A high-affinity folate binding protein in human urine. Radioligand binding characteristics,immunological properties and molecular size

High-affinity binding of [³H]folate in human urine displayed characteristics, e.g. apparent positive cooperativity, which are typical of specific folate binding. By means of a two-site enzyme-linked immunosorbent assay (ELISA) with rabbit antibodies against the low molecular weight folate binding protein from human milk, we measured folate binding protein concentrations in the range of 0.51 to 4.13 nM in urine samples from 16 apparently healthy individuals. Ultrogel AcA 44 chromatography of the urine showed that immunoreactive and radioligand bound folate binding protein coeluted in one large peak (M_r25,000).     

A high-affinity folate binding protein in human amniotic fluid. Radioligand binding characteristics,immunological properties and molecular size

The presence of a folate binding protein of high-affinity type (affinity constant 5 · 10⁹M^–1, maximum folate binding 3 nM) in human amniotic fluid was demonstrated in equilibrium dialysis experiments (37°C, pH 7.4) with the radioligand³H-folate. Dissociation of³H-folate from the binding protein was slow at pH 7.4 but rapid at pH 3.5. By use of rabbit antibodies against low molecular weight folate binding protein from human milk we determined the concentration of folate binding protein in 5 amniotic fluids (range 1.5–2.3 nM) in an Enzyme-Linked Immunosorbent Assay (ELISA). ultrogel AcA 44 chromatography of amniotic fluid showed that immunoreactive and radioligand bound folate binding protein coeluted in two peaks: a major one (M _r 25 000) and a minor one (M _r 100 000).     

A high-affinity folate binding protein in human semen

The presence of a folate binding protein of high-affinity type (affinity constant 3.10¹⁰M^–1, maximum folate binding 1.4 nM) in human semen was demonstrated in equilibrium dialysis experiments (37°C, pH 7.4) with the radioligand³H-folate. Radioligand dissociation from the binding protein was slow at pH 7.4, but rapid at pH 3.5. By use of rabbit antibodies against 25 kDa human milk folate binding protein we determined the concentration of folate binding protein in 16 speciments of human semen in an enzyme-linked immunosorbent assay. The concentration of immunoreactive folate binding protein was independent of the number of spermatozoa in individual specimens. Gel filtration showed that immunoreactive and radioligand bound folate binding protein coeluted in two peaks: a major one of 100 kDa and a minor one of 25 kDa.     

Charge heterogeneity of the folate binding protein in normal human leukocytes

The DEAE-Sepharose CL-6B chromatographic profile of supernatant from homogenized normal human leukocytes containing large amounts of folate binder revealed two peaks of binding activity. A minor binder (I) eluted with the equilibrating buffer (1 mM sodium phosphate of pH 6.0), while the major binder (II) first eluted after the initiation of a linear phosphate gradient with 200 mM sodium phosphate of pH 7.6 as the limiting buffer. Binder II was thus a more acidic protein since it required elution by a salt-pH gradient. Binding of [3H] folate to binder II was of a high-affinity type (K = 10(10) M-1) and displayed positive cooperativity.     

Ligand binding characteristics of two molecular forms,one equipped with a hydrophobic glycosyl phosphatidylinositol tail,of the folate binding protein purified from human milk

Two molecular forms of the folate binding protein were isolated and purified from human milk by a combination of cation exchange- and affinity chromatography. One protein (27 kDa) was a cleavage product of the other 100 kDa protein as evidenced by N-terminal amino acid sequence homology and a reduction in the molecular size of the latter protein to 27 kDa after cleavage of its hydrophobic glycosylphosphatidylinositol tail by phosphatidylinositol-specific phospholipase C. High-affinity binding of [³H]folate was characterized by upward convex Scatchard plots and increasing ligand binding affinity with decreasing concentrations of both proteins. Downward convex Scatchard plots and binding affinities showing no dependence on the protein concentration were, however, observed in highly diluted solutions of both proteins. Radioligand binding was inhibited by folate analogs, and dissociation of radioligand was slow at pH 7.4 but rapid and complete at pH 5.0 and 3.5. Ligand binding quenched the tryptophan fluorescence of the 27 kDa protein suggesting that tryptophan is present at the binding site and/or ligand binding induces a conformation change that affects tryptophan environment in the protein. The 27 kDa protein representing soluble folate binding protein exhibited a greater affinity for ligand binding than the 100 kDa protein which possesses a hydrophobic tail identical to the one that anchors the folate receptor to the cell membrane.     

Specific high-affinity binding protein for human corticotropin-releasing hormone in normal human plasma

A protein of Mr 25-40 kilodaltons in normal human plasma binds human corticotropin-releasing hormone (hCRH), but not ovine CRH. Binding requires both N- and C-terminal hCRH sequences and has a Kd of 2 X 10(-10) M and a binding site concentration of 1.4 pmoles per ml of plasma. Its binding is not affected by heating to 56 degrees C for 1 h, but is abolished by exposure to 6 M guanidine-HCl, 10 mM dithiothreitol. Binding proceeds rapidly at 37 degrees C and is 75% complete within 4 min. Neither rat nor sheep plasma appears to contain a CRH-binding protein. CRH-binding protein may explain the brief biological action of hCRH as compared to ovine CRH in man and why high concentrations of plasma immunoreactive hCRH in women during third-trimester pregnancy do not cause increased ACTH secretion.     

High-affinity folate receptor in human ovary, serous ovarian adenocarcinoma, and ascites: radioligand binding mechanism, molecular size, ionic properties, hydrophobic domain, and immunoreactivity.

High-affinity folate receptors are expressed in normal ovaries and ovarian carcinomas. Binding of [3H]folate in human ovary, serous ovarian carcinoma tissue, and ascites is a complex process that has not been well characterized. This study shows changes in binding affinity and mechanism of binding with decreasing receptor concentration, inhibition by folate derivatives, and a slow radioligand dissociation at pH 7.4 becoming rapid and complete at pH 3.5. The receptor seems to be positively charged since it elutes in the front effluent of a DEAE-Sepharose CL-6B ion-exchange column at pH 6.3. The gel filtration profile of Triton X-100-solubilized tissue and ascites contained two peaks of radioligand-bound receptor (25 and 100 kDa). Exposure of ascites to cleavage by phosphatidylinositol-specific phospholipase C resulted in a partial conversion of the 100-kDa peak to a 25-kDa peak. This suggests that the receptor may be anchored to the membrane by a glycosylphosphatidyl residue that inserts into Triton X-100 micelles, resulting in a large molecular size on gel filtration. The receptor in ovarian carcinoma tissue immunoreacts with antibodies against purified human milk folate receptor protein as shown by enzyme-linked immunosorbent assay, immunoprecipitation, sodium dodecyl sulfate-polyacrylamide gel electrophoresis immunoblotting (a single band of 45 kDa), and immunohistochemistry. In only three of seven ovarian carcinomas did expression of radioligand-bound receptors exceed levels found in five normal ovaries. However, only receptors in ovarian carcinoma specimens showed a high degree of immunoreactivity. Hence, even without elevations of the total receptor level, a folate receptor isoform homologous to human milk folate receptor protein seemed to prevail in serous ovarian carcinomas.     

Development of a specific radioimmunoassay for the placental folate receptor and related high-affinity folate binding proteins in human tissues

High-affinity membrane-associated and soluble folate binding proteins (FBPs) from human placenta, milk, and KB cells appear to share antigenic determinants [A. C. Antony et al. (1981) J. Biol. Chem. 256, 9684-9692 and (1985) 260, 14911-14917]. Iodination of a highly purified preparation of placental folate receptor (PFR) by various techniques resulted in significant denaturation of the PFR as evidenced by additional peaks of radioactivity on Sephacryl S-200 gel filtration in 1% Triton X-100. These denatured species had similar molecular weights on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) as radioiodinated and native PFR, and were also recognized, albeit with less efficiency, by specific rabbit antiserum raised against purified PFR. Since these denatured species failed to bind folate, they were specifically excluded from 125I-PFR by their inability to bind pteroylglutamate-Sepharose. This ws accomplished in a single step by iodination of PFR bound to the affinity column and elution of 125I-PFR under identical conditions that the native PFR was purified. The purified 125I-PFR comigrated with unlabeled PFR on SDS-PAGE and its elution profile on Sephacryl S-200 gel filtration was identical to radioligand bound PFR. The resulting radioimmunoassay standard curve using this affinity chromatography purified 125I-PFR, unlabeled PFR, and anti-human PFR serum had a range for measurement between 5 and 500 ng of PFR and was not affected by the concentration of folate in the sample. The practical utility of this radioimmunoassay for measuring cross-reacting material to the PFR was validated by its ability to quantitate the 40,000 and 160,000 Mr FBPs which are the two major forms of high-affinity FBPs in human tissues.     

A bacterial high-affinity GABA binding protein: isolation and characterization

A gamma-aminobutyric acid (GABA) binding protein (GBP) was isolated from a bacterial mutant which has high-affinity GABA binding characteristics comparable with the GABA(A) brain receptor in mammals. The GBP was partially purified and characterized and was shown to be a periplasmic protein of approximately 42,000 molecular weight. To determine the molecular weight, a bacterial GABA binding assay was used with SDS-PAGE. This procedure did not require large amounts or complete purification of protein and may be useful as a simple method in estimating the molecular weight of other bacterial binding proteins.     

Ligand binding characteristics and aggregation behavior of purified cow's milk folate binding protein depends on the presence of amphiphatic substances including cholesterol,phospholipids, and synthetic detergents

Folate binding protein was purified from cow's milk by a combination of cation exchange chromatography and methotrexate-AH-sepharose affinity chromatography. Dilution of the preparation to concentrations of protein less than 10 nM resulted in drastic changes of radioligand (folate) binding characteristics, i.e., a decrease in binding affinity with a change from upward to downward convex Scatchard plots and increased ligand dissociation combined with appearance of weak-affinity aggregated forms of the binding protein on gel filtration. These findings, consistent with a model predicting dimerization between unliganded and liganded monomers, were reversed in the presence of material eluted from the affinity column after adsorption of the protein(cofactor) or cholesterol, phospholipids, and synthetic detergents. The latter amphiphatic substances form micelles and lipid bilayers which could separate hydrophobic unliganded monomers from hydrophilic liganded monomers in the surrounding aqueous medium and thereby prevent association between these monomeric forms prevailing at low concentrations of the protein. Our data have some bearings on studies which show that cholesterol and phospholipids are necessary for the clustering of folate receptors in the cell membrane; a process required for optimum receptor function and internalization of folate.     

Mediated uptake of folate by a high-affinity binding protein in sublines of L1210 cells adapted to nanomolar concentrations of folate

Summary An L1210 cell line (JT-1), which can grow in medium supplemented with 1nm folate, has been isolated. These cells exhibit a slower growth rate than folate-replete parental cells and have a lower ability to transport folate or methotrexate via the reduced folate transport system. Measurements at nanomolar concentrations of folate revealed that the adapted cells have acquired a high-affinity folate-binding protein. Binding to this component at 37°C was rapid and reached a maximum value after 30 min which corresponded in amount to 0.23±0.3 pmol/mg protein, and excess unlabeled folate added 30 min subsequent to the [³H]folate led to a rapid release of the bound substrate. Radioactivity bound to or released from the cells after 30 min at 37°C remained as unmetabolized folic acid. Binding was also rapid at 0°C but uptake at the plateau was only one-half the value obtained at 37°C. Half-maximal saturation of the binding component (K _D) occurred at a folate concentration of 0.065nm at pH 7.4, while the affinity for folate decreased 30-fold when the pH was reduced to 6.2 (K _D=2.0nm). 5-Methyltetrahydrofolate was also bound by this component (K _i=13nm at pH 7.4) but with a much lower affinity than for folate, while progressively weaker interactions were observed with 5-formyltetrahydrofolate (K _i=45nm) and methotrexate (K _i=325nm). When the same adaptation procedure was performed with limiting amounts of 5-formyltetrahydrofolate, two additional cell lines, JT-2 and JT-3, were isolated which expressed elevated levels of the folate-binding protein. The binding activity of the latter cells was 0.46 and 1.4 pmol/mg protein, respectively. When the level of binding protein was compared in cells grown at different concentrations of folate, an increase in medium folate from 1 to 500nm caused a sevenfold reduction in binding activity in the JT-3 cell line, while these same growth conditions had no effect on binding by the other cells. These results indicate that L1210 cells adapted to low concentrations of folate or 5-formyltetrahydrofolate contain elevated levels of a high-affinity binding protein and that this protein is able to mediate the intracellular accumulation of folate compounds. L1210 cells thus appear to have two potential uptake routes for folate compounds, the previously characterized anion-exchange system and a second route mediated by a high-affinity binding protein. An additional low-affinity, high-capacity transport system for folate that had been proposed previously was not observed under a variety of experimental conditions in either the adapted or parental cells.     

Mediated uptake of folate by a high-affinity binding protein in sublines of L1210 cells adapted to nanomolar concentrations of folate

An L1210 cell line (JT-1), which can grow in medium supplemented with 1 nM folate, has been isolated. These cells exhibit a slower growth rate than folate-replete parental cells and have a lower ability to transport folate or methotrexate via the reduced folate transport system. Measurements at nanomolar concentrations of folate revealed that the adapted cells have acquired a high-affinity folate-binding protein. Binding to this component at 37 degrees C was rapid and reached a maximum value after 30 min which corresponded in amount to 0.23 +/- 0.3 pmol/mg protein, and excess unlabeled folate added 30 min subsequent to the [3H]folate led to a rapid release of the bound substrate. Radioactivity bound to or released from the cells after 30 min at 37 degrees C remained as unmetabolized folic acid. Binding was also rapid at 0 degrees C but uptake at the plateau was only one-half the value obtained at 37 degrees C. Half-maximal saturation of the binding component (KD) occurred at a folate concentration of 0.065 nM at pH 7.4, while the affinity for folate decreased 30-fold when the pH was reduced to 6.2 (KD = 2.0 nM). 5-Methyltetrahydrofolate was also bound by this component (Ki = 13 nM at pH 7.4) but with a much lower affinity than for folate, while progressively weaker interactions were observed with 5-formyltetrahydrofolate (Ki = 45 nM) and methotrexate (Ki = 325 nM). When the same adaptation procedure was performed with limiting amounts of 5-formyltetrahydrofolate, two additional cell lines, JT-2 and JT-3, were isolated which expressed elevated levels of the folate-binding protein. The binding activity of the latter cells was 0.46 and 1.4 pmol/mg protein, respectively. When the level of binding protein was compared in cells grown at different concentrations of folate, an increase in medium folate from 1 to 500 nM caused a sevenfold reduction in binding activity in the JT-3 cell line, while these same growth conditions had no effect on binding by the other cells. These results indicate that L1210 cells adapted to low concentrations of folate or 5-formyltetrahydrofolate contain elevated levels of a high-affinity binding protein and that this protein is able to mediate the intracellular accumulation of folate compounds. L1210 cells thus appear to have two potential uptake routes for folate compounds, the previously characterized anion-exchange system and a second route mediated by a high-affinity binding protein.(ABSTRACT TRUNCATED AT 400 WORDS)     

A human membrane-associated folate binding protein is anchored by a glycosyl-phosphatidylinositol tail

Membrane-associated and soluble forms of folate binding protein (FBP) have been identified in mammalian tissues and biological fluids. Despite their solubility differences, these two forms are functionally similar, immunologically cross-reacting, and have the same apparent molecular weights. In this study we demonstrate, for the first time, that the membrane FBP of cultured human KB cells contains a glycosyl-phosphatidylinositol (GPI) tail which is responsible for its hydrophobic properties and distinguishes it from the soluble FBP released into the medium. Treatment of the purified membrane FBP with phospholipase C specific for phosphatidylinositol (PI-PLC) removed the GPI tail and converted it to the soluble form without a change in apparent Mr by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In addition, virtually all of the folate binding sites on the plasma membrane of the intact cells were released as soluble, functional FBP following treatment with PI-PLC. The GPI tail contained 1-O-alkyl-2-O-acylglycerol as a mixture of fatty alcohols in ether linkage at C1 of the glycerol backbone and almost exclusively docosanoic acid (22:0) as the fatty acid on C2. The inositol also contained a mixture of fatty acids (16:0, 18:0, 18:1, 20:4, 22:0) located on a site other than the C2 position since the FBP was susceptible to PI-PLC cleavage. After nitrous acid deamination, the aqueous portion of the FBP contained covalently bound fatty acids, predominantly palmitate (16:0) and stearate (18:0), indicating the presence of additional acyl groups attached to the peptide in the form of amide, ester, or thioester linkage.     

Rabbit antibodies against the low molecular weight folate binding protein from human milk. Use for immunological characterization of human folate binding proteins in an enzyme-linked immunosorbent assay (ELISA)

Antibodies to a low molecular weight folate binding protein isolated from human milk were raised in rabbits and used for development of a two-site enzyme-linked immunosorbent assay (ELISA) for immunological characterization of human folate binding proteins (FBPs). The high and low molecular weight FBPs from human milk were immunologically indistinguishable. Furthermore, the FBPs in human urine and cerebrospinal fluid showed a cross-reactivity of 70% and 30%, respectively. No cross-reactivity of the FBP from cow's milk was observed.     

Two molecular forms of the human interferon-gamma receptor. Ligand binding, internalization, and down-regulation

The receptors for human interferon-gamma (IFN-gamma) on peripheral blood monocytes and various cells of nonhematopoietic origin were thoroughly characterized and compared. The receptors of all cell types exhibited a similar affinity for IFN-gamma (Kd approximately 1 x 10(-10) M), and in all cases receptor-mediated endocytosis and ligand degradation were demonstrated. However, the receptors differed in their molecular weights (95,000 in HeLa cells and 140,000 in monocytes, assuming a 1:1 ligand to receptor ratio) as concluded from experiments of cross-linking to 125I-IFN-gamma. Lower molecular weight species were obtained as well, particularly in monocytes. Such species could represent either degradation products or subunit structures. The monocyte and HeLa receptor responded differently to an excess of ligand. A significant receptor down-regulation was observed when monocytes were incubated with an excess of 125I-IFN-gamma, whereas no such down-regulation was observed in HeLa cells or in normal fibroblasts. This differential response was observed both in the presence or in the absence of a protein synthesis inhibitor. The receptor on monocytes was found to be acid-labile whereas that on HeLa cells was resistant to acid treatment. These and additional experiments indicate that the monocyte receptor is inactivated following internalization, whereas the HeLa receptor retains its structure and recycles back to the cell surface. The difference in the properties and fate of these two receptor subtypes is probably related to the differential functions of IFN-gamma in various cell types.     

A combination of cation exchange and ligand-affinity chromatography for purification of two molecular species of the folate binding protein in human milk,one equipped with a hydrophobic glycosyl phosphatidylinositol tail: characterization of hydrophobicity and electrical charge

Cation exchange chromatography combined with ligand (methotrexate) affinity chromatography on a column desorbed with a pH-gradient was used for separation and large scale purification of two folate binding proteins in human milk. One of the proteins, which had a molecular size of 27 kDa on gel filtration and eluted from the affinity column at pH 5-6 was a cleavage product of a 100 kDa protein eluted at pH 3-4 as evidenced by identical N-terminal amino acid sequences and a reduction in the molecular size of the latter protein to 27 kDa after cleavage of its hydrophobic glycosylphosphatidyl-inositol tail that inserts into Triton X-100 micelles. Chromatofocusing showed that both proteins possessed multiple isoelectric points within the pH range 7-9. The 100 kDa protein exhibited a high affinity to hydrophobic interaction chromatographic gels, whereas this was only the case with unliganded forms of the 27 kDa protein indicative of a decrease in the hydrophobicity of the protein after ligand binding.     

Ligand binding and protein dynamics in lactate dehydrogenase

Recent experimental studies suggest that lactate dehydrogenase (LDH) binds its substrate via the formation of a LDH/NADH.substrate encounter complex through a select-fit mechanism, whereby only a minority population of LDH/NADH is binding-competent. In this study, we perform molecular dynamics calculations to explore the variations in structure accessible to the binary complex with a focus on identifying structures that seem likely to be binding-competent and which are in accord with the known experimental characterization of forming binding-competent species. We find that LDH/NADH samples quite a range of protein conformations within our 2.148 ns calculations, some of which yield quite facile access of solvent to the active site. The results suggest that the mobile loop of LDH is perhaps just partially open in these conformations and that multiple open conformations, yielding multiple binding pathways, are likely. These open conformations do not require large-scale unfolding/melting of the binary complex. Rather, open versus closed conformations are due to subtle protein and water rearrangements. Nevertheless, the large heat capacity change observed between binding-competent and binding-incompetent can be explained by changes in solvation and an internal rearrangement of hydrogen bonds. We speculate that such a strategy for binding may be necessary to get a ligand efficiently to a binding pocket that is located fairly deep within the protein's interior.