II) was found here to be esterified by microsomal preparations from rat small intestinal mucosa. The esterification observed utilized an endogenous acyl donor(s) and produced retinyl esters containing linoleate, oleate, palmitate, and stearate in a proportion quite similar to that previously reported for retinyl esters in lymph and isolated chylomicrons of rat. No dependence on endogenous or exogenous acyl-CoA could be demonstrated. The apparent Km for retinol-CRBP(II) in the reaction with endogenous acyl donor was 2.4 X 10(-7) M. Retinol presented as a complex with CRBP(II) was esterified more than retinol presented as a complex with cellular retinol-binding protein or retinol-binding protein, two other proteins known to bind retinol in vivo, but about the same as retinol presented bound to bovine serum albumin or beta-lactoglobulin. The ability of protein-bound retinol to be esterified was related to accessibility of the hydroxyl group, as judged by the ability of alcohol dehydrogenase to oxidize the bound retinol. However, whereas retinol bound to CRBP(II) was unavailable for esterification in any acyl-CoA-dependent reaction, retinol bound to bovine serum albumin was rapidly esterified in a reaction utilizing exogenous acyl-CoA. The results suggest that one of the functions of CRBP(II) is to accept retinol after it is absorbed or generated from carotenes in the small intestine and present it to the appropriate esterifying enzyme.     

A novel family of progesterone-induced, retinol-binding proteins from uterine secretions of the pig

Two-dimensional polyacrylamide gel electrophoresis has revealed the presence of a group of relatively acidic proteins of molecular weight about 22,000 in the uterine flushings of pseudopregnant pigs. The proteins have been purified by a combination of gel filtration chromatography and high performance anion-exchange chromatography and shown to bind both [3H] retinol and [3H]retinoic acid. At least four protein peaks that bound retinoids could be detected in the uterine secretions of a single pig. The ion-exchange procedure also allowed the retinol-free apoproteins to be separated from the holoforms that had associated ligand. Amino acid sequencing of the NH2 termini of polypeptides within three of the peaks revealed the presence of proteins with some degree of sequence identity to serum retinol-binding proteins (RBP). The most basic polypeptides showed the least similarity (about 30% identity), while the most acidic isoform analyzed shared about 70% sequence identity with the NH2 terminus of human serum RBP. Western blotting procedures employing an antiserum raised against the most basic isoforms showed that the amount of retinol-binding protein in uterine secretions increased markedly in ovariectomized animals in response to long term progesterone treatment. These proteins appear to form part of the uterine histotroph thought to be essential for nourishment of the conceptuses during pregnancy. A simple three-step procedure for purifying retinol-binding protein from pig serum is also described. The NH2-terminal sequence of this RBP is similar to that of human RBP but different from those of the uterine forms. The study suggests that a family of RBP, distinct from the serum form, is secreted by the uterine endometrium of the pig in response to progesterone.     

Purification of a bovine counterpart to human prealbumin and its interaction with a bovine retinol-binding protein

A bovine counterpart to human prealbumin was purified from bovine serum by thiol-disulfide exchange chromatography on thiol-Sepharose 4B and affinity chromatography on human retinol-binding protein linked to Sepharose 4B. The bovine prealbumin had alpha1-mobility on agarose gel electrophoresis at pH 8.6. It has the same molecular weight as human prealbumin on gel filtration and consisted of subunits with a molecular weight of 12 500. This is compatible with a tetrameric structure for the bovine protein. Antiserum against human prealbumin cross-reacted with bovine prealbumin and vice versa. The bovine prealbumin formed at high ionic strength complexes with another bovine serum protein which were dissociated at low ionic strength. This property was used to isolate a protein from bovine serum, by chromatography on bovine prealbumin linked to Sepharose which cross-reacted with antiserum against human retinol-binding protein; had a molecular weight of 21 000 and alpha 2-mobility on agarose gel electrophoresis. It was concluded that the latter protein was a bovine retinol-binding protein.     

The presence of a soluble interphotoreceptor retinol-binding protein (IRBP) in the retinal interphotoreceptor space

A new, gentle technique has been developed for washing of the retinal interphotoreceptor space (IPS) to obtain soluble components of the extracellular matrix (ECM). Using this method, we have determined that the major soluble coustituent of monkey IPS is a 146,000 M_r glycoprotein, which binds [³H]retinol, sediments on sucrose gradients at 7S and has an R_f of 0.42 on native gel electrophoresis. Using size-exclusion high performance liquid chromatography, the apparent molecular weight of the native protein was calculated to be 250,000 daltons. In contrast to previous studies, no 15,000-dalton cellular retinol-binding protein (CRBP) or 33,000-dalton cellular retinaldehydebinding protein (CRALBP) was observed in the IPS wash, indicating that these proteins are probably not involved in retinol transport between retina and pigment epithelium (PE). In the supernatant fraction of retinal homogenates that contains soluble intracellular proteins as well as extracellular constituents, the 146,000 M_r protein was closely associated with a 93,000 M_r protein that could be separated on SDS-gel electrophoresis; the 93,000 M_r protein was not found in the IPS wash. The 146,000 M_r interphotoreceptor retinol-binding protein (IRBP) may function in extracellular retinol transport in the IPS.     

Retinoic acid-binding protein in rat tissue. Partial purification and comparison to rat tissue retinol-binding protein.

When the 100,000 X g supernatant fractions of several rat organs are incubated with all-trans-[3H]retinoic acid, a binding component for retinoic acid with a sedimentation coefficient of 2 S can be detected by sucrose gradient centrifugation. This tissue binding protein for retinoic acid is distinct from the tissue binding protein for retinol which has been previously described. The tissue retinoic acid-binding protein has been partially purified from rat testis and this partially purified protein would appear to have a molecular weight of 14,500 as determined by gel filtration and high binding specificity for all-trans-retinoic acid. Binding of [3H]retinoic acid is not diminished by a 200-fold molar excess of retinal, retinol, or oleic acid but is reduced by a 200-fold excess of unlabeled retinoic acid. Tissue retinoic acid-binding protein can be detected in extracts of brain, eye, ovary, testis, and uterus but is apparently absent in heart muscle, small intestine, kidney, liver, lung, gastrocnemious muscle, serum, and spleen. This distribution is different than that observed for the tissue retinol-binding protein. Tissue retinol-binding protein was also purified extensively from rat testis. The partially purified protein has an apparent molecular weight of 14,000 and high binding specificity for all-trans-[3H]retinol as only unlabeled all-trans-retinol but not retinal, retinoic acid, retinyl acetate, retinyl palmitate, or oleic acid could diminish binding of the 3H ligand under the conditions employed. The partially purified protein has a fluorescence excitation spectrum with lambda max at 350 nm. In contrast, the retinol-binding protein isolated from rat serum and described by others has a fluorescence excitation spectrum with lambda max at 334 nm and an apparent molecular weight of 19,000. When partially purified tissue retinol-binding protein is extracted with heptane, the heptane extract has a fluorescence excitation spectrum similar to that of all-trans-retinol.     

Cellular retinol-binding protein from rat liver. Purification and characterization

Cellular retinol-binding protein has been purified to homogeneity from rat liver. The procedures utilized in the purification included acid precipitation, gel filtration on Sephadex G-75 and G-50, and chromatography on DEAE-cellulose. The binding protein was purified approximately 3,500-fold, based on total soluble liver protein. The protein is a single polypeptide chain with a molecular weight of 14,600 based on information obtained by the techniques of sedimentation equilibrium analysis, gel filtration, and sodium dodecyl sulfate-polyacrylamide electrophoresis. The protein binds retinol with high affinity; the appparent dissociation constant was determined by fluorometric titration to be 1.6 X 10(-8) M. Retinol bound to the protein has an absorption spectrum (lambdamax, 350 nm) considerably altered from the spectrum of retinol in ethanol (lambdamax, 325 nm).     

Retinol-binding protein in human serum: conformational changes induced by retinoic acid binding

Polyacrylamide gel electrophoresis and isoelectrofocusing followed by immunoblotting technique with an anti-human retinol-binding protein (RBP) serum were used to study holo-RBP and apo-RBP in human plasma. Three observations were made the technique allowed for the first time to directly and quantitatively analyse holo- and apo-RBP. Holo-RBP represented 97.86 +/- 0.78% and apo-RBP 1.94 +/- 0.73% of the total RBP. All-trans-retinoic acid (RA) was found to bind to apo-RBP and to significantly modify the tertiary structure of the protein; this raises the question of RBP involvement in the transport of RA. reconstitution of holo-RBP using apo-RBP from delipidized serum was achieved only after its incubation with natural all-trans-retinoids such as retinol, 3-dehydroretinol and retinoic acid but not with synthetic analogs of retinoic acid (13-cis-retinoic acid, TMMP, 13-cis-TMMP, TTNPB). It appears that RBP has a structure specificity for natural retinoids.     

Vitamin A transport in plasma of the non-mammalian vertebrates: isolation and partial characterization of piscine retinol-binding protein

Studies were conducted to explore vitamin A transport in the non-mammalian vertebrates, especially Pisces, Amphibia, and Reptilia, and to isolate and partially characterize piscine retinol-binding protein. Retinol-containing proteins in fresh plasma obtained from bullfrogs and a turtle exhibited similar properties to those found in mammalian and chicken plasma: i.e., molecular weight of about 60,000-80,000 as estimated by gel filtration and binding affinity to prealbumin on human prealbumin-Sepharose affinity chromatography. In sharp contrast, vitamin A-containing proteins in plasma from larvae of bullfrogs as well as three fishes (carp, blue sharks, and young yellowtails) appeared to be present in plasma as monomeric retinol-binding proteins without any affinity to human prealbumin. On the other hand, plasma vitamin A in the lamprey (Cyclostomes) was found to exist exclusively as an ester form in association with the lipoproteins of hydrated density less than 1.21 g/ml. Piscine retinol-binding protein was isolated from pooled plasma of young yellowtails and was converted (1000-fold purification) to a homogeneous component by a procedural sequence that included gel filtration on Sephadex G-100, chromatography on SP-Sephadex, gel isoelectric focusing, and, finally, polyacrylamide gel electrophoresis. Purified piscine retinol-binding protein showed physico-chemical properties distinctly different from the mammalian and chicken retinol-binding proteins examined, i.e., a smaller molecular weight of approximately 16,000, a lower isoelectric point of 4.3, a prealbumin mobility on analytical polyacrylamide gel electrophoresis, and a lack of binding affinity for human prealbumin; however, it displayed similar characteristics in two ways: a 1:1 molar complex with retinol, and a high content of tryptophan (four residues). These results strongly suggest that the piscine retinol-binding protein is a prototype of the specific vitamin A-transporting protein in plasma of the vertebrates, being modified later in evolution, during phylogenetic development of the vertebrates, to acquire a binding site for prealbumin on the molecule.     

Retinol-binding protein from human urine and its interaction with retinol and prealbumin

In freshly collected urine from a patient with glomerulotubular proteinuria there were two bands which contained retinol-binding proteins. The cathodal band showed fluorescence in the ultraviolet. After extraction with organic solvents only the anodal non-fluorescent band remained. After addition of an excess retinol only one band remained which by mobility corresponded to the cathodal band.The anodal of the two bands was therefore probably the apo form and the cathodal the holo form of the same retinol-binding protein. Their proportions, determined by densitometric scanning were approximately 4/1 (anodal/cathodal band). More than 85% of the retinol-binding protein in the urine bound to prealbumin-Sephrose. The apo retinol-binding protein from urine had the same electrophoretic mobility on agarose gel el-ctrophoresis and the same pattern on isoelectric focusing as an retinol-binding protein prepared from serum. The carboxy-terminal amino acid sequence of the retinol-binding protein from freshly collected urine that bound to prealbumin-Sepharose, was -Arg-Leu. The amino-terminal sequence was Glu-Arg-Asp-Cys-Arg-Val-Ser-X-Phe-Arg-Val-Lys-Glu-Asn-Phe-Asp-Lys-Ala-Arg-Phe-X-Gly-Thr-Trp-Tyr-. This sequence and the amino acid composition are compatible with the view that the retinol-binding protein in urine is the same as in plasma.     

Characterization, Localization, and Biosynthesis of an Interstitial Retinol-Binding Glycoprotein in the Human Eye

Abstract: Human eyes contain an M_r 135K retinol-binding protein that is analogous to interstitial retinol-binding protein (IRBP) in the subretinal space of bovine eyes. It is a glycoprotein, because it binds ¹²⁵I-concanavalin A, ¹²⁵I-wheat germ agglutinin and ¹²⁵I- Lens culinaris hemagglutinin. It does not bind Ricinus communis agglutinin I. After desialation, it binds Ricinus communis agglutinin I, but loses its capacity to bind wheat germ agglutinin. These observations, coupled with the known specificities of these lectins, suggest that at least one of the oligosaccharide chains is a sialated, biantennary complex type containing fucose. Both by direct analysis of dissected ocular tissues and by immunocytochemistry it was shown that human interstitial retinol binding protein is an extracellular protein that is confined predominantly to the subretinal space. Monkey retinas incubated in vitro in medium containing [³H]leucine were shown to synthesize and secrete this protein into the medium, a conclusion that was confirmed by immunoprecipitation with an immunoglobulin fraction prepared from rabbit antibovine IRBP serum. Virtually no other labeled proteins were detectable in the medium. It is concluded that interstitial retinol-binding protein meets many of the requirements for a putative transport protein implicated in the transfer of retinol between the pigment epithelium and retina during the visual cycle, and that the neural retina may play an important role in regulating its amount in the subretinal space.     

A rapid versatile microassay for cellular retinol-binding protein using Lipidex-1000 microcolumns

A new, rapid and versatile microassay for cellular retinol-binding protein has been developed based on separation of bound and free ligand by means of Lipidex-1000, a hydrophobic Sephadex derivative. This requires quantitative manipulation of retinol in aqueous solution. The tendency of retinol to adhere to glass and plastic surfaces was overcome by addition of the detergent Ammonyx LO, which yields a micellar dispersion. Detergent concentrations up to 10 mM did not interfere with binding of retinol to Lipidex-1000 or binding protein. The binding capacity of Lipidex-1000 was found to exceed 400 nmol of retinol per ml of gel. Retinal pigment epithelium (RPE) cells were used as a source for cRBP (cellular retinol-binding protein). The binding protein is saturated with ligand by incubation for 60 min at room temperature at concentrations of free retinol over 180 nM. Separation of protein-bound retinol from free retinol is achieved via Lipidex-1000: protein-bound (specific and nonspecific) retinol is not retained and is eluted by buffer with the protein fraction. Free retinol is retained by Lipidex and is subsequently recovered by elution with methanol. Total recovery of ligand approaches 100%. Analysis time is about 4 hr for a maximum of ca. 50 samples. Nonspecific protein binding can be determined equally effectively either by incubation with 3 mM PCMBS or by addition of a 100-fold molar excess of nonlabeled retinol.(ABSTRACT TRUNCATED AT 250 WORDS)