Group-specific component (Gc) and transferrin (Tf) subtypes ascertained by isoelectric focusing

Simultaneous subtyping of Gc and TfC by isoelectric focusing allows us to compute the following gene frequencies for the Belgian population: Gc1S = 0.543 Gc1F = 0.167 Gc2 = 0.290 TfC1 = 0.784 TfC2 = 0.206 TfB = 0.007 TfD = 0.003. The Gc bands were precipitated by sulfosalicylic acid instead of by immunofixation.     

Electrophoretic subtyping of phosphoglucomutase locus 1 (PGM1) polymorphism in the Italian and Czechoslovakian populations

About 3,500 subjects from Italy and Czechoslovakia have been analyzed by acid starch gel electrophoresis for the subtyping of PGM1 polymorphism. The Italian sample included three different subgroups, from Northern, Central and Southern Italy. The allele frequencies found in the three groups do not differ significantly from each other; the observed values in the pooled sample are: PGM1S1 = 0.594, PGM1F1 = 0.118, PGM2S1 = 0.231, PGM2F1 = 0.057. In the Czechoslovakian group, which differs significantly from the Italian population, the following allele frequencies were found: PGM1S1 = 0.639, PGM1F1 = 0.118, PGM2S1 = 0.180, PGM2F1 = 0.063. The analysis of 217 families did not show any exception to Mendelian inheritance of the patterns.     

Genetic structure of the Mongols as derived from the ABO, MN, Rh, EsD, GLO1, PGM1, AcP, 6-PGD, Hp, Gc, Tf, C'3 and ChE2 loci

According to integral characterization of gene frequencies of the investigated loci AB0, MN, Rh, GLO1, PGM1, EsD, AcP, 6-PGD, Hp, Tf, Gc, C'3 and ChE2, Mongolian population has high level of polymorphism, with the exception of haplotypes R" (cdE) and Ry(CdE) at the Rh locus and TfB0-1 at the Tf locus. The data on biochemical and immunological polymorphic gene markers analysed in the population of Mongolia show that the Mongolians have some distinctive features, in comparison with the mean-in-the-world characteristics: high frequencies of the B genes at the AB0 locus; D, E, R1 and R2 at the Rh locus; GLO11, PGDc, TfDChi, E2(C5+), PGM1(1+); low frequencies of the genes A(AB0), R0(Rh), AcPc, Hp1, Gc2, C'3F, PGM 1(2-); the rest of the genes at the above-mentioned loci and the genes of the locus MN have the mean-in-the-world frequencies.     

A genetic study among the Lepchas of the Darjeeling area of eastern India

A total of 215 Lepchas (75 Buddhists and 140 Christians) living in the Kalimpong subdivision, Darjeeling district, West Bengal, India, were investigated for the distribution of haemoglobin, serum proteins and red cell enzymes. The gene frequencies were as follows: HbE = 0.02; Hp1 = 0.18; TfB = 0.007; TfDChi = 0.005; Gc2 = 0.22; pa = 0.18; pc = 0.03; PGM2(1) = 0.18; PGM6(1) = 0.002; PGDc = 0.17; AK2 = 0.02; GLO1 = 0.21. The most striking features were the complete lack of G6PD deficiency and very high frequency of PGDC. The remaining loci (serum albumin, lactate dehydrogenase, malate dehydrogenase and glucose-6-phosphate dehydrogenase, phosphohexose isomerase and superoxide dismutase) were monomorphic. The gene frequencies were similar in the Buddhist and Christian Lepchas. The observed average heterozygosity (9 loci) was 0.20 in the entire sample.     

Genetic studies of phosphoglucomutase-1 (PGM1) subtypes: population aspects]

Distribution of the subtypes and gene frequencies of phosphoglucomutase-1 among some populations of Buryats, Kirghizes of the Pamir and Russians of Moscow district was analysed. The frequencies of PGM1 genes vary in Buryats being PGM1+(1) 0.647-0.743, PGM1-(1)-0.100-0.132, PGM2+(1)-0.122-0.199 and PGM2-(1)-0.007-0.037. Following frequencies of PGM1 genes were established for Kirghizes: PGM1+(1) = 0.614, PGM1-(1) = 0.114, PGM2+(1) = 0.217 and PGM2-(1) = 0.054; in Russian populations the frequencies were: PGM1+(1) = 0.578, PGM1-(1) = 0.110, PGM2+(1) = 0.253 and PGM2-(1) = 0.059. Peculiarities of PGM1 polymorphism in the USSR and all over the world were analysed. Parallel biodemographic investigations in Buryat population demonstrated differences in intensities of selection, related to concrete PGM genotypes.     

Serum protein and red cell enzyme polymorphisms in affective disorders

Frequencies of serum groups (Hp and Gc) and red cell enzyme types (PGM1, 6-PGD and ES D) were studied in 195 patients with affective disorders. The patients were classified into four groups: (1) bipolar (manic-depressive) psychosis; (2) unipolar, recurrent, depressive psychosis; (3) non-psychotic reactive depression, and (4) unclassifiable. The Hp2 gene was increased in reactive and unclassifiable patients, the PGM1 1 gene was increased in bipolar patients and the ES D1 gene in reactive patients. No associations were found between affective disorders and the Gc and 6-PGD systems.     

Genetic structure of the populations of native inhabitants of the northeastern USSR. IV. The Koryaks of Kamchatka

Genetic structure of four Kamchatka subpopulations (675 individuals) was estimated for 25 erytrocyte and serum systems, some blood groups and for taste sensitivity to PTC. 23 of 38 loci examined are completely monomorphic. These are: AK, Ca-1, Cat, Dia, Est1-4, GOT, G-6-PD, LDH A and B, MDH, PGM2, SoD, Hb alpha and beta, ChE1, Lap, Alb, Cp, Tf, Rh. Following allele frequencies were found for polymorphic loci: AcPA = = 0.616; AcPB = 0.383; AcPC = 0.0015; EsD1 = 0.882; GLO - I1 = 0.156; GPT1 = 0.611; PGDA = = 0.959; PGM1(1) = 0.953; ChE2+ = 0.039; Gc1 = 0.888; Hp1 = 0.173; r(0) = 0.620; P(A) = 0.201; q(B) = 0.179; le = 0.192; M = 0.397; P1+ = 0.585; t = 0.371. According to monomorphic and polymorphic loci set, Kamchatka Koryaks are rather similar to other ethnic North-East Asiatic groups, being the most approximate to Reindeer Chuckchies and the most remote from Alaskan and Asiatic Eskimos. In other words, the extent of genetic differences between Kamchatka Koryaks and North-East populations corresponds to the geographic distribution and the degree of ecological differences in these populations. Analysis of interpopulation heterogeneity permitted to reveal the extent of contribution of individual loci to "differentiation" of North-East ethnic groups. The possible influence of ecological factors on interpopulation and intersubpopulation heterogeneity of the loci analysed is discussed.     

Population genetics of the group specific component (Gc) and phosphoglucomutase (PGM1) studied by isoelectric focusing

For the determination of the group-specific component (Gc) and phosphoglucomutase (PGM1) phenotypes, isoelectric focusing was performed on two samples, one of Jat Sikh of northwest India, the other of northeast English. The subtype frequencies of these two systems do not differentiate the two populations sampled. Synthesis of the existing data shows distinct PGM1 and Gc subtype frequencies in various ethnic and racial groups. The anthropological implication of these subtype frequencies is discussed.     

中国广东人红细胞PGM_1亚型遗传性多态现象

采用薄层聚丙烯酰胺凝胶等电聚焦技术,调查了中国(广东)406名无亲缘关系的正常人红细胞磷酸葡萄糖变位酶-1(PGM_1)亚型的遗传多态性。除了常见的10种亚型外,还发现了由一个新的变异型等位基因和常见的4个等位基因杂合产生的9例变异型。PGM_1位点的等位基因频率PGM_1~(1+)、PGM_1~(1-)、PGM_1~(2+)、PGM-1~(2-)和PGM_1~(V丰)(变异型等位基因)分别为0.5973、0.1256、0.1724、0.0936和0.0111;群体处于Hardy-Weinberg式平衡状态。变异型等位基因以多态频率出现,可能成为该群体的一个重要的遗传性特征。     

Genetic structure of the populations of native inhabitants in the northeastern USSR. V. The Chukot Evens

The genetic structure of two Chukot Evens subpopulations (314 individuals) for electrophoretic protein systems and taste sensitivity to PTC was studied. 17 of the 39 loci were polymorphic (43.59%). The following systems were completely monomorphic: diaphorase NAD H (Dia); glucose-6-phosphate dehydrogenase (G-6-PD); glutamatoxalate transaminase (GOT); carbonic anhydrase (Ca-1); catalase (Ct), lactate dehydrogenase (loci LDH-A and LDH-B); leucine aminopeptidase (Lap); malate dehydrogenase (MDH); purine nucleoside phosphorylase (PNP); superoxide phosphorylase (PNP); superoxide dismutase (SOD); phosphoglucomutase-2 (PGM2); cholinesterase (locus E1); red cell esterase (4 loci); albumin (Alb); hemoglobin (Hb A and B); ceruloplasmin (Cp); and blood, gren, using the standard method. The following systems were polymorphic: red cell acid phosphatase (AcP); phosphoglucomutase-1 (PGM1); 6-phosphogluconate dehydrogenase (PGD); glutamatepyruvate transaminase (GPT); glyoxalase-1 (GLO-1); esterase (EsD); adenilatkinase (AK); alkaline phosphatase (Pp); cholinesterase (locus E2); haptoglobin (Hp); transferrin (Tf); group-specific component (Gc) and ABO, MN, Lewis, P blood groups and taste sensitivity to PTC. The following allele frequencies for polymorphic loci have been detected: AKI = 0.994; GLO = 1I = 0.082; GPT1 = 0.653; AcPA = 0.400; AcPB = 0.599; AcPC = 0.001; PGDA = 0.944; PGM1(1) = 0.906; EsD1 = 0.897; E2+ = 0.048; HpI = 0.394; GcI = 0,919; Tfc = 0.987; r(O) = 0.669; p(A) = 0.184; q(B) = 0.146; M = 0.711; Le = 0.411; P1+ = 0.521; t = 0.295. The genetic structure of Chukot Evens population is significantly nearer to that of the other ethnic groups of the North-East, in comparison with the genetic structure of Evenks of the Middle Siberia.     

To the research of the gene pool of the Gagauz population of Moldavia

Population genetic data on Gagauzes from Moldavia are reported here for the first time. AB0 and Rhesus blood groups, serum protein group (HP, TF, GC) and the red cell enzyme polymorphism PGM1 were determined in 190 Gagauzes. In addition to this the ability to taste PTC was tested. The following allele frequencies were found: AB0*0 = 0.5241, AB0*A = 0.3279, AB0*B = 0.1480; RH*D = 0.6083, RH*d = 0.3917; HP*1 = 0.3544, HP*2 = 0.6456; TF*C1 = 0.7472, TF*C2 = 0.1770, TF*C3 = 0.0730, TF*B = 0.0028; GC*1F = 0.1025, GC*1S = 0.5932, GC*2 = 0.3043; PGM*1+ = 0.5932; PGM*1- = 0.1000, PGM*2+ = 0.2607, PGM*2- = 0.1107. The frequency of the PTC*T allele was found to be 0.5298. These frequencies and genetic distance analyses show that the gene pool of the Gagauzes is similar to that of neighbouring southeastern European populations.     

Subtyping of phosphoglucomutase locus 1 (PGM1) polymorphism in some populations of Rwanda: description of variant phenotypes, "haplotype" frequencies,and linkage disequilibrium data.

Some populations of Rwanda (South Twa Pygmies, Hutu, and Tutsi) have been analyzed by acid starch gel electrophoresis for the subtyping of PGM1 polymorphism. The new polymorphic third PGM11 allele, the PGM1(1Twa), which we recently detected in Twa Pygmies from North Rwanda, has not been found in this survey, whereas the rare PGM1(6) allele attains subpolymorphic frequencies in all groups. Comparison between the various populations of Rwanda shows that they differ significantly from each other with the exception of South Twa Pygmies and Tutsi. A relatively low frequency (9.6%) of the PGM1(2S) allele appears to be typical of North Twa Pygmies; a low frequency of PGM1(2F) (1.2%-3.6%) has been found in all these groups but not in the Hutu (6.4%); and a particularly high incidence of the PGM1(1F) allele (the highest so far reported) has been observed in the South Twa Pygmies (20%) and in the Tutsi (18%). The PGM1(1Twa) and PGM1(6) enzymes, which in acid starch gel are not distinguishable, can be clearly differentiated by isoelectric focusing. In addition, the same technique has shown that the rare PGM1(7) allele observed in one Hutu is different from that found at polymorphic frequency in the Japanese and from a rare PGM1(7) allele found in Germany. On the very likely hypothesis that the PGM1(1S), PGM1(1F), PGM1(2S), and PGM1(2F) result from variations at two different polymorphic sites, 1/2 and F/S, within the PGM1 structural gene, all the available population data have been analyzed to investigate whether preferential combinations (haplotypes) were identifiable. Whereas Caucasians show a prevalence of 2F and 1S combination with an 8.02% mean value of linkage disequilibrium expressed as % Dmax, from the very few and scattered African data, it is impossible to draw any inference at present.     

Group-specific component (Gc): subtypes in the Finnish population. Description of a new allele and an apparent mother-child incompatibility

The group-specific component (Gc) subtypes were determined in 575 adult Finns by immunoblotting after isoelectric focusing in agarose gel. The gene frequencies were Gc1S = 0.661, Gc1F = 0.139 and Gc2 = 0.200. This material included one rare allele, a more acidically focusing Gc 2 (named Gc 2A18). The phenotypes of 200 mother-child pairs studied were in accordance with the three-allelic mode of inheritance. An apparent mother-child incompatibility observed during routine paternity testing is reported.     

我国几个民族中毛发根葡糖磷酸变位酶—1的亚型分布

本文报道了利用等电聚焦的方法,从毛发根鞘细胞分析了我国汉、苗、土家、撒拉、土、达斡尔和赫哲等民族的葡糖磷酸变位酶-1(PGM_1)10亚型的分布,并且与其他人群的基因频率作了比较。     

中国20个民族中PGM_1及其亚型EsD、GLO1、AK、ADA和6-PGD酶型分布调查

调查了汉族、鄂伦春、赫哲、朝鲜、蒙古、羌、土家、苗、侗、畲、壮、纳西、傈僳、白、彝、景颇、哈尼、傣、维吾尔和塔吉克等20个民族的PGM_1及其亚型,EsD、GLO_1、AK、ADA和6-PGD等酶型的分布及基因频率。PGM_1及其亚型、EsD和GLO_1在中国各民族中是分布较好的,个人识别能力较高的酶。有12个民族查出有PQM_1~6基因,壮族的频率最高,PGM_1 6-1表型达4.15％。对在4174份血样中所检出的带有PGM_1~6基因的68份血样做亚型分析,在凝胶上PGM_1~6谱带均在同一位置上。EsD_1基因频率的总趋向是北方各民族高于南方。哈尼、傈僳、傣、纳西、畲、壮、侗和苗等民族EsD2-2表型达15％以上,哈尼族高达32.4％。GLO1~1基因频率塔吉克和维吾尔族为0.2927和0.2112,羌族为0.0583,其它各族在0.0714—0.1527。各民族AK~1、ADA和6-PGD~(?)基因频率均甚高。     

Gc and C3 polymorphisms in Central Sardinia

The distribution of phenotypes and gene frequencies of the group-specific component (Gc) and C3 complement were studied in Central Sardinian sample. The gene frequencies were:Gc1 = 0.733; C3F = 0.237.     

Gc and C3 polymorphisms in South Sardinia

The distribution of phenotypes and gene frequencies of the group-specific component (Gc) and C3 complement were studied in South Sardinia. The gene frequencies were: Gc1 = 0.7346; C3F = 0.1963.     

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.     

Evidence for two additional common alleles at the PGM1 locus (Phosphoglucomutase-E.C.:2.7.5.1)

Summary Lysates of erythrocytes, leukocytes, lymphocytes, and extracts of sperms were investigated for the PGM₁ isozymes by three techniques: starch gel electrophoresis, high voltage thin-layer agarose gel electrophoresis, and thinlayer isoelectric focusing on polyacrylamide gel. On starch, only the well known common phenotypes 1, 2-1, and 2 were demonstrable. On agarose, different distances of the two main cathodal bands (a, b) among the phenotypes 2-1 were noted. Furthermore, on agarose, some types considered as homozygous on starch gel had a single, sharp banded pattern, while others were broad and blurred. Optimal separation was achieved by isoelectric focusing on polyacrylamide gel. In 291 leukolysates, 10 different phenotypes were identified. These are considered as gene products of 4 different common alleles at the PGM₁ locus as suggested by preliminary family investigations. In a random population from Hessen these four alleles, had the following frequencies: PGM ₁ ^a1 0.6186, PGM ₁ ^a2 0.1718, PGM ₁ ^a3 0.1426, and PGM ₁ ^a4 0.067. The preliminary designation a1, a2, a3 and a4 was chosen as the assumed polymorphism was demonstrated on acrylamide and agarose. The sum of the frequencies PGM ₁ ^a1 and PGM ₁ ^a3 (the gene products of which have apparently the same electrophoretic mobility on starch) is similar to the frequency of the old PGM ₁ ¹ allele (0.757) in Caucasoids, PGM ₁ ^a2 and PGM ₁ ^a4 have a frequency of 0.2388 corresponding with the frequency of the old allele PGM ₁ ² .     

Genetic polymorphism of haptoglobin subtypes in a Japanese population

Haptoglobin (Hp) subtypes have been determined in the Japanese population by polyacrylamide gel isoelectric focusing followed by immunoblotting and by two-dimensional polyacrylamide gel electrophoresis. In the present study, neuraminidase-treated plasma samples were used for subtyping of Hp, without prior purification. These samples were obtained from 372 unrelated healthy donors. Allelic frequencies were: Hp*1F = 0.0014; Hp*1S+ = 0.2688; Hp*2FF = 0.0000; Hp*2FS = 0.7284, and Hp*2SS = 0.0014. The phenotypic distribution was in good accordance with the Hardy-Weinberg equilibrium.