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.     

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.     

Genetic polymorphism of horse serum protein 3 (SP3)

Two-dimensional agarose gel (pH 8.6)-horizontal polyacrylamide gel (pH 9.0) electrophoresis of horse serum samples, followed by general protein staining, revealed genetic polymorphism of an unidentified protein tentatively designated serum protein 3 (SP3). The SP3 fractions appeared distinctly when a 14% concentration of acrylamide was used in the separation gels. The 2-D mobilities of SP3 fractions were quite similar to that of albumin. Family data were consistent with the hypothesis that the observed SP3 phenotypes were controlled by four co-dominant, autosomal alleles (D, F, I, S). Evidence was provided that the F allele can be further divided into two alleles (F1 and F2); the mobilities of F1 and F2 variants were very similar. Each of the SP3 alleles gave rise to one fraction and each of the heterozygous types showed two fractions. More than 600 horses representing five different breeds (Swedish Trotter, North-Swedish Trotter, Thoroughbred, Arab and Polish Tarpan) were typed for SP3, and allele frequency estimates were calculated. SP3 was highly polymorphic in all breeds studied.     

Genetic polymorphism of horse serum protein 3 (SP3)

Summary. Two-dimensional agarose gel (pH 8.6)-horizontal polyacrylamide gel (pH 9.0) electrophoresis of horse serum samples, followed by general protein staining, revealed genetic polymorphism of an unidentified protein tentatively designated serum protein 3 (SP3). The SP3 fractions appeared distinctly when a 14% concentration of acrylamide was used in the separation gels. The 2-D mobilities of SP3 fractions were quite similar to that of albumin. Family data were consistent with the hypothesis that the observed SP3 phenotypes were controlled by four co-dominant, autosomal alleles ( D,F,I,S ). Evidence was provided that the F allele can be further divided into two alleles ( F ₁ and F ₂); the mobilities of F₁ and F₂ variants were very similar. Each of the SP3 alleles gave rise to one fraction and each of the heterozygous types showed two fractions. More than 600 horses representing five different breeds (Swedish Trotter, North-Swedish Trotter, Thoroughbred, Arab and Polish Tarpan) were typed for SP3, and allele frequency estimates were calculated. SP3 was highly polymorphic in all breeds studied.     

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 (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.     

Stabilization of the structure of horse plasma vitamin D binding protein by disulfide bonds.

Vitamin D binding protein (DBP) was isolated from horse plasma in a four-step procedure that involved Affi-Gel Blue affinity chromatography, gel filtration, hydroxylapatite chromatography, and anion exchange high-pressure liquid chromatography. The yield of DBP from 80 mL of plasma was 6-7 mg. Horse plasma DBP closely resembles other plasma DBPs, being a tryptophan-free protein of Mr 53,000. It is able to bind to and block the polymerization of monomeric actin. The secondary structure of DBP was calculated from circular dichroism measurements to be 39% alpha-helix, 42% beta-sheet, and 19% random coil. Circular dichroism and fluorescence studies revealed that the disulfide bonds of DBP contribute substantial structural stabilization to the molecule with respect to thermal denaturation. The thermal stability of DBP can be used to advantage. Incorporation of a brief treatment at 70 degrees C into the preparative scheme enables omission of one chromatographic step, without detectable alteration of the purified product.     

Genetic polymorphism of plasminogen and vitamin D binding protein in red deer (Cervus elaphus L.)

Genetic polymorphism was detected in the red deer (Cervus elaphus L.), plasma proteins, plasminogen (PLG) and vitamin D binding protein (GC) using antiserum to human proteins. The affinity of the antisera to deer plasma was less than 10% that of a human standard but they bound specifically to proteins of molecular weight expected for GC and PLG. Three codominant alleles of GC and five of PLG were observed. In a set 124 farmed deer calves and their parents, six calves had genotypes which were not consistent with the expectations of inheritance. Further inconsistencies were found when variation in isocitrate dehydrogenase (IDH) and transferrin (TRF) was examined. Using genetic models which included pedigree error parameters the data were shown to be consistent with genetic inheritance of all loci in a data set containing approximately 4.8% (SE 1.4%) parent-progeny pedigree mismatches. In samples from four deer populations representative of the red deer introduced to New Zealand the GC and PLG polymorphisms provided a probability of paternity exclusion (PE) of between 0.34 and 0.54 and when IDH and TRF were also included the PE was between 0.46 and 0.66. The four populations differed significantly in allele frequency, which supports historical evidence that they originate from separate introductions of small numbers of European red deer.     

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.     

Genetic polymorphism of serum vitamin D-binding protein (GC) in sheep and mouflon

One-dimensional polyacrylamide gel electrophoresis (1D PAGE) followed by immunoblotting revealed genetic polymorphism of GC protein in sheep (variants F, S, V) and mouflon (variants F and S, apparently identical to F and S of sheep). The frequency of Gcs allele ranged from 0.84 to 1.0 in the 12 breeds of sheep studied. GcV allele was observed only in Tsigai breed with a frequency of 0.017.     

Uptake and degradation of vitamin D binding protein and vitamin D binding protein-actin complex in vivo in the rat.

We have labelled the rat vitamin D binding protein (DBP), DBP-actin and rat albumin with 125I-tyramine-cellobiose (125I-TC). In contrast with traditional 125I-labelling techniques where degraded radioactive metabolites are released into plasma, the 125I-TC moiety is trapped intracellularly in the tissues, where the degradation of the labelled proteins takes place. By using this labelling method, the catabolism of proteins can be studied in vivo. In this study we have used this labelling technique to compare the tissue uptake and degradation of DBP, DBP-actin and albumin in the rat. DBP-actin was cleared from plasma at a considerably faster rate than DBP. After intravenous injection of labelled DBP-actin complex, 48% of the radioactive dose was recovered in the liver after 30 min, compared with 14% when labelled DBP was administered. Only small amounts of DBP-actin complex were recovered in the kidneys. In contrast with the results obtained with DBP-actin complex, liver and kidneys contributed about equally in the uptake and degradation of DBP determined 24 h after the injection. When labelled DBP was compared with labelled albumin, the amount of radioactivity taken up by the liver and kidneys by 24 h after the injection was 2 and 5 times higher respectively. In conclusion, liver and kidneys are the major organs for catabolism of DBP in the rat. Furthermore, binding of actin to DBP enhances the clearance of DBP from circulation as well as its uptake by the liver.     

Determination of the affinity of vitamin D metabolites to serum vitamin D binding protein using assay employing lipid-coated polystyrene beads.

We have developed an assay to measure the affinity of serum vitamin D binding protein for 25-hydroxyvitamin D3, 1,25-dihydroxyvitamin D3, and vitamin D3, using uniform diameter (6.4 microns) polystyrene beads coated with phosphatidylcholine and vitamin D metabolites as the vitamin D donor. The lipid metabolite coated beads have a solid core, and thus all of the vitamin D metabolites are on the bead surface from which transfer to protein occurs. After incubating these beads in neutral buffer for 3 h, essentially no 3H-labeled vitamin D metabolites desorb from this surface. Phosphatidylcholine/vitamin D metabolite-coated beads (1 microM vitamin D metabolite) were incubated with varying concentrations of serum vitamin D binding protein under conditions in which the bead surfaces were saturated with protein, but most of the protein was free in solution. After incubation, beads were rapidly centrifuged without disturbing the equilibrium of binding and vitamin D metabolite bound to sDBP in solution was assayed in the supernatant. All three vitamin D metabolites became bound to serum vitamin D binding protein, and after 10 min of incubation the transfer of the metabolites to serum vitamin D binding protein was time independent. The transfer followed a Langmuir isotherm, and the Kd for each metabolite binding to serum vitamin D binding protein was derived by nonlinear least-squares fit analysis. From this analysis the following values for the Kd were obtained: 5.59 x 10(-6) M, 25-hydroxyvitamin D; 9.45 x 10(-6) M, 1,25-dihydroxyvitamin D; and 9.17 x 10(-5) M, vitamin D. In conclusion, we have developed a method which avoids problems encountered in previous assays and allows the precise and convenient determination of binding affinities of vitamin D metabolites and serum vitamin D binding protein.     

Polymorphism of 14C vitamin D3 binding protein in cattle and water buffalo serum.

Cattle and water buffalo sera labelled with vitamin D3[14C] (300 and 480 individual samples respectively) were subjected to starch gel electrophoresis followed by autoradiography in an attempt to identify a possible polymorphism of the proteins capable of binding this vitamin. Three phenotypes controlled by two codominant autosomal alleles were identified in cattle while in water buffalo six phenotypes controlled by three codominant autosomal alleles were observed.     

Genetic polymorphism and close linkage of two alpha 1-protease inhibitors in horse serum.

Two-dimensional electrophoretic analysis of horse serum proteins was done by a first-dimension separation in agarose gel (pH 5.4) followed by a second-dimension separation in horizontal polyacrylamide gel (pH 9.0). This method resulted in improved and reproducible separation of many alpha-globulins. Two groups of alpha 1-globulins, designated Pi1 and Pi2, were found to be protease inhibitors. Preliminary studies indicated that Pi1 and Pi2 proteins differed from each other in molecular weight and in protease inhibiting spectra. Extensive polymorphism was observed for both these proteins. Family data supported the hypothesis that Pi1 and Pi2 types were controlled by autosomal codominant alleles. For both Pi1 and Pi2 systems, most of the homozygous types showed two fractions each while the heterozygous types had 4 fractions. Six Pi1 and five Pi2 alleles were observed in two breeds of Swedish horses. Complete genetic linkage was observed for Pi1 and Pi2 loci as no recombinant type was observed in 40 informative matings studied.     

Immunoperoxidase localization of vitamin D dependent calcium binding protein.

Calcium binding protein (CaBP) was localized by the indirect peroxidase-labeled antibody method in chick duodenum 72 hr after administering 32.5 nmol of cholecalciferol to vitamin D-deficient chicks. CaBP was observed in cytoplasm and nuclei of absorptive cells but was absent from goblet cells. Our results are consistent with the suggested functional role for CaBP in the prevention of intracellular accumulation of calcium by preventing mitochondrial accumulation of calcium, enhancing removal of calcium from absorptive cells, and/or preventing the "leaking" of calcium into cells through the lateral borders. They are not consistent with an extracellular functional role for CaBP.