Genetic polymorphism of blood group and erythrocyte enzymes in three ethno-territorial groups of the northern European part of Russia]

Using the data on five red cell markers (AB0, PGM1, ACP1, GLO1, and ESD) polymorphisms, the population genetic structure of three ethnic territorial groups from the north of European Russia (Continental Nentsy, Kola Saami, and Russian Coast-dwellers) was described. In general, the groups studied a Caucasoid pattern of the frequency distribution of erythrocytic marker alleles. However, a substantial contribution of a Mongoloid component to the Nenets gene pool, expressed as a high frequency of the PGM1*1 allele along with a low frequency of the GLO1*1 allele, was observed. Three ethnic territorial groups examined were close to one another with respect to the distribution of classical biochemical markers. The interpopulation diversity was low (the mean FST = 0.015). The differences observed were for the most part caused by the genetic characteristics of Nentsy. The maximum interpopulation diversity was observed for the GLO1 locus (FST = 0.056).     

Genetic Predisposition to Alcoholic Toxic Cirrhosis

Comprehensive analysis of the contribution of genetic factors into predisposition to alcoholic toxic cirrhosis (TC) was performed. The AB0, 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 lociGC, ACP1, ESD, and GLO1.In the TC patients, the observed heterozygosity (H _o) 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). A considerable decrease in the ABO*0allele frequency at the expense of an increase in the ABO*Aallele frequencywas observed in the TC patients as compared to the control sample. The TF*C2allele frequencywas two times higher in the patients than in the control group (0.2571 and 0.1308, respectively). The frequencies ofPI*Zand PI*S, the PIalleles 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*0allele, whereas the GST1*2frequency 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, andGST1*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 red cell-enzyme phenotypes (ACP1, PGM1, and GLO1) in both TC and control groups.     

Population structure of Volga Tatars inferred from the mitochondrial DNA diversity data

The data on mitochondrial DNA (mtDNA) variation in two populations of Volga Tatars, representing the population of Buinsk and Aznakaevo districts of the Republic of Tatarstan are presented. Comparative analysis of the data on mtDNA variation in the populations of Eastern Europe showed that Volga Tatars were characterized by low interpopulation differentiation (F _ST = 0.33%), while the level of interethnic differentiation in Eastern Europe is 1.8%. Genetic similarity of Tatars from the eastern regions of Tatarstan to Bashkirs, as well as of Tatars from western regions to Chuvashes, with whom they share territorial borders, was revealed. Positive correlation between population genetic structure in Eastern Europe and linguistic affiliation of the ethnic groups studied was observed.     

Genetic variation and population structure of interleukin genes among seven ethnic populations from Karnataka,India

The extent of genetic variation and the degree of genetic differentiation among seven ethnic populations from Karnataka, India (Bunt, Havyak, Iyengar, Lingayath, Smartha, Vaishya, Vokkaliga), was investigated using four single nucleotide polymorphisms (SNPs: IL-1A 4845, IL-1B 3954, IL-1B 511 and IL-1RA 2018) of the interleukin gene cluster. Allele frequencies varied by threefold among these populations, which also differed for gene diversity and heterozygosity levels. The average degree of population subdivision among these castes was low (F _ST = 0.02). However, pair-wise interpopulation differentiation ranged from 0–7%, indicating no detectable differentiation to moderate differentiation between specific populations. The results of phylogenetic analysis based on genetic distances between populations agreed with known social and cultural data on these ethnic groups. Variation in the allele frequencies, as well as differentiation, may be attributed to differential selection and demographic factors including consanguinity among the ethnic groups. Information on the distribution of functionally relevant polymorphisms among ethnic populations may be important towards developing community medicine and public health policies.     

The Russian gene pool. Genogeography of erythrocyte genetic markers (ACP1, PGM1, ESD, GLO1, 6-PGD)

The study continues the series of works on the Russian gene pool. Gene geographic analysis of five erythrocytic gene markers best studied in the Russian population (ACP1, PGM1, ESD, GLO1, and 6-PGD) has been performed. Gene-geographic electronic maps have been constructed for 13 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 eight alleles (ACP1*A, ACP1*C, PGM1*2+, PGM1*2-, PGM1*1-, ESD*1, GLO1*1, and PGD*C) 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 Dagestan gene pool: Polymorphism of immunogenetic and biochemical markers in Kumyks

This study is a part of long-term investigations devoted to the analysis of the gene pool of Dagestan ethnic groups. The phenotype (in %), gene, and haplotype frequencies in Kumyk ethnic group are reported. A total of 39 alleles and six haplotypes of 14 loci (AB0, Rhesus, P, Levis, Kell, HP, GC, C’3, TF, 6PGD, GLO1, ESD, ACP, and PGM1) of immunobiochemical genetic marker systems were examined. Rare haplotypes of the Rhesus system were identified, including CDE in the Karabudakhkent population with the frequency of 0.030, and Cde and cdE in the Dorgeli population with the frequencies of 0.034 and 0.38, respectively. Similarly to the other ethnic populations of Dagestan examined, Kukyk populations carried rare, albeit typically “Caucasoid” gene ACP1 ^c of the AcP1 locus. The frequency of this allele in the two populations was similar, constituting 0.031 for Karabudakhkent and 0.032 for Dorgeli. In Kumyks, allele frequencies of the AB0, Rhesus, P, Lewis, Kell, HP, GC, C′3, TF, 6PGD, GLO1, ESD, ACP, but not PGM1, systems were similar to the mean allele frequencies at these loci observed in the other ethnic groups from the Dagestan, Caucasus, and the whole European historical ethnographic province. At the same time, the allele frequency values obtained were different from those for the populations of Kazakhstan, Central Asia, Siberia, and the Ruswsian Far East. Thus, the results obtained for classical genetic markers indicate that Kumyks are genetically closer to the indigenous populations of Dagestan than to Turkic-speaking populations. Analysis of the fit of the observed phenotype frequencies to the Hardy-Weinberg expectations showed that compared to other indigenous populations of Dagestan examined, in Kumyks the genetic state of the population upon random allele association was close to equilibrium. Probably, this state was determined by practical absence of the consanguineous marriages upon preservation of intra-aul endogamy.     

Genetic Structure of the Volga–Ural and Central Asian Populations Inferred from the Data on Alu Polymorphism

NineAlu loci (Ya5NBC5, Ya5NBC27, Ya5NBC148, Ya5NBC182, YA5NBC361, ACE, ApoA1, PV92, TPA25) were analyzed in six ethnic populations (Trans-Ural Bashkirs, Tatars-Mishars, Mordovians-Moksha, Mountain Maris, Udmurts, and Komi-Permyaks) of the Volga–Ural region and in three Central Asian populations (Uzbeks, Kazakhs, and Uigurs). All Alu insertions analyzed appeared to be polymorphic in all populations examined. The frequency of insertion varied from 0.110 in Mountain Maris at the Ya5NBC5 locus to 0.914 in Tatars at the ApoA1 locus. The data on the allele frequency distribution at nine loci point to the existence of substantial genetic diversity in the populations examined. The value of the observed heterozygosity averaged over nine Alu insertions varied from 0.326 in Mountain Maris to 0.445 in Kazakhs and Uigurs. The level of the interpopulation genetic differences for the Volga–Ural population (F _st = 0.061) was higher than for the populations of Central Asia (F _st = 0.024), Europe (F _st = 0.02), and Southeastern Asia (F _st = 0.018). The populations examined were highly differentiated both in respect of linguistic characteristics and the geographical position. The data obtained confirmed the effectiveness of the marker system used for the assessment of genetic differentiation and the relationships between the ethnic groups.     

Statistical power for detecting genetic divergence—organelle versus nuclear markers

Statistical power is critical in conservation for detecting genetic differences in space or time from allele frequency data. Organelle and nuclear genetic markers have fundamentally different transmission dynamics; the potential effect of these differences on power to detect divergence have been speculated on but not investigated. We examine, analytically and with computer simulations, the relative performance of organelle and nuclear markers under basic, ideal situations. We conclude that claims of a generally higher resolving power of either marker type are not correct. The ratio R = F _ST,organelle/F _ST,nuclear varies between 1 and 4 during differentiation and this greatly affects the power relationship. When nuclear F _ST is associated with organelle differentiation four times higher, the power of the organelle marker is similar to two nuclear loci with the same allele frequency distribution. With large sample sizes (n ≥ 50) and several populations or many alleles per locus (≥5), the power difference may typically be disregarded when nuclear F _ST > 0.05. To correctly interpret observed patterns of genetic differentiation in practical situations, the expected F _STs and the statistical properties (i.e., power analysis) of the genetic markers used should be evaluated, taking the observed allele frequency distributions into consideration.     

Separating Effects of Gene Flow and Natural Selection along an Environmental Gradient

Genetic differentiation along environmental clines is often observed as a result of interplay between gene flow and natural selection. In order to understand the relative roles of these processes in shaping this differentiation, we designed a study in which we used two approaches that have not previously been combined, the Q _ST–F _ST comparison and crossbreeding. We examined (1) interpopulation phenotypic and genetic (AFLP) variation, and (2) performance of interpopulation hybrids in a common annual Senecio glaucus. Fitness of interpopulation hybrids (F1 and F2) was tested under simulated population natural conditions in terms of aridity and analyzed for a relationship with (1) spatial distance and (2) environmental differences (amount of annual rainfall). While phenotypic variation corresponded to the clinal changes in aridity along population locations, viz. narrower and longer leaves, longer leaf outgrowths and advanced flowering in more arid environments, the F _ST < 0.1 calculated from AFLP data suggested intensive interpopulation gene flow, with little if any contribution of genetic drift. Performance of hybrids in simulated natural environments revealed heterosis in F1, but a hybrid breakdown in F2 generation. These effects were related to both the spatial distance between hybrid parents and their population rainfall differences. The detected clinal phenotypic variation and outbreeding depression in F2 strongly support presence of aridity-induced clinal natural selection, which is matched by the observed Q _ST ≫ F _ST. From this we conclude that Q _ST–F _ST comparison can detect effect of diversifying selection when patterns of phenotypic variation across sampled locations can be reliably predicted from environmental variation.     

Gene pool of Daghestan ethnic groups: Polymorphism of classical gene markers in the Darghin ethnic group

The work is part of a study of the gene pool for Daghestan ethnic groups. In total, 38 alleles and eight genotypes were studied at 14 loci (AB0, Rhesus, P, Lewis, Kell, PH, GC, C′3, TF, 6-PGD, GLO1, ESD, ACP, and PBM1) of immunogenetic and biochemical polymorphic gene systems. A high frequency of allele d of the Rhesus system was observed in all populations examined (0.399–0.474). Among the rare haplotypes of the Rhesus system, we observed CDE in the Degva population, Cde in the Sergokala and Degva populations, and cdE in the Sergokala and Vanashimakhi populations. The typical Caucasian ACP1 ^c allele of the ACP1 locus, which is rather uncommon, was observed at a relatively high frequency in three (Segokala, Vanashimakhi, and Gubden) of the four local populations under study. In the Lewis system, a high frequency of the Le(a+b+) phenotype, which is characteristic of early childhood, was detected in the adult populations of Sergokala and Degva. The rare PGM ₁ ^V allele of the phosphoglucomutase 1 system (PGM1) was additionally observed in the Sergokala population. Statistical analysis identified 19 cases where the observed phenotype frequencies significantly differed from the frequencies expected from the Hardy-Weinberg equilibrium.     

Empirical Distributions of F ST from Large-Scale Human Polymorphism Data

Studies of the apportionment of human genetic variation have long established that most human variation is within population groups and that the additional variation between population groups is small but greatest when comparing different continental populations. These studies often used Wright’s F _ST that apportions the standardized variance in allele frequencies within and between population groups. Because local adaptations increase population differentiation, high-F _ST may be found at closely linked loci under selection and used to identify genes undergoing directional or heterotic selection. We re-examined these processes using HapMap data. We analyzed 3 million SNPs on 602 samples from eight worldwide populations and a consensus subset of 1 million SNPs found in all populations. We identified four major features of the data: First, a hierarchically F _ST analysis showed that only a paucity (12%) of the total genetic variation is distributed between continental populations and even a lesser genetic variation (1%) is found between intra-continental populations. Second, the global F _ST distribution closely follows an exponential distribution. Third, although the overall F _ST distribution is similarly shaped (inverse J), F _ST distributions varies markedly by allele frequency when divided into non-overlapping groups by allele frequency range. Because the mean allele frequency is a crude indicator of allele age, these distributions mark the time-dependent change in genetic differentiation. Finally, the change in mean-F _ST of these groups is linear in allele frequency. These results suggest that investigating the extremes of the F _ST distribution for each allele frequency group is more efficient for detecting selection. Consequently, we demonstrate that such extreme SNPs are more clustered along the chromosomes than expected from linkage disequilibrium for each allele frequency group. These genomic regions are therefore likely candidates for natural selection.     

The Russian Gene Pool: Gene Geography of Erythrocytic Gene Markers (ACP1,PGM1,ESD,GLO1, and 6-PGD)

The study continues the series of works on the Russian gene pool. Gene geographic analysis of five erythrocytic gene markers best studied in the Russian population (ACP1, PGM1, ESD, GLO1, and6-PGD) has been performed. Gene-geographic electronic maps have been constructed for 13 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 eight alleles (ACP1*A, ACP1*C, PGM1*2+, PGM1*2–, PGM1*1–, ESD*1, GLO1*1, and PGD*C) 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.     

Analysis of the VNTR Polymorphism at the PAH and eNOS Genes and the CCR5 Gene Deletion in Populations of Northern Caucasus

VNTR allelic polymorphism at the phenylalanine hydroxilase (PAH) and endothelial constitutive nitric oxide synthase (eNOS) genes and the prevalence of the CCR5 chemokine receptor gene 32-bp deletion were examined in four populations of Northern Caucasus: Adygs, Kumyks, Karachais, and Nogais (Kuban and Karanogais). Population-specific features of the allele and genotype frequency distribution patterns of the polymorphisms examined were described. The data obtained were compared to those obtained from literature. The results of the study confirmed that the frequency and occurrence of the PAH polymorphic alleles exhibit substantial interpopulation differences. In the populations of Northern Caucasus, the eNOS minisatellite polymorphism alleles and genotypes frequency distribution patterns were close to those described earlier for populations of the Volga–Ural region (VUR), and also for the Australian Caucasoids, Japanese, and Turks. In the populations examined, the mean frequency of the CCR5 gene deletion was 0.055, which was somewhat lower than in the populations of VUR (0.070) and Europe (0.081), and practically identical to that in Asian populations (0.050). For each population observed and expected heterozygosities at each locus were calculated. In general, the gene pool of Northern Caucasian populations showed substantial differentiation at the loci examined: the G _ST value was 0.0274. The data for individual loci showed that the greater contribution to the interpopulation diversity was made by the differences in the PAH VNTR allele frequencies (G _ST = 0.04), while the differences at the eNOSand CCR5 loci were small (G _ST = 0.0025 and G _ST = 0.0039, respectively).     

Genetic Polymorphism of Erythrocytic Enzymes in Yakut Populations

Polymorphism of the erythrocytic enzymes PGM1, ACP1, ESD, and GLO1 was found in Yakut populations. The allelic frequencies of the polymorphic systems studied varied within the following ranges: PGM1*1+, 0.5833–0.7791; PGM1*1–, 0.0345–0.1176; PGM1*2+, 0.1250–0.2813; ACP1*A, 0.1429–0.3382; ACP1*B, 0.6548–0.8571; ESD*2, 0.1250–0.4643; and GLO1*1, 0.0116–0.2845.     

Analysis of polymorphism at nine nuclear genome DNA loci in Maris

Population genetic survey of the indigenous populations of the Marii El Republic, represented by the two major ethnographic groups of Maris, Meadow (five samples from Morkinsk, Orshansk, Sernursk, Sovetsk, and Zvenigovsk districts) and Mountain (one sample from Gornomariisk district) Maris, was carried out. All Mari groups were examined at nine polymorphic DNA loci of nuclear genome, VNTR(PAH) (N=422), STR(PAH) (N=152), VNTR(ApoB) (N=294), VNTR(DAT1) (N=363), VNTR(eNOS) (N=373), ACE (N=412), IVS6aGATT (N=513), D7S23(KM.19) (N=494), and D7S8 (N=366). Allele and genotype frequency distribution patterns were obtained for individual samples and ethnographic groups, as well as for the ethnic group overall. In each of six Mari samples examined, the deficit of heterozygotes was observed, i.e., the mean observed heterozygosity was lower than the expected one. The indices of mean heterozygosity, $\bar H_S = 0.455$ , and interpopulation differentiation, $\bar F_{ST} = 0.0024$ , for the Mari gene pool were obtained using a set of DNA markers analyzed. The highest level of interpopulation differentiation is characteristic of ACE loci (F _ST=0.0104) and D7S23(KM.19/PstI) (F _ST=0.0123). Analysis of the genetic distances and interpopulation differentiation (F _ST) showed that the main part of genetic diversity in Maris was determined by the differentiation between the populations of Meadow Maris. The contribution of the differences between the ethnographic groups of Mountain and Meadow Maris to the ethnic gene pool was small. It is suggested that the main role in the formation of the Mari gene pool is played by the geographic factor.     

Allelic polymorphism of six microsatellite DNA Loci in populations of Sakha (Yakutia)

The allele frequency distributions of six STR loci (D3S1358, D16S539, THOI, D8S1179, LPL, and HUMvWFII) used in forensic practice were analyzed in populations of Sakha (Yakutia): three ethnogeographical groups of Sakha (Yakuts), Evenks, Yukagirs, Dolgans, and Russians. There were significant differences between Russians and all other populations by five markers. The total discriminating power (PD) of the locus system studied was assessed for each population. The interpopulation genetic difference (F _ST) was 0.005. Data on the allelic polymorphism of the above STR loci were used to analyze phylogenetic relationships among the populations of Sakha and those of other regions: East Europe, South Siberia, Chukotka, and Kamchatka.     

Genetic population structure of two African-Ecuadorian communities of Esmeraldas

The genetic structure of two African-Ecuadorian communities, Rio Cayapas and Viche (Esmeraldas province, northwest Ecuador), was studied on the basis of ACP1, ADA, AK1, CA2, ESD, GLO1, G6PD, PGD, and PGM1 subtypes and thermostability, PGM2, HBβ, F13A, F13B, ORM1, AHSG, C6, C7, and APOC2 gene frequency, and migration data on 255 individuals. The fixation index of Wright (F_ST), correspondence, and genetic distance analysis were applied to compare the genetic relationships between these communities and other American populations of African ancestry. F_ST values from the migration data and surname origins suggest that Rio Cayapas is genetically more isolated and shows less mobility and admixture than does Viche. The genetic admixture estimates indicate a large contribution of African genes to the gene pool of both communities (74.3% to 58.4%), whereas the proportion of the Amerindian component differs significantly (14.5% in Rio Cayapas to 27.6% in Viche). Am J Phys Anthropol 109:159–174, 1999.© 1999 Wiley-Liss, Inc.     

Polymorphism of immunogenetic and biochemical markers in Siberian (Tobol-Irtysh) Tatars

The polymorphism of immunogenetic and biochemical markers has been studied in nine populations of five ethnic-geographic groups of Siberian (Tobol-Irtysh) Tatars. Data on the frequency distributions of 33 alleles and 6 haplotypes of 14 loci (ABO, RHD, RHC, RHE, P, KEL, HP, C′3, TF, GLO1, ESD, ACP, PGD, and PGM1) in sample of 354 subjects have been obtained. Comparison with other ethnic groups has shown that the gene pool of Tobol-Irtysh Tatars contains an ancient autochthonic genetic stratum similar to that found in the neighboring Ob’ Ugrian population. Genetic relationships of various strengths with Central Asian Turks and the ethnic groups of the Volga region have been found, which apparently reflect different stages of the ethnogenesis of the Tobol-Irtysh Tatars.     

Genetic variation at the MHC DRB1 locus is similar across Gunnison's prairie dog (Cynomys gunnisoni) colonies regardless of plague history

Yersinia pestis was introduced to North America around 1900 and leads to nearly 100% mortality in prairie dog (Cynomys spp.) colonies during epizootic events, which suggests this pathogen may exert a strong selective force. We characterized genetic diversity at an MHC class II locus (DRB1) in Gunnison's prairie dog (C. gunnisoni) and quantified population genetic structure at the DRB1 versus 12 microsatellite loci in three large Arizona colonies. Two colonies, Seligman (SE) and Espee Ranch (ES), have experienced multiple plague‐related die‐offs in recent years, whereas plague has never been documented at Aubrey Valley (AV). We found fairly low allelic diversity at the DRB1 locus, with one allele (DRB1*01) at high frequency (0.67–0.87) in all colonies. Two other DRB1 alleles appear to be trans‐species polymorphisms shared with the black‐tailed prairie dog (C. ludovicianus), indicating that these alleles have been maintained across evolutionary time frames. Estimates of genetic differentiation were generally lower at the MHC locus (F_ST = 0.033) than at microsatellite markers (F_ST = 0.098). The reduced differentiation at DRB1 may indicate that selection has been important for shaping variation at MHC loci, regardless of the presence or absence of plague in recent decades. However, genetic drift has probably also influenced the DRB1 locus because its level of differentiation was not different from that of microsatellites in an F_ST outlier analysis. We then compared specific MHC alleles to plague survivorship in 60 C. gunnisoni that had been experimentally infected with Y. pestis. We found that survival was greater in individuals that carried at least one copy of the most common allele (DRB1*01) compared to those that did not (60% vs. 20%). Although the sample sizes of these two groups were unbalanced, this result suggests the possibility that this MHC class II locus, or a nearby linked gene, could play a role in plague survival.     

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.