Genetic analysis of human lymphocyte proteins by two-dimensional gel electrophoresis

Summary We describe a genetic polymorphism of cytosol polypeptide with mol.wt. of 20,000 detected in lymphocytes the arythrocytes by two-dimensional gel electrophoresis. Three different electrophoretic phenotypes (type 1-1, 2-1, and 2-2) of the polypeptide have been identified in a Japanese population. Family studies indicate that the phenotypes are determined by two common alleles at a single autosomal locus. The polypeptide is present in the cytosol of various kinds of cells and is abundant in erythrocytes. The data on a gel filtration of the erythrocyte cytosol proteins on a Sephadex G-100 column suggest that the polypeptide exists as a dimer in cells. In nine out of 79 individuals, the phenotypes of the polypeptide were different from those of glyoxalase 1 (GLO1) which has similar properties in subunit size, cell distribution, and allele frequencies. These date indicate that the polypeptide with mol. wt. of 20,000 is a new polymorphic cellular polypeptide. We propose that the polypeptide be temporarily designated as cytosol polypeptide with mol. wt. of 20,000 (CP20) and that the gene for CP20 be designated as CP20. The gene frequencies of two common alleles (CP20 ¹ and CP20 ²) are 0.955 and 0.045, respectively, in a Japanese population.     

Genetic analysis of human lymphocyte proteins by two-dimensional gel electrophoresis: 4. Genetic polymorphism of cytosol 100k polypeptide

Summary We describe a genetic polymorphism of a human cellular polypeptide with mol. wt. 100,000, detected in peripheral blood lymphocytes by high resolution two-dimensional electrophoresis. Three different electrophoretic types (1-1, 2-1, and 2-2) of the polypeptide have been identified. Family and population studies indicate that the three phenotypes of the polypeptide are determined by two common alleles at a single autosomal locus. The polypeptide occurs in the cytosol and is one of the abundant polypeptides of B-lymphoblastoid cells, T-lymphoblastoid cells, fibroblasts, and HeLa cells. The data indicate that the cytosol polypeptide with mol.wt. 100,000 shows a genetic polymorphism determined by aew autosomal locus. It is proposed that the polypeptide and its locus be temporarily designated cytosol 100k polypeptide (C100k polypeptide) and C100P, respectively. In a Japanese population, the gene frequencies of C100P ¹ and C100P ² were 0.907 and 0.093, respectively.     

Genetic analysis of human lymphocyte proteins by two-dimensional gel electrophoresis: 2. Genetic polymorphism of lymphocyte cytosol 64K polypeptide

Summary We describe a genetic polymorphism of human lymphocyte cytosol major polypeptide with mol. wt. 64,000, detected in peripheral blood lymphocytes by high resolution two-dimensional electrophoresis. Three different electrophoretic types (1-1, 2-1, 2-2) of the polypeptide have been identified. Family and population studies indicate that the three phenotypes of the polypeptide are determined by two common alleles at a single autosomal locus. The polypeptide occurs in the cytosol and is predominent in peripheral blood lymphocytes, B-lymphoblastoid cells, T-lymphoblastoid cells, lymph node, and spleen. The polypeptide has not been detected in HeLa cells, fibroblasts, erythrocytes, serum, and cerebrum. Traces of the polypeptide exist in liver, kidney, and skeletal muscle. It is proposed that the polypeptide and its locus be temporarily designated lymphocyte cytosol 64K polypeptide (LC64K polypeptide) andLC64P, respectively. In a Japanese population, the gene frequencies ofLC64P ¹ andLC64P ² were 0.936 and 0.064, respectively. The data suggest thatLC64P is a new locus, product of which shows genetic polymorphism and is associated with the function and/or the structure of lymphocytes.     

Genetic analysis of human lymphocyte proteins by two-dimensional gel electrophoresis:

Summary Three different electrophoretic types (1-1, 2-1 and 2-2) of a human cellular polypeptide with molecular weight of 31000 have been identified by the analysis of PHA-stimulated peripheral blood lymphocyte proteins using high resolution two-dimensional gel electrophoresis. Family and population studies indicate that the three phenotypes of the polypeptide are determined by two common alleles at a single autosomal locus. The 31k polypeptide appears to be present as a monomer in the cytosol in a wide range of different cell types, including permanent lymphoblastoid cell lines, fibroblasts and HeLa cells. In an individual with the 31k polypeptide type 2-2, the phenotypes of adenosine deaminase and uridine monophosphate kinase were both type 1. These data indicate that the 31K polypeptide is a new polymorphic protein encoded by a new autosomal locus. It is proposed that the polypeptide and its locus be temporarily designated cytosol 31k polypeptide (C31k polypeptide) and C31P, respectively. In a Japanese population, the gene frequencies of C31P ¹ and C31P ² were 0.940 and 0.060, respectively. The C31k polypeptide type 2-2 appears to be a molecular weight variant as well as a charge variant.     

Phenotype and gene frequencies of acid phosphatase (s-AcP) in the human parotid saliva

Summary Genetic polymorphism of the human parotid salivary acid phosphatase (s-AcP) in the Japanese population is described. The use of polyacrylamide gel isoelectric focusing electrophoresis with the pH range of 4.0–6.5 enabled us to discern three variant patterns controlled by two codominant alleles at the single autosomal locus. The two alleles were designated s-AcP: A and s-AcP:a, and the gene frequencies calculated from 183 Japanese subjects were s-AcP:A=0.2268±0.022, s-AcP:a=0.7732±0.022, respectively. The distribution of phenotypes fitted the Hardy-Weinberg equilibrium.     

A new method for FXIIIA genetic variants determination using isoelectric focusing in 1 M urea

Summary A new method for separating genetic variants of the A subunit of human coagulation factor XIII using ultrathin layer polyacrylamide gel isoelectric focusing in 1M urea followed by immunoblotting is described. The pattern obtained by this method differs from that reported previously: Three sets of unrelated band patterns are observed and can be explained by the existence of two additional gene loci, designated FXIIIA2 and FXIIIA3, besides the previously reported FXIIIA locus, now renamed FXIIIA1. The FXIIIA2 locus is polymorphic and shows three commonly occurring phenotypes, FXIIIA2 1, FXIIIA2 2-I, and FXIIIA2 2. These are determined by two common alleles, FXIIIA2^*1 and FXIIIA2^*2, with respective frequencies of 0.7965 and 0.2035 in the Japanese population. The studied population conforms to a Hardy-Weinberg equilibrium, and family data confirmed autosomal codominant transmission. The FXIIIA3 locus is monomorphic.     

Genetic studies on free-ranging macaques of Cay Santiago. II. 6-phosphogluconate dehydrogenase and NADH-methemoglobin reductase (NADH-diaphorase).

For the population of 395 semi-free-ranging rhesus macaques (Macaca mulatta) that inhabited Cayo Santiago in 1976, 6-phosphogluconate dehydrogenase phenotypes of 378 animals were determined. Three phenotypes, controlled by two autosomal codominant alleles,PGD^A andPGD^B, were found by electrophoretic methods. The frequencies of the alleles are 0.898 and 0.102, respectively. The population, composed of five troops and peripheral males, is in Hardy-Weinberg equilibrium at this locus. The allele frequencies at the 6-phosphogluconate dehydrogenase locus in the population in 1976 were compared with frequencies in 1973; a statistically significant difference was found in one troop. The phenotypes of NADH-methemoglobin reductase (NADH-diaphorase) were determined electrophoretically for 372 animals. These phenotypes are probably the products of two autosomal codominant alleles,Dia¹ andDia², with frequencies of 0.786 and 0.214, respectively. The population is in equilibrium at this locus also. Tests of homogeneity at the dehydrogenase and reductase loci indicate that the allele frequencies are significantly different among the five troops in the population. Observed and expected phenotypic ratios in progeny were compared at the dehydrogenase and the reductase loci. The only significant deviation from expectation occurs among offspring of mothers heterozygous at the reductase locus. The observed distributions of alleles at the 6-phosphogluconate dehydrogenase locus and the NADH-methemoglobin reductase locus are probably the results of stochastic processes.     

Genetic polymorphism of the seventh component of complement in a Japanese population

Summary Genetic polymorphism of C7 in a Japanese population has been described, using polyacrylamide gel isoelectric focusing electrophoresis followed by an electrophoretic blotting technique. Phenotypes of C7 were classified into six common patterns, and observed phenotypes were produced by autosomal codominant at a single locus with three alleles. Three common alleles, designated C7^*B, C7^*M and C7^*A, were found, and gene frequencies calculated from 494 individuals showed C7^*B=0.858, C7^*M=0.096 and C7^*A=0.046, respectively. It is noteworthy that both C7^*M and C7^*A have polymorphic frequencies in the Japanese population. The distribution of phenotypes fitted the Hardy-Weinberg equilibrium. Results indicate that the electrophoretic blotting technique, which has high specificity and sensitivity, is applicable in the study of heterogeneity of protein antigens.     

Genetic polymorphism of eserine resistant esterases in canine plasma*

Six plasma eserine resistant esterase phenotypes were observed in a population of 1438 dogs consisting of 38 breeds. Analysis of parentage records of the dogs examined revealed that the phenotypic variation of eserine resistant esterases was controlled by 3 codominant alleles Es^A, Es^Band Es^Cat one autosomal locus. The gene frequency of Es^Bwas high in most of the breeds examined. Allele Es^Cwas only seen in 5 Japanese native breeds, Akita, Shikoku, Hokkaido, Shinshu-Shiba and Mino-Shiba, and in a Spitz dog. Allele Es^Ahas a low frequency in Japanese breeds but a higher frequency in some of the European breeds tested.     

Primate red cell enzymes: glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase

Glucose-6-phosphate dehydrogenase (E. C.: 1.1.1.49) phenotypes and 6-phosphogluconate dehydrogenase (E. C.: 1.1.1.44) phenotypes were determined by starch-gel electrophoresis of red cell hemolysates of Galago crassicaudatus subspp., Propithecus verreauxi, Lemur spp., Hapalemur griseus, and Macaca mulatta. A single glucose-6-phosphate dehydrogenase (G6PD) phenotype was found in each species. A single 6-phosphogluconate dehydrogenase (6PGD) phenotype was found in Lemur spp., Hapalemur griseus, and Galago crassicaudatus argentatus. In a group of six Propithecus verreauxi, three 6PGD phenotypes, PGD A, PGD AB, and PGD B, were found. Three phenotypes, PGD A, PGD AB, and PGD B, were found in 38 G. c. crassicaudatus. The three phenotypes in each species are apparently the products of two codominant autosomal alleles, PGD^A and PGD^B. The frequency of PGD^A in G. c. crassicaudatus is 0.263. A population of 260 free-ranging macaques displays a polymorphism at the 6PGD locus. Three phenotypes, PGD A, PGD AB, and PGD B, were found. These also appear to be controlled by two codominant autosomal alleles, PGD^A and PGD^B the frequency of PGD^A = 0.913. Additional analysis of three well-defined troops within the macaque population indicated that there are no significant differences between the troops or within the population at the 6PGD locus.     

Phosphoglucomutase electrophoretic variants in the mouse

The phosphoglucomutase (PGM) electrophoretic phenotype of the mouse (Mus musculus) consists of several distinct components which can be grouped into two major zones designated PGM-1 and PGM-2. Evidence presented here indicates that each zone is controlled by a single genetic locus denoted Pgm-1 and Pgm-2, respectively. Two variant forms segregated at the Pgm-1 locus. They were codominantly expressed and inherited as alleles at an autosomal locus. The alleles were termed Pgm-1 ^a (fast) and Pgm-1 ^b (slow). These alleles were separately fixed in a number of inbred strains of mice. Preliminary evidence based on wild mouse phenotypes indicates that variant forms also exist for PGM-2 which are inherited as alleles at an autosomal locus. Genetic linkage relationships have not been determined for these loci. PGM-1 variants and PGM-2 were expressed in mouse fibroblasts in vitro.Supported by U.S. Public Health Service grants GM-09966 and GM-07249 from General Medical Sciences and 5 F2 HD-35,531 from Child Health and Human Development; and Atomic Energy Commission contract AT(30-1)-3671.Postdoctoral Fellow of the U.S. Public Health Service.     

Genetic polymorphism of complement C6 and haplotype analysis between C6 and C7 in a Japanese population

Summary Genetic polymorphism of C6 in the Japanese population has been described using polyacrylamide gel isoelectric focusing electrophoresis followed by the electrophoretic blotting technique, and haplotype analysis between C6 and C7 has also been investigated. In 565 plasma samples five different common patterns and three rare variant patterns were observed, and these were controlled by autosomal codominance at a single locus with three common and one rare alleles. These alleles were designated C6^*B, C6^*A, C6^*B2, and C6^*M, and gene frequencies were estimated to be 0.50265, 0.43186, 0.06018, and 0.00531 for C6^*B, C6^*A, C6^*B2, and C6^*M, respectively. It is noteworthy that C6^*B2 has a polymorphic frequency in the Japanese population. The distribution of phenotypes fitted the Hardy-Weinberg equilibrium. Two combinations between C6 and C7 alleles, namely C6B-C7B and C6M-C7B, were shown to be in significant positive linkage disequilibrium. The presence of allelic combinations showing linkage disequilibrium suggests the close proximity between the C6 and C7 loci.     

Orosomucoid (ORM) typing by isoelectric focusing: evidence for gene duplication of ORM1 and genetic polymorphism of ORM2

Summary It has been demonstrated that the genetic polymorphism of human serum orosomucoid (ORM) is controlled by polymorphic ORM1 and monomorphic ORM2 loci. In this study a Japanese family was encountered in which several members had puzzling electrophoretic patterns consisting of four bands. The ORM patterns were due to the products of a duplicated ORM1 locus haplotype (ORM1 ^* 2·1) or the products of new variant alleles at the ORM2 locus. The ORM1 ^* 2·1 haplotype is very common in the Japanese population, occurring at an allele frequency of 0.16. The increased occurrence of ORM1 2-1 and the heterogeneity in band intensity among ORM1 2-1 phenotypes could be explained in terms of a duplicated gene ORM1 ^* 2·1. The ORM2 locus proved to be polymorphic, with six alleles in the Japanese population. Dedicated to Professor Dr. K. Nishigami on the occasion of his 60th birthday     

Genetic variants of phosvitin in egg yolk of the Japanese quail, Coturnix coturnix japonica

Phosvitin polymorphism in egg yolk of the Japanese quail was found by horizontal polyacrylamide gradient gel electrophoresis. Six phenotypes of yolk phosvitin designated A, B, C, AB, AC, and BC were observed in a population of 281 birds. Analysis of family data revealed that the phenotypic variation of quail yolk phosvitins was controlled by an autosomal Pv locus with three codominant alleles, Pva, Pvb and Pvc. The gene frequencies of Pva, Pvb and Pvc were 0.064, 0.824 and 0.112, respectively.     

Genetic polymorphism of the B subunit of human coagulation factor XIII: Another classification

Summary Genetic polymorphism of the B subunit of human coagulation factor XIII was studied using agarose gel isoelectric focusing (pH 4–6.5) followed by immunofixation. Factor XIII-B of all samples after desialylation was classified into three types (F, S, and FS). From results of the present study, it was confirmed that factor XIII-B was controlled by two codominant alleles on an autosomal locus. Allele frequencies of F-XIIIB ^F and F-XIIIB ^S in a Japanese population were 0.336 and 0.664, respectively.     

Electrophoretic heterogeneity of mouse erythrocyte peptidases

Starch gel electrophoresis in conjunction with a specific staining method revealed the occurrence of five distinct peptidases in mouse red blood cells. These enzymes can be distinguished on the basis of substrate specificity and electrophoretic mobility. They have been designated peptidases A, B, C, D, and E to correspond with the nomenclature adopted for human peptidases with which the mouse enzymes appear to be homologous. Genetically determined variants of peptidase C are described. The phenotype Pep C1 occurs in C57BL/Gr mice and the phenotype Pep C2 in CBA/Gr and Strong A/Gr mice. These phenotypes and the presumed heterozygote, Pep C2-1, appear to be due to the occurrence of codominant autosomal alleles which have been designated Pep-C ¹ and Pep-C ². F₁ and F₂ crosses show segregation in the expected Mendelian ratios. F₂ embryos and their placentae show the same electrophoretic pattern for peptidase C. The occurrence of a separate locus controlling the structure of each distinct peptidase is postulated.     

Discovery of a genetic polymorphism of human plasma protein C inhibitor (PCI): genetic survey utilizing isoelectric focusing followed by immunoblotting,immunological and biochemical characterization

Summary The objectives of this study were to determine the genetic basis of the electrophoretic differences of human plasma protein C inhibitors (PCI) from 977 individuals. Three discrete antibodies were produced against the PCI purified from human plasma and peptides that corresponded to the N-terminal 15 amino acid residues and the C-terminal 15 residues of human PCI, the chemical structures of which were determined by cDNA sequence analysis. The combined techniques of polyacrylamide gel isoelectric focusing and immunoblotting with these three different antibodies resolved the plasma PCI into several isoprotein bands, with a pH range of 6–7. These PCI isoproteins, however, were not stained by anti-human kallikrein, anti-human protein C or anti-human urokinase antibodies. Therefore, each of the PCI bands, which were detected by immunoblotting with the anti-PCI antibody and the two different anti-peptide antibodies, were derived from free PCI, and not an inactive PCI species. Two common phenotypes, designated PCI 1 and 1–2, were recognized, and family studies showed that they represented homozygosity or heterozygosity for two autosomal codominant alleles, PCI ^*1 and PCI ^*2. A population study of plasma samples collected from 977 Japanese individuals indicated that the frequencies of the PCI ^*1 and PCI ^*2 alleles were 0.988 and 0.012, respectively.     

Genetic polymorphism of human factor I (C3b inactivator)

Summary Genetic polymorphism of human factor I (C3b inactivator) has been described using polyacrylamide gel isoelectric focusing electrophoresis of neuraminidase-treated EDTA plasma samples followed by electrophoretic blotting technique. In 435 individuals three different common patterns were observed, and these were controlled by two common alleles at a single locus. The results of typing family material confirmed autosomal codominant Mendelian inheritance. Two common alleles were designated FI^*B and FI^*A, and gene frequencies were estimated to be 0.8931 and 0.1069 for FI^*B and FI^*A, respectively. The distribution of phenotypes fitted the Hardy-Weinberg equilibrium. Linkage studies failed to show close linkage between factor I and the major histocompatibility complex.     

Genetic control of two electrophoretic variants of glucosephosphate isomerase in the mouse (Mus musculus)

The autosomal variation and the genetic control of GPI has been determined by a comparison of electrophoretic patterns of F₁ and backcross progeny of three inbred strains of mice. The locus controlling the production of GPI in the mouse has been designated Gpi-1. Two alleles at this locus have been described and designated Gpi-1 ^a and Gpi-1 ^b, which represent, respectively, the slow and fast electrophoretic forms. Twenty-seven inbred strains of mice have been classified for these two alleles. The absence of close linkage of Gpi-1 to seven other genetic loci has been determined. It has been demonstrated that the polymorphism of Gpi-1 is widely distributed in feral mice. GPI was expressed in vitro and in four types of malignant tumors.Supported by U.S. Public Health Service Grants GM-09966, from General Medical Sciences, and GY 4193.     

Genetic polymorphism of eserine resistant esterases in canine plasma

Six plasma eserine resistant esterase phenotypes were observed in a population of 1438 dogs consisting of 38 breeds. Analysis of parentage records of the dogs examined revealed that the phenotypic variation of eserine resistant esterases was controlled by 3 codominant alleles ESA, ESB and ESC at one autosomal locus. The gene frequency of ESB was high in most of the breeds examined. Allele ESC was only seen in 5 Japanese native breeds, Akita, Shikoku, Hokkaido, Shinshu-Shiba and Mino-Shiba, and in a Spitz dog. Allele ESA has a low frequency in Japanese breeds but a higher frequency in some of the European breeds tested.