Porcine serum cobalophilin and transcobalamin. Identification, isolation and properties including electrofocusing patterns

Pooled porcine serum was found to contain cobalophilin (also called transcobalamin I) and transcobalamin (also called transcobalamin II). The two proteins were harvested by batchwise absorption with vitamin B-12 covalently coupled to Sepharose, and then separated from each other either by gel filtration or using an immunoadsorbent. Both proteins were finally isolated as single proteins using a second vitamin B-12-Sepharose chromatography step. Cobalophilin and transcobalamin complexed with vitamin B-12 had molecular weights by gel filtration of 135 000 and 38 000 and by the formula of Svedberg 104 000 and 44 000, Stokes radii 4.97 nm and 2.65 nm, and sedimentation coefficients 5.39 S and 3.75 S, respectively. Electrofocusing resolved the cobalophilin complex into three main isoproteins isoelectric at pH 3.23, 3.42 and 3.69, and transcobalamin into only the main component isoelectric at a value as low as pH 3.47. Neither protein was capable of binding to the ileal intrinsic factor receptor.     

Isolation of the porcine ileal intrinsic factor receptor by sequential affinity chromatography

An extract containing solubilised receptor was passed through four columns containing Sepharose to which had been covalently coupled anti-cobalophilin IgG, vitamin B-12-intrinsic factor, vitamin B-12, and free intrinsic factor, respectively. Following a wash the receptor was eluted with EDTA, then residual Triton X-100 micelles and vitamin B-12-intrinsic factor were removed by Sephadex G-200 filtration. The receptor was purified 84 000-fold, sodium dodecyl sulphate electrophoresis indicated two subunits and gel filtration of its vitamin B-12-inttrinsic factor complex resolved it into two molecular species.     

Studies on the solubilized porcine ileal intrinsic factor receptor and on a 340 000-dalton component binding vitamin B-12

A 340 000-dalton component “C-III” was found when Triton X-100-containing extracts of ileal mucosa were incubated with human or porcine intrinsic factor vitamin B-12 preparations. It was not formed when abnormal human intrinsic factor, unable to attach to the intrinsic factor receptor, was used. Prolonged storage promoted the transfer of vitamin B-12 to it from the vitamin B-12-intrinsic factor receptor species C-I and C-II. The component was also present in ileal extracts prepared with or without detergent and it bound vitamin B-12 directly. Immunologically and by electrofocusing it could be classified as a cobalophilin but its molecular dimensions were larger than described for cobalophilin. It thus represents a novel vitamin B-12 binding protein, possibly a macromolecular acceptor of vitamin B-12 which accepts vitamin B-12 bound via intrinsic factor to the ileal intrinsic factor receptor.In the presence of EDTA or at low pH, vitamin B-12-intrinsic factor did not bind to any of the receptor species and under the same conditions it could all be dissociated from the receptor complexes but not from C-III. The dissociated receptor was able to recombine with vitamin B-12-intrinsic factor and it appeared to bind free and vitamin B-12-bound intrinsic factor in vivo.     

Solubilised intrinsic factor receptor from pig ileum and its characteristics.

The vitamin B-12-intrinsic factor receptor was shown to be present in pig ileum and localized on the brush borders of the enterocytes, and to be solubilisable with Triton X-100. At neutral pH and in the presence of Ca2+ it bound the vitamin B-12-intrinsic factor but not the vitamin B-12-cobalophilin complex. The solubilised vitamin B-12-intrinsic factor-receptor complex consisted of two molecular species with clear Stokes radii (13.11 and 33.53 nm), sedimentation coefficients (15.1 and 45.1 S) and molecular weights (1 600 000 and 12 000 000). A third smaller macromolecule possibly also represented the receptor. Some receptor activity was present in extracts prepared with buffers lacking detergent. There was evidence that the receptor is a membrane lipoprotein from which the lipids reversibly dissociate. Free intrinsic factor also bound to the solubilized receptor and its vitamin B-12-binding site seemed not to be involved in the attachment to the receptor. A small portion of the vitamin B-12-intrinsic factor spontaneously dissociated from the receptor and nearly all dissociated in the presence of Na2-EDTA. TheStokes radius of the dissociated vitamin B-12-intrinsic factor complex was 0.17 nm smaller than before binding to the receptor. Intrinsic factor and cobalophilin were present in ileal extract and observations were made on their molecular characteristics. These proteins, polymers of the vitamin B-12-intrinsic factor complex and binding of vitamin B-12 and its protein complexes to detergent micelles may give spurious receptor-like effects which must be properly controlled.     

Solubilised intrinsic factor receptor from pig ileum and its characteristics

The vitamin B-12-intrinsic factor receptor was shown to be present in pig ileum and localized on the brush borders of the enterocytes, and to be solubilisable with Triton X-100. At neutral pH and in the presence of Ca²⁺ it bound the vitamin B-12-intrinsic factor but not the vitamin B-12-cobalophilin complex. The solubilised vitamin B-12-intrinsic factor-receptor complex consisted of two molecular species with clear Stokes radii (13.11 and 33.53 nm), sedimentation coefficients (15.1 and 45.1 S) and molecular weights (1 600 000 and 12 000 000). A third smaller macromolecule possibly also represented the receptor. Some receptor activity was present in extracts prepared with buffers lacking detergent. There was evidence that the receptor is a membrane lipoprotein from which the lipids reversibly dissociate. Free intrinsic factor also bound to the solubilized receptor and its vitamin B-12-binding site seemed not to be involved in the attachment to the receptor. A small portion of the vitamin B-12-intrinsic factor spontaneously dissociated from the receptor and nearly all dissociated in the presence of Na₂-EDTA. The Stokes radius of the dissociated vitamin B-12-intrinsic factor complex was 0.17 nm smaller than before binding to the receptor. Intrinsic factor and cobalophilin were present in ileal extracts and observations were made on their molecular characteristics. These proteins, polymers of the vitamin B-12-intrinsic factor complex and binding of vitamin B-12 and its protein complexes to detergent micelles may give spurious receptor-like effects which must be properly controlled.     

Purification of rat intestinal receptor for intrinsic factor · vitamin B-12 complex by affinity chromatography

Rat intrinsic factor was bound to vitamin B-12-Sepharose to produce intrinsic factor · vitamin B-12-Sepharose. Intestinal receptor for intrinsic factor · vitamin B-12 complex was purified from rat ileal extract by affinity chromatography using the intrinsic factor · vitamin B-12-Sepharose as an affinity adsorbent with recovery of 48.5% and specific activity increased 335 fold of original sample.     

Comparative studies on intrinsic factor and cobalophilin in different parts of the gastrointestinal tract of the pig

The vitamin B₁₂ binders in the pig pyloric mucosa gastric and intestinal juice from the upper gastrointestinal tract were fractionated into only two molecular forms, classified as intrinsic factor and cobalophilin. The unsaturated vitamin B₁₂-binding power due to cobalophilin was lower in the intestinal than in the gastric juice. Electrofocusing revealed that intrinsic factor and cobalophilin in the intestinal juice contained more of the `neutral'-type isoproteins, and the suggestion is made that this is due to enzyme activity. The gastric-juice intrinsic factor contained more acidic isoproteins, which supports the hypothesis that carbohydrate is added on to the polypeptide chain of this protein before it is secreted into gastric juice. The gastric- and intestinal-juice cobalophilins, studied also by electrofocusing, differed from that of pyloric mucosa and they appeared to be of salivary origin. With regard to molecular dimensions there was no significant difference between the intrinsic factors and cobalophilins from all sources studied. All cobalophilins had molecular weights by the formula of Svedberg of approx. 92500, Stokes radii of 4.62nm and sedimentation coefficients of 5.15S. The corresponding values for the intrinsic factors were 63600, 3.57nm and 4.38S. In addition, the intrinsic factors exhibited similar avidities for binding to the solubilized ileal intrinsic-factor receptor. Also the intrinsic factors and cobalophilins, irrespective of their source, bound to the analogous specific xenoantibodies with the same avidity. The present results demonstrate that intrinsic factor remains practically unaltered during its passage through the proximal intestine and render unlikely the speculations made about the presence of an endogenous binder for intrinsic factor as well as the existence of a `pancreatic intrinsic factor'. In addition, they are compatible with the theory that the interference by undegraded cobalophilin may be the reason for the abnormal vitamin B₁₂ absorption observed in patients with pancreatic insufficiency.     

Human plasma R-type vitamin B12-binding proteins. I. Isolation and characterization of transcobalamin I. TRANSCOBALAMIN III. and the normal granulocyte vitamin B12-binding protein.

Transcobalamin I and transcobalamin III have been purified approximately 6,000,000- and 3,000,000-fold, respectively, from normal human plasma using a purification scheme consisting of immunoadsorption, dialysis against 7.5 M guanidine HCl to remove endogenous vitamin B12, and affinity chromatography on vitamin B12-Sepharose. The two proteins were separated from each other subsequently by chromatography on DEAE-cellulose. The vitamin B12-binding protein present in granulocytes obtained from normal subjects has been purified approximately 5000-fold using affinity chromatography on vitamin B12-Sepharose as the sole purification technique. The final preparations of all three proteins were homogeneous based on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Transcobalamin I and transcobalamin III belong to the R-typed class of vitamin B12-binding proteins and are indistinguishable from each other, and from the human granulocyte, milk, and saliva R-type vitamin B12-binding proteins, when studied by immunodiffusion with rabbit anti-human milk vitamin B12-binding protein sera. The carbohydrate compositions, expressed as moles of carbohydrate per mole of vitamin B12, of transcobalamin I, transcobalamin III, and the normal granulocyte vitamin B12-binding protein, respectively, are: sialic acid, 18, 11, 11; fucose, 9, 20, 24; galactose, 41, 51, 46; mannose, 24, 22, 20; galactosamine, 2, 2, 2; and glucosamine, 46, 54, 46. The high sialic acid content of transcobalamin I appears to account for the fact that this protein elutes after transcobalamin III and the normal granulocyte vitamin B12-binding protein during chromatography on DEAE-cellulose. This observation provides support for the hypothesis that differences among the R-type vitamin B12-binding proteins are due to differences in carbohydrate content. The similarities in carbohydrate composition and other properties of transcobalamin III and the granulocyte vitamin B12-binding protein provide support for the hypothesis that human plasma transcobalamin III is derived from granulocytes. The differences observed between transcobalamin I and the normal granulocyte vitamin B12-binding protein suggest that transcobalamin I may not be derived from granulocytes.     

Biosynthesis of transcobalamin II by adult rat liver parenchymal cells in culture.

The biosynthesis of transcobalamin II was investigated in primary cultures of adult rat liver parenchymal cells maintained in serum-free media. The data indicate that these hepatocytes secrete a vitamin B₁₂-binding substance into the culture medium which is identical to rat serum transcobalamin II as judged by the following criteria: (i) gel filtration on columns of Sephadex G-200; (ii) ion-exchange chromatography on columns of diethyl aminoethyl cellulose and carboxymethyl cellulose; (iii) polyacrylamide-gel electrophoresis at pH 9.5; and (iv) the ability to facilitate cellular vitamin B₁₂ uptake by HeLa cells and mouse L-929 fibroblasts in culture. The secretion of transcobalamin II by the liver parenchymal cells was blocked by cycloheximide, puromycin, and p-fluorophenylalanine. The inhibition by cycloheximide, but not that of the other inhibitors, was partially reversed upon removal of the drug. The liver parenchymal cells incorporated radioactive amino acids into transcobalamin II which was absorbed from the growth medium using affinity chromatography on Sepharose containing covalently linked B₁₂. Collectively, these data indicate that rat liver parenchymal cells, in culture, are capable of the biosynthesis de novo of transcobalamin II and the subsequent secretion of this protein into the culture media.     

Effect of the cobalt-N coordination on the cobamide recognition by the human vitamin B12 binding proteins intrinsic factor, transcobalamin and haptocorrin

The binding of several corrinoids to the binding site of human intrinsic factor, transcobalamin or haptocorrin was investigated, p-Cresolyl cobamide and 2-amino-vitamin B12 are complete corrinoids, whose nucleotide at the lower face of the corrin ring is not coordinated to the cobalt. These corrinoids were greater than or equal to 10(3) times less efficiently recognized by intrinsic factor or transcobalamin than vitamin B12, which contains a Co-coordinated nucleotide. Pseudovitamin B12, with a weak Co-N coordination bond, revealed only moderate affinity to intrinsic factor. From these findings it is concluded that the cobamide binding to intrinsic factor and transcobalamin is strongly affected by the Co-N coordination bonds of their lower cobalt nucleotide ligands. We suggest that the Co-N coordination bond positions the nucleotide at a critical distance to the corrin ring, which is recognized by the binding proteins. Human haptocorrin, however, disclosed to distinctive selectivity regarding the different corrinoid structures. The protein bound all corrinoids with similar efficiency, independent of the strength of their Co-N coordinations, or the structures of their lower Co alpha ligands. Hence, the corrin ring, rather than a structural feature induced by the Co-N coordination, has to be considered responsible for the corrinoid binding to haptocorrin.     

Release of vitamin B-12 in vitro from intrinsic factor-vitamin B-12 complex Purification and characterization of a releasing factor from rat ileal brush border

Vitamin B-12 is released from the purified gastric intrinsic factor-[⁵⁷Co]vitamin B-12 (intrinsic factor- [⁵⁷Co]vitamin B-12) complex, when incubated with rat intestinal mucosa. Maximum specific activity for splitting the complex is localized in ileal brush border. Release of [⁵⁷Co]vitamin B-12 is not due to its mere exchange during incubation with endogenous non-radioactive vitamin B-12. The splitting process has specific requirement for Ca²⁺ and ATP and it is thermolabile, time- as well as temperature-dependent. It is also inactivated by the presence of p-chloromercuribenzoate. Further, the vitamin B-12-releasing factor has been isolated from solubilized brush border and is purified 70-fold by (NH₄)₂SO₄ precipitation, gel filtration and Con. A-Sepharose 4B affinity chromatography. In SDS-polyacrylamide gel electrophoresis, it is resolved into a single band of about 25 kDa, indicating its purity. The releasing factor exhibits maximum activity at pH 7.4; isoelectric focusing reveals only one major form with pI 7.52. With intrinsic factor-[⁵⁷Co]vitamin B-12-complex as the substrate, apparent K_m and V_max values obtained are 128.2·10⁻¹² M/1 and 117.6 pg·h⁻¹ 100 μg protein, respectively. Amino acid and carbohydrate analyses reveal the glycoprotein nature of the factor. Intrinsic factor-[⁵⁷Co]vitamin B-12 complex is not susceptible to unspecific proteolytic digestion/ Similarly, the releasing factor does not hydrolyse other proteins. Thus, the observed substrate-specificity of the releasing factor differentiates it from other known proteolytic enzymes of ileal brush borders.     

Identification and characterization of intrinsic factor and cobalophilin from pig ileal and pyloric mucosa

Pig ileal mucosa was found to bind about 240 ng vitamin B₁₂/g and to contain two vitamin B₁₂-binding proteins. One was highly active in the Schilling test, behaved immunologically as intrinsic factor and was responsible for about half of the total vitamin B₁₂-binding capacity. The other binder was identified as cobalophilin (R-protein). Immunochemical purification of these proteins from pig ileum and pylorus was performed and the molecular characteristics (sedimentation and diffusion coefficients, Strokes radii, frictional ratios and molecular weights) of their vitamin B₁₂ complexes were estimated. Isoelectric focusing revealed differences between the ileal and pyloric intrinsic factors but not between the cobalophilins. The mean isoelectric points of the pyloric and ileal intrinsic factors were pH 5.79 and 5.30, respectively, whereas the corresponding figures for the cobalophilins were 4.13 and 4.10.     

Cobalamin transport proteins and their cell-surface receptors

The primary function of cobalamin (Cbl; vitamin B12) is the formation of red blood cells and the maintenance of a healthy nervous system. Before cells can utilise dietary Cbl, the vitamin must undergo cellular transport using two distinct receptor-mediated events. First, dietary Cbl bound to gastric intrinsic factor (IF) is taken up from the apical pole of ileal epithelial cells via a 460 kDa receptor, cubilin, and is transported across the cell bound to another Cbl-binding protein, transcobalamin II (TC II). Second, plasma TC II-Cbl is taken up by cells that need Cbl via the TC II receptor (TC II-R), a 62 kDa protein that is expressed as a functional dimer in cellular plasma membranes. Human Cbl deficiency can develop as a result of acquired or inherited dysfunction in either of these two transmembrane transport events. This review focuses on the biochemical, cellular and molecular aspects of IF and TC II and their cell-surface receptors.     

Structural study on ligand specificity of human vitamin B12 transporters

Studies comparing the binding of genuine cobalamin (vitamin B12) to that of its natural or synthetic analogues have long established increasing ligand specificity in the order haptocorrin, transcobalamin and intrinsic factor, the high-affinity binding proteins involved in cobalamin transport in mammals. In the present study, ligand specificity was investigated from a structural point of view, for which comparative models of intrinsic factor and haptocorrin are produced based on the crystal structure of the homologous transcobalamin and validated by results of published binding assays. Many interactions between cobalamin and its binding site in the interface of the two domains are conserved among the transporters. A structural comparison suggests that the determinant of specificity regarding cobalamin ligands with modified nucleotide moiety resides in the beta-hairpin motif beta3-turn-beta4 of the smaller C-terminal domain. In haptocorrin, it provides hydrophobic contacts to the benzimidazole moiety through the apolar regions of Arg357, Trp359 and Tyr362. Together, these large side chains may compensate for the missing nucleotide upon cobinamide binding. Intrinsic factor possesses only the tryptophan residue and transcobalamin only the tyrosine residue, consistent with their low affinity for cobinamide. Relative affinity constants for other analogues are rationalized similarly by analysis of steric and electrostatic interactions with the three transporters. The structures also indicate that the C-terminal domain is the first site of cobalamin-binding since part of the beta-hairpin motif is trapped between the nucleotide moiety and the N-terminal domain in the final holo-proteins.     

Development of a purification procedure for the placental protein 14 involving metal-chelate affinity chromatography and hydrophobic interaction chromatography

Placental protein 14 was isolated from the biological material of patients undergoing legal abortions. The major part of ballast protein was removed by ion-exchange chromatography on DEAE-Sepharose and CM-Sepharose. Albumin was separated by chromatography on Blue-Sepharose. Complete purification was obtained by metal-chelate affinity chromatography on Nickel-Chelate Sepharose and hydrophobic interaction chromatography on Phenyl-Sepharose and Octyl-Sepharose. The protein was not exposed to denaturing agents or extreme pH.     

Selective vitamin B12 malabsorption in two siblings

Two siblings with megaloblastic anemia responsive to parenteral vitamin B₁₂ were studied to elucidate the cause of the B₁₂ deficiency. Gastric juice from both contained acid and functional intrinsic factor. Serum contained transcobalamin II and lacked antibodies to intrinsic factor. Schilling tests showed vitamin B₁₂ malabsorption uncorrected by hog intrinsic factor or pancreatic extract. Other parameters of small intestinal function were normal. Proteinuria was initially present in both but cleared in one following treatment with B₁₂. These patients with “familial selective vitamin B₁₂ malabsorption” are the first reported from Canada. Only 37 cases have been reported in the world literature to date.     

Purification of methylmalonyl-CoA mutase from Propionibacterium shermanii using affinity chromatography.

A novel procedure for the purification of methylmalonyl-CA mutase from Propionibacterium shermanii has been described which employs affinity chromatography on a column of immobilized vitamin B-12 linked covalently to Sepharose. The method has the advantage of being simple and rapid, thus enabling the purification of the enzyme to near homogeneity with good yields.     

Human plasma R-type vitamin B12-binding proteins. II. The role of transcobalamin I, transcobalamin III, and the normal granulocyte vitamin B12-binding protein in the plasma transport of vitamin B12.

The normal human granulocyte vitamin B12-binding protein, transcobalamin I, and transcobalamin III, have been labeled with 125I-labeled N-succinimidyl 3-(4-hydroxyphenyl)propionate and utilized for plasma clearance studies performed with rabbits. Both moieties of 125I-labeled granulocyte vitamin B12-binding protein-[57Co]vitamin B12 were cleared rapidly from the plasma (is less than 90% by 5 min) by the liver. After 30 min, the bulk of the 125I reappeared in the plasma in small molecular weight (less than 1000) form and was rapidly excreted in the urine. After 60 min the bulk of the [57Co]vitamin B12 reappeared in the plasma bound to rabbit transcobalamin II and was subsequently taken up by a variety of tissues. Approximately 15% of the 125I-labeled granulocyte vitamin B12-binding protein-[57Co-a1vitamin B12 was excreted intact into the bile during the period from 10 to 80 min after injection. The hepatic uptake of the protein-vitamin B12 complex was blocked by the prior injection of desialyzed fetuin but not by native fetuin. Similar results were obtained with 125I-labeled transcobalamin III-[57Co]vitamin B12. Approximately 90% of both moieties of 125I-labeled transcobalamin I-[57Co]vitamin B12 had prolonged plasma survivals similar to that of 125I-labeled bovine serum albumin. After treatment with neuraminadase, both moieties of the 125I-labeled transcobalamin I-[57Co]vitamin B12 complex were cleared rapidly from the plasma by the liver in a manner that was indistinguishable from that observed in the case of untreated granulocyte vitamin B12-binding protein and transcobalamin III. These observations indicate that desialyzed transcobalamin I and the native forms of the granulocyte vitamin B12-binding protein and transcobalamin III are cleared from plasma by the mechanism elucidated by Ashwell and Morell (Ashwell, G., and Morell A. G. (1974) Adv. Enzymol. 41, 99-128) that is capable of clearing a wide variety of asialoglycoproteins. These observations have implications concerning the function of the human R-type vitamin B12-binding proteins, the nature of the enterohepatic circulation of vitamin B12, the biological significance of the mechanism described by Ashwell and Morell, and the etiology of the increased plasma concentration of human R-type protein that occurs frequently in chronic myelogenous leukemia and occasionally in hepatocellular carcinoma and other solid tumors.     

The cDNA sequence and the deduced amino acid sequence of human transcobalamin II show homology with rat intrinsic factor and human transcobalamin I.

The cellular uptake of cobalamin (Cbl, vitamin B12) is mediated by transcobalamin II (TCII), a plasma protein that binds Cbl and is secreted by human umbilical vein endothelial (HUVE) cells. These cells synthesize and secrete TCII and, therefore, served as the source of the complementary DNA (cDNA) library from which the TCII cDNA was isolated. This full-length cDNA consists of 1866 nucleotides that code for a leader peptide of 18 amino acids, a secreted protein of 409 amino acids, a 5'-untranslated segment of 37 nucleotides, and a 3'-untranslated region of 548 nucleotides. A single 1.9-kilobase species of mRNA corresponding to the size of the cDNA was identified by Northern blot analysis of the RNA isolated from HUVE cells. TCII has 20% amino acid homology and greater than 50% nucleotide homology with human transcobalamin I (TCI) and with rat intrinsic factor (R-IF). TCII has no homology with the amino-terminal region of R-IF that has been reported to have significant primary as well as secondary structural homology with the nucleotide-binding domain of NAD-dependent oxidoreductases. The regions of homology that are common to all three proteins are located in seven domains of the amino acid sequence. One or more of these conserved domains is likely to be involved in Cbl binding, a function that is common to all three proteins. However, the difference in the affinity of TCII, TCI, and R-IF for Cbl and Cbl analogues indicates, a priori, that structural differences in the ligand-binding site of these proteins exist and these probably resulted from divergence of a common ancestral gene.     

Structural studies of Fc receptors. III. Isolation and molecular weight analysis of the component chain of Fc gamma receptor of macrophage

Surface receptors of guinea pig peritoneal macrophages specific for the Fc region of IgG (Fc gamma receptor) were isolated and identified as a surface-radioiodinated component with a molecular weight of 44,000 that bound in an Fc-specific manner to IgG2 of guinea pig immunoglobulin immobilized in any of the following three different ways: IgG2 antibody in insoluble immune complex, IgG2 antibody bound to antigen-coupled Sepharose, and IgG2 covalently coupled to Sepharose. In order to obtain the Fc gamma receptor retaining the binding activity, the Fc-binding component was isolated by IgG2 affinity chromatography in which mild acidic buffer (pH 5.0-4.0) was chosen to elute the component bound to the affinity column. Forty-five to sixty-two percent of the eluted radioactivity was shown to rebind to the IgG2-affinity column. The bound fraction showed a single radioactive peak of 44,000 daltons in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The Fc-binding component isolated by the affinity chromatography behaved similarly in gel filtration in the presence of a detergent, as did the detergent-solubilized Fc gamma receptor before isolation by affinity chromatography. These results suggested that the Fc gamma receptor was isolated in a native form. Furthermore, it was confirmed that the isolated Fc gamma receptor is distinct from actin or the actin-like protein (DNase I-binding protein) which had been reported to bind to IgG-affinity column.