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.     

Protein subtype polymorphisms (Gc and Tf) in a Catalan population from Gerona (northeastern Spain)

The Tf and Gc polymorphic subtype variants have been examined by means of isoelectric focusing in a population sample from two subpyrenean regions in the province of Gerona (Northeast Spain). The estimated allele frequencies were Tf*C1 = 0.774, Tf*C2 = 0.167, TF*C3 = 0.055, TF*B = 0.004; Gc*1F = 0.129, Gc*1S = 0.555 and Gc*2 = 0.316. These values are in general similar to those so far reported in other Spanish populations. The comparisons between our data and those published in Spain, indicate that the present sample is closer to Barcelona than to the other groups compared.     

Serum protein polymorphisms in Arab Moslems and Druze of Israel: BF, F13B, AHSG, GC, PLG, PI, and TF.

We report results of typing two population samples, Israeli Arab Moslems and Arab Druze, for seven serum protein genetic variants. Data are presented in comparison with results for the same markers in a sample of Jordanian Arabs. In Israeli Moslems gene frequencies for BF (n = 169) were BF*S = 0.6361, BF*F = 0.3343, BF*S07 = 0.0296, and BF*1 = 0, and for TF (n = 90) the gene frequencies were: TF*C1 = 0.7167, TF*C2 = 0.2611, and TF*C3 = 0.0222. Allele frequencies for AHSG in Israeli Moslems (n = 155) and Druze (n = 192) were AHSG*1 = 0.9129 and 0.8750 and AHSG*2 = 0.0806 and 0.1250, respectively. Gene frequencies for PLG in Moslems (n = 149) and Druze (n = 190) were PLG*A = 0.4597 and 0.5288 and PLG*B = 0.5101 and 0.4188, respectively. The typing of Israeli Arab Druze (n = 194) for F13B resulted in F13B*1 = 0.8454, F13B*2 = 0.0387, F13B*3 = 0.0979, and F13B*4 = 0.0180. Results on the same population for PI (n = 192) were PI*M1 = 0.7839, PI*M2 = 0.1276, PI*M3 = 0.0781, PI*M4 = 0.0026, and PI*M5 = 0.0026. Observed rare alleles in various systems indicate gene flow from Europe, Africa, and Asia into the Middle East. The results on Arab populations were considered in relation to available population data in the three adjacent continents. The emerging gene frequency profile for Arabs seems to fit with the central geographic and climatic position of the Middle East.     

Transferrin C subtypes and ethnic heterogeneity in Sweden

Transferrin (TF) C subtypes were studied in Swedish Lapps (Saami) and in Swedes from northern, central and southern Sweden, and the allele frequencies were compared with those in other European populations. The Swedish Lapps were found to have the lowest frequency of the TF*C3 allele (1-2%) so far observed in Europe. Most European populations have TF*C3 allele frequencies between 5 and 7%. Finns differ by having high TF*C3 frequencies (13-14%). The relatively high TF*C3 frequencies found in northeastern Sweden (13%) and in central Sweden (9%) are most likely due to eastern influence. Unlike other genetic markers of eastern influence (e.g. TF*DCHI), which are of Asiatic Mongoloid origin, TF*C3 appears to originate from Finno-Ugric populations.     

Transferrin subtypes in 51 Danish patients with hereditary haemochromatosis and in 847 normal subjects

Summary Transferrin (TF) subtypes were determined by isoelectric focusing in 51 unrelated Danish patients with hereditary haemochromatosis (HH) and in 847 normal subjects. The following TF phenotype frequencies were observed in HH patients and controls, respectively: TF*C1, 70.6% vs. 58.8%; TF*C2, 5.9% vs. 2.4%; TF* C3, 0% vs. 0.4%; TF*C1–2, 11.8% vs. 24.7%; TF*C1–3, 5.9% vs. 9.7%; TF*C2–3, 3.9% vs. 2.2%; TF*B–C1, 2.0% vs. 1.5%; TF*B–C2, 0% vs. 0.4%. None of these differences were statistically significant. There was no relationship between the TF subtypes and the clinical or paraclinical expression of disease in HH patients.     

PI and TF subtypes in Chuetas (Majorcan Jews).

PI and TF subtypes were studied in a sample of 137 individuals of the Chueta population. In addition to the PI*M alleles, PI*S, PI*Z, and PI*F were observed in the PI system. In the TF system no TF*B or TF*D alleles were found. PI results were compared with those of some Jewish and non-Jewish populations. The relatively high frequency of PI*S is indicative of a substantial Spanish influence. There are no previous data available on TF*C subtypes in Jews. The very low TF*C3 frequency in Chuetas (lower than in Spain) indicates that this allele may be extremely rare or absent in other Jewish populations.     

Characteristics of the gene pool of the Gagauz population of Moldova]

Population genetic data on Gagauzes from Moldova are reported for the first time. Blood groups AB0 and Rh and biochemical markers of genes HP, TF, GC, and PGM1 were determined in 190 Gagauzes. The following allelic frequencies were determined: AB0*0, 0.5241; AB0*A, 0.3279; RH*d, 0.4571; HP*1, 0.3544; TF*C1, 0.7472; TF*C2, 0.1770; TFC3, 0.0730; TF*B, 0.0028; GC*1F, 0.1025; GC*1S, 0.5932; GC*2, 0.3043; PGM1*1+, 0.5286; PGM*1-, 0.1000; PGM1*2+, 0.2607; and PGM1*2-, 0.1107. The data obtained indicate that the gene pool of Gagauzes is similar to those of neighboring southeastern European populations.     

Distribution of the ABO blood groups and the HP,TF, GC,PI and C3 serum proteins in Yakuts

In Yakut populations examined, polymorphisms of immunological and serum protein markers, including AB0 and Rhesus blood groups, HP, TF, GC, PI and C3, were revealed. Gene frequencies for the systems studied fell into the following ranges: AB0 system: r, 0.514 to 0.663; p, 0.136 to 0.306; q, 0.110 to 0.337; haptoglobin HP*1: 0.214 to 0.431; transferrin TF*C: 0.700 to 1.0; group specific component GC*1: 0.821 to 0.978; PI*M1 proteinase inhibitor (or alpha 1-antitrypsin) PIM1: 0.860 to 0.946; and third component of the complement C3*F: 0.031 to 0.143.     

Genetic predisposition to development of toxic liver cirrhosis caused by alcohol]

Comprehensive analysis of the contribution of genetic factors into predisposition to alcoholic toxic cirrhosis (TC) was performed. The ABO, RH, HP, TF, GC, PI, ACP1, PGM1, ESD, GLO1, and GST1 genetic polymorphisms were compared in 34- to 59-year-old male TC patients and control donors of the same sex and age. The phenotypic frequencies in the TC group deviated from the theoretically expected values; the main difference was the excess of rare homozygotes for the loci GC, ACP1, ESD, and GLO1. In the TC patients, the observed heterozygosity (Ho) was considerably lower than the theoretically expected value (H(e)). Wright's fixation index (F) in the TC patients was 30 times higher than in the control group (0.0888 and 0.0027, respectively). The frequencies of PI*Z and PI*S, the PI alleles that are responsible for lower concentrations of proteinase inhibitor, were 12 and 6 times higher in the TC than in the control group. The TC patients exhibited a significantly higher frequency of the liver glutathione-S-transferase GST1*0 allele, whereas the GST1*2 frequency was two times higher in the control subjects than in the TC patients (0.2522 and 0.0953, respectively). The TC and control groups showed statistically significant differences in the frequencies of the following alleles of six independent loci: ABO*0, TF*C1, TF*C2, PI*M1, PI*Z, ACP1*C, PGM1*1+, PGM1*1-, PGM1*2-, GST1*0, and GST1*2. The haptoglobin level was significantly higher and the serum transferrin level was drastically lower in all phenotypic groups of TC patients than in control subjects. The concentrations of IgM and IgG depended on the HP, GC, and PI phenotypes. The total and direct reacting bilirubin concentrations depended on the erythrocytic-enzyme phenotypes (ACP1, PGM1, and GLO1) in both TC and control groups.     

Genetic structure of Mongolic-speaking Kalmyks.

Genetic polymorphisms of blood groups ABO and RH D, serum proteins HP, TF, and GC, and red cell enzymes ACP1, PGM1, ESD, GLO1, and SOD-A have been reported for three tribes (Torguts, Derbets, and Buzavs) of the Volga's Kalmyk-Oyrats. The Kalmyks exhibit genetic markers that are characteristic of Central Asian populations, namely, high allelic frequencies for ABO*B, TF*C2, GC*IF, ESD*2, and GLO1*2, and the rare incidence of individuals with the RH-negative phenotype. Genetic distance measures reveal that close genetic affinities exist between the Derbets and Buzavs, but both populations differ significantly from the Torguts. Collectively as an ethnic group, the Kalmyks genetically resemble the contemporary Buryats of the Baikal region of southeastern Siberia and the Mongols of Mongolia. The transplantation of the Kalmyk-Oyrats from their homeland near Lake Baikal to their current residence (4500 km) near the Caspian Sea and their subsequent isolation for more than 300 years have not appreciably altered the gene frequencies from the parental populations for frequencies of standard genetic markers.     

The Russian gene pool. Genogeography of serum genetic markers (HP, GC, PI, TF)

The study continues the series of works on the Russian gene pool. Gene geographic analysis of four serum gene markers best studied in the Russian population (HP, GC, PI, and TF) has been performed. Gene-geographic electronic maps have been constructed for 14 alleles of these loci and their correlations with geographic latitude and longitude. For all maps, statistical characteristics are presented, including the variation range and mean gene frequencies, partial and multiple correlations with latitude and longitude, and parameters of heterozygosity and interpopulation diversity. The maps of five alleles (HP*1, GC*2, GC*1S, PI*M2, and TF*C2) are shown and analyzed in detail. The genetic relief and structural elements of the maps are compared with the ecumenical trends, main variation patterns of these genes in northern Eurasia, and genetic characteristics of the indigenous populations of the Urals and Europe.     

The N-terminal epidermal growth factor-like domain in factor IX and factor X represents an important recognition motif for binding to tissue factor.

Factors VII, IX, and X play key roles in blood coagulation. Each protein contains an N-terminal gamma-carboxyglutamic acid domain, followed by EGF1 and EGF2 domains, and the C-terminal serine protease domain. Protein C has similar domain structure and functions as an anticoagulant. During physiologic clotting, the factor VIIa-tissue factor (FVIIa*TF) complex activates both factor IX (FIX) and factor X (FX). FVIIa represents the enzyme, and TF represents the membrane-bound cofactor for this reaction. The substrates FIX and FX may utilize multiple domains in binding to the FVIIa*TF complex. To investigate the role of the EGF1 domain in this context, we expressed wild type FIX (FIX(WT)), FIX(Q50P), FIX(PCEGF1) (EGF1 domain replaced with that of protein C), FIX(DeltaEGF1) (EGF1 domain deleted), FX(WT), and FX(PCEGF1). Complexes of FVIIa with TF as well as with soluble TF (sTF) lacking the transmembrane region were prepared, and activations of WT and mutant proteins were monitored by SDS-PAGE and by enzyme assays. FVIIa*TF or FVIIa*sTF activated each mutant significantly more slowly than the FIX(WT) or FX(WT). Importantly, in ligand blot assays, FIX(WT) and FX(WT) bound to sTF, whereas mutants did not; however, all mutants and WT proteins bound to FVIIa. Further experiments revealed that the affinity of the mutants for sTF was reduced 3-10-fold and that the synthetic EGF1 domain (of FIX) inhibited FIX binding to sTF with K(i) of approximately 60 microm. Notably, each FIXa or FXa mutant activated FVII and bound to antithrombin, normally indicating correct folding of each protein. In additional experiments, FIXa with or without FVIIIa activated FX(WT) and FX(PCEGF1) normally, which is interpreted to mean that the EGF1 domain of FX does not play a significant role in its interaction with FVIIIa. Cumulatively, our data reveal that substrates FIX and FX in addition to interacting with FVIIa (enzyme) interact with TF (cofactor) using, in part, the EGF1 domain.     

Genetic transferrin types and iron-binding: a comparative study of a European and an African population sample

Summary Two population samples, one from Europe and one from Africa, were analyzed for the distribution of genetic transferrin (TF) types, serum concentrations of TF, serum iron concentrations and free iron-binding capacities. In Europeans the distribution of the TF alleles was C1=0.816, C2=0.143, C3=0.037 and B₂=0.004. In black Africans the allele frequencies were: C1, 0.823; C2, 0.104; and D₁=0.073; TF^*C3 was absent. The mean serum concentrations were 362±88 mg/dl in Europeans and 528±176 mg/dl in Africans; this difference was statistically significant. The concentration of serum imunoglobulins was also elevated in black Africans although their health was reported to be normal. The serum iron concentrations in Africans were decreased; the free ironbinding capacity of TF was, thus, increased; the free ironbinding capacity of TF was, thus, increased. In both population samples there was a tendency for slightly higher TF concentrations in the TF C1 subtype than the TF C2 subtype. This correlation was not statistically significant. Analysis of a larger sample is required to establish this relationship.     

Genetic structure of a Sakha population from Siberia and ethnic affinities

The red cell enzymes ACP1, ESD, GLO1, PGM1 and RDS and the serum proteins GC, HP, PI, and TF were determined for samples of 150 and 144 Sakha, respectively. The Sakha, a Turkic-speaking population, inhabit the Sakha-Yakutia Republic in northeastern Siberia. High gene frequencies were found for ACP1*A, GLO1*1 and GC*1F, whereas no P1*S or P1*Z alleles were found. In addition, 1 heterozygous phenotype with ACP1*C and 2 heterozygous phenotypes with ESD*7 were found. The genetic distance measures show close affinities of the Sakha population to Buryats (especially Western Buryats), Mongols, and Evenks, whereas the genetic distance to Turkic-speaking Altay and Tuvan populations is great.     

C6 polymorphism in Japanese: typing by agarose gel isoelectric focusing-immunofixation

Agarose gel isoelectric focusing was used to investigate the genetic polymorphism of the sixth component of complement (C6) in Japanese. C6 patterns were visualized by the immunofixation procedure. The allele frequencies calculated from 135 individuals were as follows: C6*A = 0.467, C6*B = 0.481, C6*B2 = 0.037, and C6*B3 = 0.015. It is suggested that C6*B3 is the fourth common allele characterizing the Japanese population.     

The cytoplasmic domain of tissue factor is phosphorylated by a protein kinase C-dependent mechanism.

Tissue factor (TF) is an integral membrane glycoprotein that serves as a cellular receptor and cofactor for the activation of the plasma protease factor VII. TF activity in both monocytes and endothelial cells is regulated by various cytokines and mitogens, including the protein kinase C (PKC) activator phorbol 12-myristate 13-acetate (PMA). Three TF constructs (full-length human, a cytoplasmic domain deletion mutant, and a human-rat TF chimera), expressed in a human kidney cell line, were used to examine the in vivo phosphorylation state of TF after PMA treatment. The cytoplasmic domains of both rat and human TF were rapidly phosphorylated after cells were treated with 10-100 nM PMA. This response was completely abolished by preincubating cells with staurosporine, the potent PKC inhibitor, prior to PMA treatment. Localization of the phosphorylation site(s) to the cytoplasmic domain was demonstrated using a deletion mutant of TF and by CNBr digestion at the single methionine residue (Met-210) in the TF sequence. The rat TF cytoplasmic domain was phosphorylated to a higher specific activity than the human TF cytoplasmic domain. Phosphoamino acid analysis of the chimeric TF revealed both phosphothreonine and phosphoserine, whereas human TF contained only phosphoserine. Thus both potential phosphoacceptor sites are phosphorylated in the rat TF cytoplasmic domain. Alignment of TF cDNA sequences of mouse, rat, rabbit, and man revealed that the phosphoacceptor site (X-S*/T*-P-X, where asterisk indicates the phosphorylated residue) in the cytoplasmic domain has been conserved through evolution.     

C7 polymorphism in Japanese: new allele C7*8

The polymorphism of C7 was investigated in neuraminidase-treated sera from 513 unrelated Japanese individuals using isoelectric focusing followed by an electroimmunoblotting technique. Besides the common phenotypes 5 rare variants including 2 types of new variants were detected. The family analysis suggested the hereditary occurrence of a new allele C7*8. The allele frequencies were: C7*1 = 0.8314, C7*2 = 0.0926, C7*3 = 0.0380, C7*4 = 0.0331, C7*6 = 0.0010, and C7*8 = 0.0039.     

Restriction fragment analysis of duplication of the fourth component of complement (C4A)

The two genes encoding the fourth component of complement (C4A and C4B) reside between HLA-B and HLA-DR on human chromosome 6. Two kilobases downstream from each C4 gene lies a 21-hydroxylase gene (CA21HA and CA21HB, respectively). Utilizing the method of Southern blotting and a 5'-end 2.4-kb BamHI/KpnI fragment of the C4 cDNA, we have analyzed TaqI-digested DNA from four pedigrees with one or more extended haplotypes containing a C4A duplication, as demonstrated by protein electrophoresis and segregation analysis. Two C4A protein duplications (C4A*2,A*3,C4B*QO and C4A*3,A*5,C4B*QO) segregated with two large TaqI DNA restriction fragments (7.0 and 6.0). In pedigree Fi, one individual homozygous for HLA-A3,B35,C4,DR1,DQ1,BFF,C2C,-C4A2,3,C4BQO had TaqI 7.0- and 6.0-kb restriction fragments with equal hybridization intensities as measured by two-dimensional densitometry (7.0/6.0 kb = 0.83, SD = 0.12, N = 7). A hybridization probe for the 21-hydroxylase gene also demonstrated equal gene dosage (CA21HA/CA21HB = 1.01). DNA from another individual (Ma I-2) with a different C4A gene duplication (C4A*3,A*5,C4B*QO) also had equal densitometry measurements (7.0/6.0 kb = 1.07). We conclude that two extended haplotypes from unrelated pedigrees have two C4 genes and both C4 genes encode separate C4A alleles. These findings are compatible with a gene conversion event of C4B to C4A.     

C1R subcomponent polymorphism in Japanese: description of a new allele

The polymorphism of C1R was investigated in 570 unrelated Japanese individuals using isoelectric focusing and immunoblotting. A total of 11 different C1R phenotypes including a new pattern designated C1R 11-1 were observed. The allele frequencies were C1R*1 = 0.4561, C1R*2 = 0.3377, C1R*5 = 0.1956, C1R*8 = 0.0088 and C1R*R (C1R*9 and C1R*11) = 0.0018. The population data fitted the Hardy-Weinberg equilibrium. The C1R polymorphism in Japanese was shown to be controlled by 3 common alleles, C1R*1, C1R*2 and C1R*5, as compared to Caucasians where only the former 2 are present commonly. This complement system can be a useful genetic marker for anthropological studies.     

Genetic polymorphisms in autochthonous Basques from northern Navarre

This survey reports primary results of classical allele frequencies on ten protein loci in a Basque population sample from northern Navarre, the less known from an anthropological and genetic point of view than the populations of the other Basque territories of Spain. Since ancient times this has been a zone of Basque population settlement, and the Basque language (Euskera) still remains deeply rooted among its autochthonous population. A total of 122 blood samples from unrelated northern Navarrese with autochthonous ascendants to the third generation were typed for GC, HP, PI, TF, ACP1, AK1, CA2, ESD, PGD and PGM1 genetic systems. Basque surnames and birthplaces were the criteria used to define family origins. Genetic structure was analyzed on different population hierarchical levels. Northern Navarre seems to be the most genetically deviated area in comparison with other Basque groups. The highest level of differentiation is observed between Navarrese and Alava Basques whereas Guipúzcoa province, the territory adjacent to northern Navarre, presents the lowest genetic distance from the study area. Northern Navarrese show some distinguishing genetic characteristics in relation to other Basque relative samples, which include high frequencies for PI*M1 and TF*C1 and low levels of PGD*C and PGM1*2 alleles. When the genetic data reported here are analyzed jointly with GM allotypes frequencies, the results significantly reinforce the relative position of Navarrese Basques as well as the topology of the Basque cluster on genetic maps. The analysis of relationships among the genetic structures of Basque population samples leads us to ask ourselves which of them fits in best with the ancient Basque population. Classical geographers placed the tribe of the Vascones in the geographical region currently known as Navarre, so extant Navarrese Basques might be considered firm candidates to denote the anthropological and genomic distinctiveness of the ancient Basques.