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.     

Molecular-genetic analysis of VNTR polymorphism in alleles of the phenylalanine hydroxylase gene in inhabitants of the Volga-Urals region

Molecular genetic analysis of the VNTR alleles at the phenylalanine hydroxylase (PAH) gene was carried out in seven Volga-Ural ethnic groups (Bashkirs, Tatars, Chuvashes, Maris, Mordovians, Udmurts, and Komis). The PCR fragments revealed included alleles of 380, 440, 470, 500, 530, 560, and 650 bp, containing 3, 5, 6, 7, 8, 9, and 12 repeat copies, respectively. Substantial heterogeneity of the populations in respect to the distribution and frequency of the VNTR alleles and genotypes was demonstrated. The indices of observed and theoretical heterozygosity of the PAH VNTR alleles were calculated. The mean heterozygosity index was 70.02%. This high index value along with the established differentiation of the populations in respect to the frequency distribution of the VNTR alleles and PAH genotypes permitted the conclusion that the given polymorphic locus can serve as a highly informative marker for examination of the genetic structure of the Volga-Ural populations.     

Population-genetic structure of Chuvashia (from data on eight DNA loci in the nuclear genome)

Population-genetic study of indigenous populations representing three ethnic Chuvash group: highland (Cheboksarsk and Morgaush district), lowland (Kanash district) and mid-lowland (Marposad district). Eight polymorphic DNA loci of the nuclear genome (VNTR/PAH, STR/PAH, VNTR/ApoB, VNTR/DAT1, APF, VNTR/eNOS, IVS6aGATT, and KM.19/PstI) were examined in the population of each district. For each of the four population, we estimated the allele and genotype frequency distributions at each polymorphic system, heterozygosities HS and between-population differences FST. In the combined Chuvash sample, HS = 0.464 and FST = 0.006. Loci VNTR(DAT) and VNTR(ApoB) showed highest between-population differentiation (0.009 < or = FST < or = 0.012), and loci IVS6aGATT, APF, VNTR/eNOS, and D7S23 (KM.19), lowest differentiation (0.001 < or = FST < or = 0.003). Analysis of genetic distances revealed somewhat higher genetic similarity between the Cheboksarsk and Morgaush populations belonging to the highland Chuvash group, whereas the highland Chuvash population from the Marposad district, which belong to the mid-lowland group, was more distant from the former populations.     

Genetic structure of people from the Volga-Ural region and Central Asia from data of Alu-polymorphism

Nine Alu 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 (Fst = 0.061) was higher than for the populations of Central Asia (Fst = 0.024), Europe (Fst = 0.02), and Southeastern Asia (Fst = 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.     

"Synthetic" maps of the Mari gene pool (from immunobiochemical polymorphism data)]

Models of geographic distribution of 33 alleles of 10 loci (AB0, TF, GC, PI, HP, AHS, F13B, ACP1, PGM1, GLO1) in the indigenous population of five raions (districts) of Marii El Republic were analyzed by cartographic statistical methods. Based on 33 maps for individual alleles, synthetic maps were constructed; they reflected the general characteristics of the spatial variability of the Mari gene pool. A map of reliability of the synthetic maps was also obtained. This study was the first to use estimates of the reliability of the gene-geographic prognosis for constructing and interpreting the maps of principal components. Synthetic maps of principal components reveal the geography of the main factors that determine the genetic diversity of the Maris. In the map of the first principal component (accounting for 25.5% of the total variation of the Mari gene pool), isolines clearly ran in the latitudinal direction; i.e., the variability exhibited a north-south gradient. The direction of changes reflects the characteristic features of the microevolution of the Mari gene pool, because it differs from the direction of the principal components of in the total Ural gene pool. The second principal component (24.3% of variation) also exhibited a latitudinal gradient in the western part of Marii El. In the eastern part of the republic, isolines drastically change their direction and display a marked west-east gradient. This longitudinal orientation of principal components is characteristic of the Maris in the synthetic maps of the Ural region. Contributions of individual genes in the variation of principal components were analyzed. In proceeding from the geographic space to the space of principal components, it was found that Highland Maris are separated from Meadow Maris not only geographically, but also genetically.     

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.     

Population study of the Udmurt population: Analysis of ten polymorphic DNA loci of the nuclear genome

Genetic structure of Southern and Northern ethnographic groups of the Udmurt population from six regions of the Republic of Udmurtia has been studied. All the samples were examined using ten polymorphic DNA loci: VNTR/PAH, VNTR/ApoB, VNTR/DATI, VNTR/eNOS, ACE, CCR5 Δ32, KM19, IVS6a, THOI, and FABP2. Allelic and genotype frequencies were estimated for each of the six populations. The average heterozygosity for these ten polymorphic loci varied from 0.47 in Udmurts from Glazovskii region to 0.53 in Udmurts from Malopurginskii region. The level of genetic variation (F _ST) between populations of Udmurts was 0.0048. Ethnographic subdivision of the population into Northern and Southern Udmurts is in good agreement with the values of genetic distances and phylogenetic analysis.     

Genogenography of the aboriginal population of Marii El (from data on immunobiochemical polymorphism)

The geographic distribution of the frequencies of genes related to the immunological and biochemical polymorphism was studied in the Maris, who are the indigenous population of the Marii El Republic. Data on the frequencies of 33 alleles of 10 loci (ABO, TF, GC, PI, HP, AHS, F13B, ACP1, PGM1, and GLO1) in five raions (districts) of Marii El were obtained. Computer interpolation maps were constructed for all alleles. The maps allows to predict the distribution of the alleles throughout Marii El. A map of the reliability of the cartographic prediction was drawn. For the first time, the reliability of predicted gene frequencies were taken into account in constructing and interpreting the maps of gene frequencies. For the entire set of the studied genes, parameters of heterozygosity (HS) and gene diversity (GST) were estimated. Cartographic correlation analysis was performed to reveal the relationship between gene frequencies and geographic coordinates. It was found that 42% of the studied genes predominantly correlated with latitude and 9% with longitude. It was assumed that the genetic structure of Mari populations had been mainly determined by latitude-related factors. A map of Nei's genetic distances between the overall Mari gene pool and the local populations revealed a central core, which was close to the "average Mari" gene pool, and a periphery, which was genetically distant from it. Suggestions on the microevolution of the Mari gene pool were advanced. Maps of the genes with the most characteristic genetic relief (ABO*B, ACP*A, TF*D, GC*1F, PI*M2, HP*1F, and F13B*3) are shown. These maps exhibit a high correlation with the maps of principal components.     

Genetic polymorphism study at four minisatellite loci (D1S80, D17S5, D19S20, and APOB) among five Indian population groups

The present study reports the genetic variation observed among five anthropologically distinct population groups of India, using four highly polymorphic minisatellite loci (D1S80, D17S5, D19S20, and APOB 3' VNTR) in order to examine the effect of geographical and linguistic affiliations on the genetic affinities among these groups. Random individuals from five ethnic groups were studied; the sample size ranged from 235 to 364. The population groups belong to two geographically separated regions of India, the state of Maharashtra (western India) and the state of Kerala (southern India). The two Maharashtrian groups (Konkanastha Brahmins and Marathas) speak "Marathi," an Indo-European language, whereas the three Kerala population groups (Nairs, Ezhavas, and Muslims) speak "Malayalam," an Indo-Dravidian language. Genomic DNA was extracted from peripheral blood samples and analyzed using amplified fragment length polymorphism (Amp-FLP) technique. All four loci displayed high heterozygosity with average heterozygosity in the range of 0.82 to 0.84. The Polymorphic Information Content and Power of Discrimination were > or = 0.75 and > or = 0.80, respectively. The coefficient of gene differentiation was found to be low (average G(ST) = 1.2%; range between 0.6% at D1S80 locus to 1.6% at APOB 3' VNTR locus) across the loci, indicating close affinity among the population groups. The neighbor-joining tree revealed two clear clusters, one for the two Maharashtrian population groups and the other for the three Kerala population groups. The results obtained are in conformity with the geographical and linguistic backgrounds of the studied populations.     

Genetic variation among four Mexican populations (Huichol, Purepecha, Tarahumara, and Mestizo) revealed by two VNTRs and four STRs

Allele distributions of two polymorphisms with variable number of tandem repeats (VNTR), D1S80 and APOB, and four polymorphisms with short tandem repeats (STR), VWA, TH01, CSF1PO, and HPRTB, were analyzed in three Mexican ethnic groups: Huichol, Purepecha, and Tarahumara. Genotype distribution was in agreement with Hardy-Weinberg expectations for each locus and ethnic group. Heterozygosity (H), power of discrimination, and probability of exclusion were estimated. The three groups presented some distinctive genetic features: (1) a diminished genetic diversity (H = 66.8% to 73.4%) and mean number of alleles by locus (5.8 to 6.3) in comparison with Mexican mestizos (H = 78.3%, 10.5 alleles/locus), and (2) uneven allele distributions as evidenced by "distinctive alleles" with high frequencies, especially in the Tarahumara and the Huichol. Genetic relatedness analysis included data from a previously typed mestizo population, the largest and most widely distributed population in Mexico. Allele distribution differentiation was observed among all four groups, except between mestizo and Purepecha (p > 0.05), which was interpreted as indicating a larger Spanish component in the Purepecha as a result of gene flow effects. Although intrapopulation inbreeding (FIS) was not significant, heterozygote deficiency in the total population (FIT) and divergence among populations (FST) were significant (p < 0.05). Genetic distances displayed a closer relationship among mestizos, Purepechas, and Huichols in relation to Tarahumaras. Correlation between the observed genetic features and the geographic isolation level points to genetic drift as the main cause of differentiation among these Mexican populations.     

Restriction polymorphism of the major non-decoding region of mitochondrial DNA in human populations from the Volga-Ural region]

The restriction fragment length polymorphism (RFLP) of the major noncoding region of mitochondrial DNA (mtDNA) was studied in the Bashkir (N = 217), Tatar (N = 57), Chuvash (N = 44), Mari (N = 52), Mordovian (N = 55), Udmurt (N = 62), and Komi (N = 45) populations. Of seven polymorphic AvaII, BamHI, EcoRV, KpnI, and RsaI restriction sites, five were found in Bashkirs and Tatars, and four were found in each of the other populations. In total, 13 mitotypes were detected, and only three of them were common to all populations from the Volga-Ural region. The parameters of gene diversity were calculated with respect to the polymorphic sites and mitotypes. Comparison with published data revealed both Mongoloid and Caucasoid components in the gene pool of the modern populations from the Volga-Ural region. The Mongoloid component was prevalent in the mitochondrial gene pool, which is consistent with historical, anthropological, and ethnographic data.     

A study of polymorphism of the D2 dopamine receptor gene in the population of the Volga-Ural Region

Using polymerase chain reaction (PCR), TaqI polymorphism for the D2 dopamine receptor gene (DRD2) was studied in eight populations of the Volga-Ural region that belong to the Turkic (Bashkirs, Tatars, and Chuvashes), Finno-Ugric (Maris, Komis, Mordvinians, and Udmurts), and Eastern-Slavonic (Russians) ethnic groups. Significant differences in the distribution of genotype frequencies were found between the Tatar population belonging to the Turkic branch of the Altaic linguistic family and the Mari and Mordvinian populations belonging to the Finno-Ugric branch of the Ural family and between the Tatar and Bashkir populations belonging to the Turkic ethnic group.     

Genetic analysis of the Utah population: a comparison of STR and VNTR loci

Genetic data are reported for nine short tandem repeat (STR) loci (D3S1358, vWA, FGA, D8S1179, D21S11, D18S51, D5S818, D13S317, and D7S820) and six variable number of tandem repeat (VNTR) loci (D2S44, D10S28, D4S139, D1S7, D5S110, and D17S79) in samples of Utah African Americans, European Americans, and Hispanics. Little evidence of departures from Hardy-Weinberg equilibrium or gametic equilibrium was found in these populations. Because of their relatively higher mutation rates, the VNTR loci exhibited higher average heterozygosity and lower FST levels than did the STR loci. Genetic distance analysis showed congruence between the two types of systems, and a genetic distance analysis of the STR data showed that the three Utah populations are genetically similar to the same ethnic groups in other parts of the United States. In addition, this analysis showed that the African American population is the most genetically divergent, with greater similarity between the Hispanic and European American populations. This analysis demonstrates a high degree of consistency for population designations commonly used in forensic analysis.     

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).     

Analysis of the genetic differentiation of Bashkirs and peoples from the Volgo-Ural region from data on polymorphic markers of the nuclear genome]

Nei's coefficient of genetic differentiation (Gst) was used to estimate the intergroup differentiation of four ethnic geographic groups of Bashkirs and the interethnic differentiation of seven ethnoses (Bashkirs, Tatars, Chuvashes, Udmurts, Maris, Komis, and Mordovians) from the Volga-Ural region. The coefficient of genetic differentiation calculated from data on four polymorphic loci (MET, D7S23, PKU, and apoB) and classical biochemical markers (AB0, MN, Rh, Hp, and AcP) of the nuclear genome was similar in all tested populations. The genetic difference between the ethnoses from the Volga-Ural region (Gst = 1.91%) was intermediate between that in European (Gst = 1.18%) and Siberian (Gst = 5.84%) ethnoses.     

Burden of hereditary diseases in residents of the Mari El Republic]

A summary of the medical genetic studies of the Marii El population is presented. A total of 276,900 people, 110,894 and 166,006 urban and rural inhabitants, respectively, were examined. Regarding the ethnic composition, the studied population was mostly Mari (61.96%) and Russian (32.04%). Medical genetic examination revealed 480 subjects from 260 families with autosomal dominant (AD) diseases, 234 subjects from 184 families with autosomal recessive (AR) diseases, and 49 subjects from 41 families with x-linked diseases. Segregation analysis revealed a good agreement between the expected and observed segregation frequencies for families with AR and AD diseases and allowed the frequency of hereditary diseases in the urban and rural, as well as the Russian and Mari, populations, to be estimated. The total frequency of AD diseases in Maris was approximately twice as high as in Russians (1.99 and 0.97%, respectively); substantial differences between district populations were found. The total frequency of AR diseases was also two times higher in Maris than in Russians (1.00 and 0.54%, respectively). The frequencies of AR and AD diseases in different districts were correlated with the levels of random and local inbreeding, population size, and the index of maximum selection.     

Assessment of population differentiation using DNA fingerprinting and modified Wright's Fst-statistics

Using our results and literature data on multilocus DNA fingerprinting, we propose a method of obtaining unbiased estimates of the between--population genetic similarity index and a measure of population subdivision based on modified Wright's FST-statistics. On the basis of multiple comparison T2 Hotelling's test and Holmes' procedure, the FST-statistics was applied to assess differentiation of four (Pacific and Atlantic) subpopulations of humpback whale Megaptera novaeangliae, six populations of California island gray fox Urocyon littoralis, and geographically isolated Ob' and Yakutia populations of Siberian white crane Crus leucogeranus. It was shown that the regional humpback whale subpopulations do not constitute a single panmictic unit (P < 10(-4)). The subdivision index of the Pacific and Atlantic populations expressed in terms of FST-statistics varied from 0.101 to 0.157. The differentiation estimates for the island fox populations, which ranged from 0.2109 to 0.4027, indicate that subdivision of these populations is a function of the distance between the islands, island size, and population size. In particular, the smallest and the greatest differences were found respectively between the populations of the geographically closest northern islands (FST = 0.2157, FST = 0.2109) and between those of the most distant northern and southern islands (FST = 0.4027, FST = 0.3869). Subdivision of the island populations with minimum areas and low population number was intermediate (FST = 0.3789). Mean values of heterozygosity, within-population genetic similarity index, and the number of coinciding fragments for two random individuals of Siberian white crane from the Ob' and Yakutia population were not statistically significantly different (P > or = 0.852, (P > or = 0.491, (P > or = 0.325). However, pairwise comparisons of mean FST values indicated that the differentiation estimates for samples from these populations fall within the limits of population subdivision (P = 0.01). The subdivision estimate (0.108-0.133) of various groups of Siberian white cranes is comparable to interregional subdivision of humpback whale. Based on the results of this study, we recommend the approach based on modified Wright's FST-statistics for studying genetic population structure aimed at detecting population subdivision.     

中国14个民族红细胞血型座位的遗传分化

根据中国13个人口逾百万的民族及台湾高山族的红细胞血型座位的基因频率,分析了各血型系统的分化程度。结果表明,中国人群在MNSs系统上的分化十分显著。对各民族间的亲缘关系分析表明,汉族、朝鲜族、蒙古族、回族,满族和藏族等北方民族首先聚集在一起,侗族、高山族、壮族和彝族等聚集在一起,然后白族与南北两大人集聚集在一起,最后才是维吾尔族与其它人群相聚。本文以华北汉族作为蒙古人种的代表,探讨了世界上三大人种间的遗传关系,结果表明,黄种人与黑种人之间的遗传差异最小,而黑种人与白种人之间的遗传差异最大。根据基因分化系数(G_(ST))和Shannon信息测度(H),中国民族间的遗传差异均仅占中国人总遗传变异量的2％左右,这说明,绝大部分遗传变异存在于各民族之内。     

Genetic diversity of the Khakass gene pool: Subethnic differentiation and the structure of Y-chromosome haplogroups

The structure of Khakass gene pool has been investigated: Y-chromosome haplogroup compositions and frequencies were described in seven population samples of two basic subethnic groups, Sagai and Kachins, from three geographically separated regions of the Khakass Republic. Eight haplogroups were detected in the Khakass gene pool: C3, E, N*, N1b, N1c, R1a1a, and R1b1b1. The haplogroup spectra and the genetic diversity by haplogroups and YSTR haplotypes differed significantly between Sagai and Kachins. Kachins had a low level of gene diversity, whereas the diversity of Sagai was similar to that of other South-Siberian ethnic groups. Sagai samples from the Askizskii district were very similar to each other, and so were two Kachin samples from the Shirinskii district, while Sagai samples from the Tashtypskii district differed considerably from each other. The contribution of intergroup differences among ethnic groups was high, indicating significant genetic differentiation among native populations in Khakassia. The Khakass gene pool was strongly differentiated both by haplogroup frequencies and by YSTR haplotypes within the N1b haplogroup. The frequencies of YSTR haplotypes within the chromosome Y haplogroups N1b, N1c, and R1a1 were determined and their molecular phylogeny was investigated. Factor and cluster analysis, as well as AMOVA, suggest that the Khakass gene pool is structured by territory and subethnic groups.     

An anthropobiological study in Basse Kotto (Central Africa). I. Erythrocyte and sero-genetic markers: an analysis of the genetic differentiation

Phenotype and allele frequencies for hemoglobin types (Hb beta), acid phosphatase (AcP), phosphoglucomutase (PGM1 and PGM2), esterase D (EsD), 6-phosphogluconate dehydrogenase (6-PGD), glyoxalase I (GLO), superoxide dismutase (SOD A), and adenylate kinase (AK) as well as for haptoglobins (Hp), group-specific component (Gc), transferrin (Tf), Gm, and Inv groups and albumin, are reported in the Mbugu, Sango, Yakpa, and Baya Mandja ethnic groups in the Basse Kotto district of the Central African Republic. The total sample size amounts to 133 males and 128 females aged from 16 to 60, unrelated and healthy. A new albumin variant (albumin Mbugu) is described and discussed. The average heterozygosity is high in each group because of a high degree of exogamy. the FST average standardized value among the four groups indicates that the genetic differentiation in Basse Kotto is at level of about 2%. This indicates that the four examined groups might be considered genetically homogeneous, in spite of their different ethnic origins. The genetic distances among the four groups show that only the Baya Mandja are less closely related to the other three groups because of their foreign origin.