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.     

Equine markers genes. Polymorphism for group-specific component (Gc).

Polymorphism of equine Gc protein was demonstrated by immunofixation electrophoresis with a goat anti-human Gc antibody. Three different phenotypes, F, FS and S, were found. Family data supported the genetic theory of two autosomal codominant alleles, GcF and GcS. Both alleles occurred in Standardbred, Thoroughbred and Arabian horses and in Shetland ponies. A frequency of 0.23 for GcS in the American Standardbred horse indicates the system should be useful for problems of identification and parentage.     

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.     

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.     

Population distribution of the human vitamin D binding protein: anthropological considerations

The polymorphism of the serum vitamin D binding protein (DBP) in humans is based on the existence of three common alleles, Gc1F, Gc1S, and Gc2, and 84 rare alleles. The geographical distribution of Gc1F, Gc1S, and Gc2 alleles shows north to south clines, together with a balanced equilibrium between the Gc1F or Gc1S allele frequency and the Gc2 frequency. The distribution of the FST values shows high variability within a geographical area. For European and North Asiatic groups, the FST values are the lowest observed, and the reason may be a long process of homogenization. Aboriginal populations from Australia and New Guinea and groups from both North Africa and South America show the greatest heterogeneity of their allele frequencies. Systematic factors such as genetic drift and selection may account for this distribution. In contrast with the three main DBP alleles, the distribution of the rare alleles corresponds to patterns of human migrations that occurred during prehistoric and historic periods. Thus, the rare mutants are of particular relevance to anthropological and genetical investigations.     

Genetic polymorphism of group-specific component/vitamin-D-binding protein subtypes in six populations from north-eastern China

On six populations from North-Eastern China the frequencies of Gc subtypes were studied by isoelectric focusing on ultra-thin polyacrylamidegel followed by the improved sulfosalicylic acid precipitation. The following Gc subtype allele frequencies could be observed in the Han (Harbin), Ewenki, Tahur, Mongolian, Oroquen and Xibe populations: Gc*1F = 0.4246, 0.4941, 0.4479, 0.4077, 0.4606 and 0.4503; Gc*1S = 0.2587, 0.2936, 0.3151, 0.2822, 0.3370 and 0.3035; Gc*2 = 0.3065, 0.2064, 0.2266, 0.3006, 0.2022 and 0.2388. In addition to this 16 individuals of five populations showed rare Gc variant alleles (1A3, 1A8, 1A9, 1A14, 1C?).     

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.     

Genetic polymorphism of the vitamin D binding protein (Gc) in the musk shrew (Suncus murinus)

In the musk shrew ( Suncus murinus ), the electrophoretic bands in the post-albumin region were identified as vitamin D binding protein (Gc) by the [³HI vitamin D₃ binding method. Three Gc phenotypes were distinguished from each other: a single faster band (Gc-A), a single slower band (Gc-B) and the double bands (Gc-AB). Results of mating experiments indicated that the Gc-A and Gc-B are controlled by two codominant alleles, Cc ^a and Gc ^b at an autosomal locus ( Cc ), respectively. It was noticed that, in the Gc-AB phenotypes, the Gc-B band was constantly more intense than the Gc-A band in the protein staining. The same tendency was also observed btween the homozygous Gc-A and Gc-B bands, and further, radioactivity of the Gc-B bound with [³H] vitamin D₃ was about twofold higher than that of the Gc-A. These results suggest that the Gc^b yields its protein product twofold more than the Gc ^a. No cross-reaction between the shrew proteins and a rabbit anti-human Gc protein was observed.     

Gc subtyping in south Indian tribal and caste populations

Seven tribal (Konda Kammara - 2 samples; Koya Dora - 3 samples; Lambadi) and caste (Madiga) populations from Andhra Pradesh (South India) have been analyzed for the distribution of Gc subtypes. The observed heterogeneity in the distribution of Gc1F, Gc1S and Gc2 alleles was found to be statistically significant. Comparisons are made with North Indian populations as well as with those of other racial affiliation. The anthropological impact of the Gc subtype polymorphism is discussed.     

Gc subtypes in Northern Indians

Isoelectric focusing was used to determine the frequencies of the Gc subtypes in a population sample from The North Indian subcontinent (now living in Birmingham, UK). The gene frequencies observed were as follows: Gc1F = 0.191, Gc1S = 0.519 and Gc2 = 0.290.243 individuals were typed and no variant alleles were detected.     

On the variability of Gc subtypes in Italy

909 individuals from different places of Italy were analyzed for the distribution of Gc subtypes. The observed heterogeneity in the distribution of the allele frequencies was found to be statistically significant. Comparing our results with those reported by other authors it is seen that within Italy a considerable regional variation in the frequencies of the Gc subtype alleles is present. However, there are no indications for any particular distribution patterns or gradients. In one of our samples (Bari district), one case of Gc 1S-1C3 was found.     

Hereditary recombined three-allele variant of the Gc system

A three-allele variant with Gc 2, Gc 1F and Gc 1A2 alleles was detected in both a baby and his mother during paternity testing by isoelectric focusing. His father had a normal Gc phenotype, Gc 2-1F. Further examination of his mother's relatives revealed that his grandfather also had the same three-allele variant, while his grandmother and his aunt had normal Gc 2-1F and Gc 2-2. From these results, it was considered that the Gc 1F and Gc 1A2 alleles were on the same single chromosome. It was suggested that recombination had occurred between two chromosomes that had the Gc 1F and Gc 1A2 allele, respectively, forming the variant allele Gc 1F1A2 on a single chromosome.     

The distribution of the group specific component (Gc) in four endogamous groups of Punjab, North India

The paper reports the distribution of group specific component (Gc) types among four endogamous groups of Punjab: Jat Sikh, Khatri, Ramgarhia, and Ramdasia. A total of 418 individuals were tested for this polymorphism. The frequency of Gc1 alleles ranges between 0.7056 and 0.7636. These frequencies are compared with those obtained in other Indian populations.     

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.     

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.     

Study of five haemogenetic markers (Gc, C3, Bf, Ag, and GALT) in six Indonesian populations and in 12 subgroups of Balinese

In various ethnic groups of the Indonesian archipelago and of Bali, the polymorphisms of the serum proteins Gc globulin (vitamin D-binding protein), C3 (complement component 3), Bf (complement factor B), Ag x,y (lipoprotein allotypes), and of the red cell enzyme system GALT (galactose-1P-uridyltransferase) were analysed. Among the studied proteins, the Gc system was the most informative one for the anthropologist. Besides considerable differences of frequencies of the common alleles Gc*1F, Gc*1S and Gc*2, a number of rare alleles (1A1, 1A3, 1A8, 1A9, 1A12, 1C2, 1C21, 1C24, and 2C8) and some new ones (1C28, 1C29, 1C30, 2C9) were observed. The presence of Gc*1A1 demonstrates the relationship to the Australo-Melanesian populations, but Mongolian variants (1A3, 1A8, 1A9, 1C2) were also encountered. Within the C3 system a very high frequency of the C3*S allele was observed in all populations. The rare alleles C3*F0.55, C3S1, and C3*S0.5 were observed in some groups. A new allele (C3*F0.35) was detected in a Chinese individual and in a nobleman from Bali. The frequency of the Bf*F allele was rather low in general, and the Bf*S0.7 allele was found in three Indonesian individuals only. The Ag*(x) frequencies were rather high, as it is known for Asiatic populations. Variability among subgroups was not very pronounced. The GALT*2 allele (Duarte variant of the enzyme) was observed very rarely; however, it was present in several populations. Enzyme activities could not be determined, and therefore we cannot tell whether the galactosaemia gene (GALT*0) was present or not.     

Gc subtypes identified by isoelectric focusing in Baboons (Papio hamadryas)

Summary Phenotyping for Gc variants by conventional electrophoresis in 835 Papio hamadryas baboons demonstrated a monomorphic population. Gc subtyping by polyacrylamide IEF gels, pH 4–6, on 394 of these baboons revealed the existence of two common alleles which we named Gc _Papio ¹ and Gc _Papio ² . Pedigree data confirmed the inheritance of a single locus, two allele system and the observed gene frequencies were 0.593 for Gc _Papio ¹ and 0.407 for Gc _Papio ² .     

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.     

Distribution of group-specific component/vitamin-D-binding protein subtypes in Saudi Arabia

The distribution of group-specific component (Gc) phenotypes and the Gc allele frequencies were investigated in 1,082 individuals from five different provinces of Saudi Arabia by the combined use of isoelectric focusing and immunofixation. Between provinces variations in the Gc allele frequencies were found. Gc1S decreased and Gc1F increased from the northwest to the southeast in Saudi Arabia. The overall frequencies in Saudi Arabia were 0.236 for Gc1F, 0.610 for Gc1S, 0.150 for Gc2 and 0.004 for rare alleles. The observed frequencies did not differ significantly from those found in other population samples from the Middle East. In nine samples rare Gc variants were found.     

Genetic studies on the Gc subtypes

Summary Gc subtypes were determined by immunofixation isoelectric focusing. In a family study involving 93 families with a total of 176 children, a three-allele model with six genotypes was confirmed. The distribution of Gc subtypes was studied in three populations from Europe and in a sample of Druzes from Northern Israel. Three new variant Gc types were observed.