Polymorphic post-albumin of cattle and horse plasma identified as vitamin D binding protein (Gc protein)

Cattle and horse plasma samples of known post-albumin types were radiolabelled with ¹⁴C-vitamin D₃. These samples were then analysed by polyacrylamide gel electrophoresis, followed by autoradiography. The patterns observed were identical to those of post-albumin variants. The polymorphic post-albumin protein of cattle and horse was thus identified as the vitamin D binding protein and homologous to the Gc protein of human plasma.     

Affinity differences for vitamin D metabolites associated with the genetic isoforms of the human serum carrier protein (DBP)

Human vitamin D binding protein (DBP) displays considerable polymorphism with 120 described alleles. Among these, three alleles are frequently observed, Gc 1F (pI 4.94–4.84), Gc 1S (pI 4.95–4.85) and Gc 2 (pI 5.1). Differences between these genetic forms of the protein in affinity for vitamin D metabolites have been detected by electrophoretic methods. The constant affinity (Ka) values determined in this study confirm these differences. The affinities of six rare variants were also examine. Those of the DBP genetic forms to the vitamin D derivatives 25-OH-D₃ and 1,25-(OH)₂-D₃ seem to be related to the isoelectric point of the proteins: a high affinity corresponding to a low isoelectric point. The Gc 1A9 and 1A11 mutants were associated with higher affinity for the vitamin D derivatives and the Gc 1C1 and 1C21 mutants were deficient.     

Phenotype frequencies of vitamin D binding protein (Gc) and of posttransferrin-2 (Ptf-2) in Belgian cattle breeds*

The vitamin D binding protein (Gc) and posttransferrin-2 (Ptf-2) phenotypes have been determined in a number of Belgian cattle breeds. A very slow migrating variant of the Gc protein — Gc C — has been found in White and Red East Flemish breed. This variant was absent from the other breeds studied. This slow variant was identified as a vitamin D binding protein by autoradiography. The Gc C protein was shown to be controlled by a codominant autosomal allele Gc C at the Gclocus. The Gc C protein is probably identical with a fraction previously described in buffalo and an Italian cattle breed. The allele frequencies for the Gc and Pft-2 systems are reported for several Belgian breeds of cattle.     

Quantitative studies of the interaction of cholecalciferol ((vitamin D3) and its metabolites with different genetic variants of the serum binding protein for these sterols.

Cholecalciferol (vitamin D3) and its 25-hydroxy metabolite are transported in plasma bound to a specific protein, the binding protein for cholecalciferol and its metabolites (DBP). DBP is identical with the group-specific component (Gc) proteins, which are known to display genetic polymorphism. Studies were conducted to explore whether or not major differences in the transport of cholecalciferol and its biological metabolites might exist among persons with different Gc phenotypes. Detailed quantitative studies were first carried out on the interaction of 25(OH)D3 with DBP in 21 different samples of serum, representing eight different Gc phenotypes. The studies used a filter disc assay method that provided highly reproducible quantitative results with cholecalciferol-related sterols. The Gc phenotypes studied included the three common types (Gc 1-1, 2-1, and 2-2) and several uncommon genetic variants (Gc Ab-Ab, Ab-1, Ab-2, Chip-1, and Chip-2). The binding affinities for 25(OH)D3 observed with these different sera were all fairly similar to each other. More extensive studies were then conducted to compare the binding of four cholecalciferol-related sterols to each of three genetic variants of DBP, by using sera from homozygous persons with the Gc 1-1, Gc 2-2 and Gc Ab-Ab phenotypes. The ligands tested included cholecalciferol, 25(OH)D3, 1,25(OH)2D3, and 24(R) 25(OH)2D3. The affinities of the three genetic types of DBP/Gc protein were found to be similar for each of the four cholecalciferol-related sterols. The apparent association constants for 25(OH)D3 and 24,25(OH)2D3 were similar (approx. 1--2 x 10(8) M-1); lesser affinities were observed for 1,25(OH)2D3 (kA approx. 1 x 10(7) M-1) and for cholecalciferol (kA approx. 3--4 x 10(5) M-1). Thus the common genetic variants of DBP/Gc protein, and the uncommon genetic variants studied here, all appear to have similar binding properties for cholecalciferol and its several metabolites.     

Detection of genetic variation with radioactive ligands. III. genetic polymorphism of transcobalamin II in human plasma

We detected genetically determined, electrophoretic variants of vitamin B12 binding proteins, most probably transcobalamin II, in human plasma. Polymorphic variants were observed in all populations tested; the two most common alleles (of at least four detected to date) attain frequencies of greater than 40% in Caucasians and Orientals. The variants are autosomally inherited and are seen as doublets in homozygotes, and four-banded patterns, the sum of two dissimilar homozygote patterns, in heterozygotes. The technique used in this survey, polyacrylamide gel electrophoresis (PAGE) autoradiography of plasma and serum labeled in vitro with 57Co-vitamin B12 is particularly applicable to the study of trace proteins such as the transcobalamins (10(-9)M). Possible functional variation in the TC II allele products is described, and the selective significance of this worldwide polymorphism is considered.     

Variants of the group-specific component system as demonstrated by immunofixation electrophoresis. Report of a new variant, Gc Boston (Ge B).

Immunofixation electrophoresis is a relatively simple and reliable method for the genetic phenotyping of the group-specific component (Gc) of serum. This method permits direct comparison of electrophoretic mobilities and band concentrations, with no interference by other proteins. The variants Gc Ab and Gc Y appear identical by this technique; the Eskimo variant appears to be similar to Gc D but not to Gc Ab as previously reported. Gc Norway, also designated Gc 1C, is electrophoretically cathodal to the slower band of Gc 1 and therefore appears to be a distinct variant. A new variant, Gc Boston, is single banded with mobility between the two bands of Gc 1.     

Genetic polymorphism of the vitamin D binding protein (Gc protein) in pig plasma determined by agarose isoelectrofocusing

Genetic polymorphism of the pig plasma vitamin D binding protein Gc was demonstrated by agarose isoelectrofocusing followed by either autoradiography or immunofixation with specific human Gc antiserum. Three different types F, FS and S were observed. Family data supported the genetic theory that the Gc types are controlled by two autosomal codominant alleles GcF and GcS. Both alleles are present in Yorkshire and Duroc. In Danish Landrace and Hampshire only the GcF allele was observed.     

Genetic polymorphism of the vitamin D binding protein (Gc protein) in pig plasma determined by agarose isoelectrofocusing

Genetic polymorphism of the pig plasma vitamin D binding protein Gc was demonstrated by agarose isoelectrofocusing followed by either autoradiography or immunofixation with specific human Gc antiserum. Three different types F, FS and S were observed. Family data supported the genetic theory that the Gc types are controlled by two autosomal codominant alleles Gc^F and Gc^s . Both alleles are present in Yorkshire and Duroc. In Danish Landrace and Hampshire only the Gc^F allele was observed.     

VDBP,CYP27B1, and 25-Hydroxyvitamin D Gene Polymorphism Analyses in a Group of Sicilian Multiple Sclerosis Patients

Multiple sclerosis (MS) is a chronic demyelinating disease of central nervous system regarded as one of the most common causes of neurological disability in young adults. The exact etiology of MS is not yet known, although epidemiological data indicate that both genetic susceptibility and environmental exposure are involved. A poor vitamin D status has been proposed as the most attractive environmental factor. Several evidence have highlighted the importance of mutations in vitamin D-regulating genes for vitamin D status. The purpose of our study was to assess the genetic variants of VDBP and CYP27B1 in MS patients and in a control group. A total of 192 subjects, including 100 MS patients and 92 healthy controls, were genotyped by polymerase chain reaction followed by restriction fragment length polymorphism analyses. Serum 25-hydroxyvitamin D levels were measured in MS patients and controls by high-performance liquid chromatography. We did not observe any statically significant difference in the distribution of genotypic VDBP variants between the study groups. 25(OH)D plasma levels were significantly higher in the control group versus MS patients; MS patients who carried Gc2 showed lower 25(OH)D plasma levels and those who carried Gc1f showed higher levels. We observed only wild-type allele for CYP27B1 mutations analyzed both in MS patients and in the control group. In conclusion, our findings do not support a role of an independent effect of the investigated vitamin D-related gene variants, VDBP and CYP27B1, in the risk of MS.     

The vitamin D binding of the common and rare variants of the group-specific component (Gc)

Summary The vitamin D₃ binding properties of the common and rare Gc variants were examined. Vitamin D₃ labeled with ¹⁴C was added to serum. Gc phenotypes were demonstrated autoradiographically following separation by immunofixation electrophoresis on agarose. This qualitative analysis did not reveal differences in vitamin D₃ binding by the group-specific components of the common types Gc1-1, Gc 2-1, and Gc2-2. The double-band variants Gc Darmstadt, Gc Y/Ab, Gc Toulouse, Gc Norway, and Gc Caucasian were examined; the phenotypes Gc Ab-Ab, Gc Ab-1, Gc Ab-2, Gc T-1, Gc T-2, Gc Norw-2, and Gc 1-Cau showed normal D₃ binding. The double bands of Gc Darmstadt in the phenotype D-2 appeared somewhat weak. The singleband mutants Gc Wien, Gc Chippewa, Gc Opava, and Gc Z were analyzed; the phenotypes Gc W-1, Gc W-2, Gc Chip-1, Gc Chip-2, Gc 1-Op, Gc Op-2, Gc 1-Z, and Gc 2-Z showed normal D₃ binding. A mutant in the Gc system with clearly defective vitamin D₃ binding properties remains to be delineated.     

A monoclonal antibody against human vitamin-D-binding protein for the analysis of genetic variation in the group-specific component system (Gc)

Summary We have developed a murine hybridoma cell line that is stable in secreting a monoclonal antibody (hDBP-1) directed against the group-specific component (Gc) molecule. The hDBP-1 is monospecific for Gc and does not crossreact with human albumin, which has 23% of its amino acid residues identical with vitamin-D-binding protein (DBP). The subclass of the antibody is IgG1 for the heavy chain, the light chain being of the kappa type. Isoelectric focusing discloses four major bands for the hDBP-1 with isoelectric points between pH 6.5 and 7.8. Binding to the antigen at different pH values was determined: there is high affinity in the physiological range and no binding at pH 3.5 and lower. In the presence of high salt concentrations, binding was reduced to about 50% at 1.5 M NaCl. The hDBP-1 recognizes the common human Gc types and the Gc of all apes and old world monkeys. No reaction was observed with the Gc of other mammals such as horses, cattle, rats, rabbits, sheep, goats and pigs. By testing hDBP-1 against 77 of the more than 120 known rare human Gc variants, it could be shown that this monoclonal antibody cannot recognize seven of these rare variants and can only poorly recognize nine. The binding site of hDBP-1 to Gc is not related to the binding site of Gc with G-actin: it recognizes Gc, the binary complex between Gc and G-actin, as well as the ternary complex between Gc, G-actin and DNase I. Competition assays with vitamin D₃ and Gc in enzyme-linked immunosorbent assay indicate that the epitope of hDBP-1 on the Gc molecule may be related to the vitamin-D₃-binding site.     

Heritability of quantitative variation at the group-specific component (Gc) locus

Human group-specific component (Gc) is the plasma transport protein for vitamin D; in addition, polymorphic electrophoretic variants of Gc are found in all human populations. Because of its physiologic importance and in view of the extensive genetic variation at the Gc locus, we have determined the heritability of quantitative variation in Gc by comparing a series of monozygotic (MZ) and dizygotic (DZ) twins of known Gc genotype. The series included 31 MZ twin pairs, 13 DZ twin pairs, and 45 unrelated controls. Since Gc concentration is increased by estrogens, pregnant women and women taking oral contraceptives were excluded. We found no age-related differences in Gc concentration or differences between males and females, but the concentrations of Gc in the three electrophoretically determined genotypes were significantly different from each other. Using classical methods of heritability analysis, the overall heritability of variation in Gc concentration is approximately 70%. Heritability in males is greater than in females, probably reflecting the additional environmental effect of estrogens in women. To determine if the differences in Gc concentration between the three genotypes explain the high heritability, a new variance decomposition procedure was developed following classical methods in quantitative genetics. Application of this method suggests that 19% of the total variation in Gc concentration, combining both sexes, is due to electrophoretic differences between individuals (30% in females and 20% in males). Thus, the genetic component of variation in Gc concentration can be decomposed into a major gene component--the result of electrophoretic variation at the structural locus--and a second, unexplained, polygenic component.     

Genetic polymorphism of the vitamin D binding protein and another post-albumin protein in horse serum.

Horizontal polyacrylamide gel electrophoreses, on 10% separation gel, of horse serum revealed polymorphism of the vitamin D binding protein (Gc protein) and another post-albumin protein (Pa). Family data supported the hypothesis that Gc and Pa types were controlled by autosomal codominant alleles. For both Gc and Pa proteins, the homozygous types showed a single fraction while the heterozygous type had two fractions. Pa types were found to be identical to the post-albumin types reported earlier by starch gel electrophoresis. Two Gc alleles, GcF and GcS, and three Pa alleles, Pa D, Pa F and Pa S, were observed in samples from Swedish (four breeds), Lipizzaner and Arab horses. The frequency of the more common allele at the two loci, i.e. GcF and PaF, ranged from 0.72-0.93 and from 0.58-0.99, respectively, in the different breeds studied. Plasma samples showed an extra protein fraction near the GcS fraction and thus were found unsuitable for Gc typing.     

Genetic polymorphism of the vitamin D binding protein and another post-albumin protein in horse serum

Horizontal polyacrylamide gel electrophoresis, on 10% separation gel, of horse serum revealed polymorphism of the vitamin D binding protein (Gc protein) and another post-albumin protein (Pa). Family data supported the hypothesis that Gc and Pa types were controlled by autosomal codominant alleles. For both Gc and Pa proteins, the homozygous types showed a single fraction while the heterozygous type had two fractions. Pa types were found to be identical to the post-albumin types reported earlier by starch gel electrophoresis. Two Gc alleles, Gc F and Gc S , and three Pa alleles, Pa D, Pa F and Pa S , were observed in samples from Swedish (four breeds), Lipizzaner and Arab horses. The frequency of the more common allele at the two loci, i.e. Gc F and Pa F , ranged from 0.72–0.93 and from 0.58–0.99, respectively, in the different breeds studied. Plasma samples showed an extra protein fraction near the Gc S fraction and thus were found unsuitable for Gc typing.     

Evolutionary and structural relationships among the group-specific component, albumin and alpha-fetoprotein.

The group-specific component (Gc) is a plasma protein that binds vitamin D. Recent characterization of human Gc cDNA demonstrated homology with serum albumin and alpha-fetoprotein. This study compares the sequences of the three proteins and demonstrates a strong evolutionary relationship. Albumin, alpha-fetoprotein and Gc evolved from an ancestral gene containing an intragenic triplication. Comparison of the amino acid sequences and patterns of double disulfide bonds suggests that the Gc gene may have diverged from an ancestral gene earlier in evolution than the genes encoding albumin and alpha-fetoprotein. Analysis of the amino acid and nucleotide sequences of the three internal domains of Gc revealed 19-23% amino acid sequence identity and the localization of three homology blocks with 40-44% nucleotide sequence identity. The deduced amino sequence of Gc furnished data for comparing its molecular configuration based on the predicted secondary structure with those predicted for human albumin and alpha-fetoprotein. Utilization of Gc cDNA has also led to the identification of its genomic DNA and detection of a human DNA polymorphism.     

A new hereditary single band variant of the Gc system

Summary A new single band variant (Gc Ar) or the Gc subtypes not identical with the known Gc variants has been detected in the plasma of a healthy blood donor by isoelectric focusing. Using this technique the variant is represented by a single band which has a similar isoelectric point to the Gc 1C2 anodal band. It is well known that the single band Gc phenotypes remain unaltered after neuraminidase treatment. Nevertheless, the new single band variant (Gc Ar) is altered after neuraminidase treatment as is Gc 2A3. After neuraminidase treatment, the Gc Ar band is affected and moved to the nearby position of the Gc 2 band. Investigation of the proband's family shows that the variant occurs combined with the common alleles Gc 1F, Gc 1S and that it has an autosomal dominant inheritance.     

Gc revisited: Six further Gc-phenotypes delineated by isoelectric focusing and by polyacrylamide gel electrophoresis

Summary Six newly observed Gc variants are described. The variants Gc 1A10, 1A11, 1A12, 1A13, and 1C11 have double band patterns. The anodal bands of these variants are susceptible to neuraminidase treatment. Gc 2A7 is a single band variant which is not altered by neuraminidase incubation. Polyacrylamide gel isoelectrofocusing with immunofixation and polyarcylamide gel electrophoresis appear to be efficient methods for the analysis of the Gc system.     

The amino acid sequence of the NH2-terminal portion of rat and human vitamin D binding protein: evidence for a high degree of homology between rat and human vitamin D binding protein

We determined the amino terminal sequence of rat and human vitamin D binding protein (VDBP). The sequences of the two proteins are: Rat VDBP: LeuGluArgGlyArgAspTyrGluLysAspLysValCysGlnGluLeuSerThrLeuGlyLys Human VDBP: LeuGluArgGlyArgAspTyrGluLysAsnLysValCysLysGluPheSerHisLeuGlyLys AspAspPhe GluAspPhe There are 19 matches out of a total of 24 residues sequenced giving a percent match/length of 79.2%. Differences in the composition of the two proteins at residue 10, 14, 16, and 22 can be accounted for by single base changes in the the gene for the proteins. The difference (Thr----His) at residue 18 requires a change in two bases in the respective genes. We conclude that the sequence of the amino terminus of rat and human VDBP is similar with a high degree of homology between the two proteins. Vitamin D sterols, such as 25-hydroxyvitamin D3, 24,25-dihydroxyvitamin D3, and 25,26-dihydroxyvitamin D3, are bound with high affinity by a plasma alpha-globulin - VDBP, also known as group-specific component (Gc). Other vitamin D sterols, such as 1,25-dihydroxyvitamin D3 and vitamin D3 itself, are bound to this protein with a lesser affinity. VDBP also binds actin with high affinity. Its role in vitamin D physiology is unclear, although it may play a role in the bioavailability of different D sterols. Svasti et al. have shown that human group specific component (Gc) exists as different isoforms that have rapid or slow mobility on gel electrophoresis. The different human Gc isoforms have similar NH2-terminal and COOH-terminal amino acid sequences. The difference in the mobility of the various isoforms is due to post-translational modification of the protein by various carbohydrate residues; treatment of the protein with neuraminidase results in the conversion of the different isoforms to a single isoform. The amino acid sequence of the amino terminus of rat VDBP is not known. Recently, Cooke reported preliminary data from the analysis of cDNA clones showing that rat and human VDBP are partially homologous and that rat and human VDBP exhibit homology with rat and human albumin and alpha-fetoprotein. The NH2-terminal sequence of the rat VDBP, however, has not been reported. In order to learn more about the nature of the NH2-terminal sequence of human and rat VDBP, we isolated these proteins in relatively pure form and determined the NH2-terminal amino acid sequence of both of them.(ABSTRACT TRUNCATED AT 400 WORDS)     

Unusual sialilation of three different rare genetic variants of serum DBP: Gc 1A17, Gc 1A16, and Gc 1A11

Summary The proteins of three anodal Gc1 variants, Gc 1A16, 1A11, and 1A17, are characterized by the most acidic isoelectric points observed so far among the different Gc mutants. Stepwise removal of N-acetylneuraminic acid (NANA) by treatment with neuraminidase was performed to estimate the degree of sialilation of these Gc variants. The results indicate that both proteins, the anodal and the cathodal component of these Gc 1 mutants, carry sialic acid residues. This observation is remarkable in so far as usually only the anodal component of the Gc 1 protein contains NANA and only a single residue. From the experiments carried out it can be deduced that Gc 1A16 has two NANA residues in the anodal and one NANA residue in the cathodal component. Gc 1A16 was found in four members of three generations in a Danish family; the variant segregated as a Mendelian trait. More difficult to interprete are the results obtained with the variants Gc 1A11 and Gc 1A17. Gc 1A11 probably has three NANA residues in the anodal and two NANA residues in the cathodal component. Gc 1A11 has been observed in two mother-child pairs and is presumably also a simple genetic trait. Gc 1A17 has also several NANA residues in both Gc proteins; it is suggested that the anodal component has either three or four NANA residues and the cathodal component either two or three NANA residues. Family information on this variant is not yet available.     

Group-specific component (vitamin D binding protein) prevents the interaction between G-actin and profilin

Profilin purified from human platelets formed a 1:1 molar ratio complex with rabbit skeletal muscle G-actin but was displaced by purified serum Gc (vitamin D binding protein) in a dose-dependent fashion as assessed by chromatography and ultrafiltration. This suggested that Gc and profilin competed for the same binding area on G-actin, with Gc-G-actin complexes being more stable than profilin-G-actin complexes in vitro. The binding domain for Gc on G-actin was localized to a 16,000-Da C-terminal fragment of G-actin generated by Staphylococcus aureus V8 protease, as judged by comigration on two-dimensional electrophoresis and also by overlaying electrophoresis gels with 125I-Gc. Previous studies have reported that residues 374 and 375 of G-actin are essential for binding of profilin. In this study, experiments involving tryptic removal of Cys-374 labeled with the fluorescent probe N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)-ethylenediamine showed that these C-terminal amino acids were not necessary for interaction with Gc.