[Genetic diversity and relationships of northern eurasia populations for polymorphic Alu-insertions].

We for the first time have examined the autosomal gene pool of the Siberia, Central Asian and the Far East populations (27 populations of 12 ethnic groups) using a set of polymorphic Alu insertions in the human genome. The results of the analysis testify (i) to a significant level of genetic diversity in the Northern Eurasian populations and (ii) to a considerable differentiation of gene pool in the population of this region. It has been shown that at the CD4 locus, the frequency of Alu (-) is inversely related to the Mongoloid component of the population, the lowest and highest frequencies of the Alu deletion at locus CD4 were recorded respectively in Eskimo (0.012) and Russian and Ukrainian (0.35). The analysis of gene flow proved Caucasoid populations (Russian, Tajik and Uzbek), as well as those of Turkic ethnic groups from the Southern Siberia (Altaians and Tuvinians) and Khanty and Mansy populations to be the recipients of a considerable gene flow from the outside of the concerned population system, as compared with the East Siberian and the Far East ethnic groups. The results of the correlation analysis received with use polymorphic Alu insertion testify to the greatest correlation of genetic distances with anthropological characteristics of populations.

[Genetic diversity of Khakassian gene pool: subethnic differensiation and the structure of Y-chromosome haplogroups,].

The structure of Khakass gene pool has been investigated: compositions and frequencies of Y-chromosome haplogroups were described in seven population samples of two basic subethnic groups--Sagays and Kachins from three territorially distanced regions of Khakassia Republic. Eight haplogroups: C3, E, N*, N1b, N1c, R1a1a and R1b1b1 have been determined in Khakass gene pool. Significant differences between Sagays and Kachins were shown in haplogroup spectra and a level of genetic diversity in haplogroups and YSTR-haplotypes. Kachin samples are characterized by a low value of gene diversity, whereas the level of Sagay diversity is similar to that of other South-Siberian ethnoses. Sagay samples from Askizsky region are very similar to each other just as two Kachin samples from Shirinsky region, while Sagay samples from Tashtypsky region greatly differ from each other. A great portion of intergroup differences was determined among different ethnic groups, which testifies to significant genetic differentiation of native populations in Khakassia. Khakass gene pool is greatly differentiated both in haplogroup frequencies and in YSTR-haplotypes within N1b haplogroup. Frequencies and molecular phylogenesis of YSTR-haplotypes were revealed within N1b, N1c and R1a1 haplogroups of Y-chromosome. We carried out comparative analysis of the data obtained. The results of factor, cluster and dispersion analyses are evidence of structuredness of Khakass gene pool according to territorial-subethnic principle.

[Skewed X-chromosome inactivation in human embryos with mosaic trisomy 16].

The sex ratio and X-chromosome inactivation were analyzed in placental tissues of human spontaneous abortuses with pure and mosaic forms of chromosome 16 trisomy. The sex ratio value was found to decrease with an increase in the share of cells with the trisomic karyotype, which suggests differential survival of embryos belonging to different sexes. The pattern of X-chromosome inactivation in cells of extraembryonic mesoderm in the control group of embryos and in spontaneous abortuses with the level of trisomy 16 below 80% corresponded to random X-inactivation, whereas in most embryos with a frequency of trisomy 16 exceeding 80% skewed inactivation was observed. Our results support the hypothesis about the existence of an autosomal transfactor influencing the initiation of X-chromosome inactivation and suggest its possible localization on chromosome 16.

Characteristics of Populations of the Russian Federation over the Panel of Fifteen Loci Used for DNA Identification and in Forensic Medical Examination.

Seventeen population groups within the Russian Federation were characterized for the first time using a panel of 15 genetic markers that are used for DNA identification and in forensic medical examinations. The degree of polymorphism and population diversity of microsatellite loci within the Power Plex system (Promega) in Russian populations; the distribution of alleles and genotypes within the populations of six cities and 11 ethnic groups of the Russian Federation; the levels of intra- and interpopulation genetic differentiation of population; genetic relations between populations; and the identification and forensic medical characteristics of the system of markers under study were determined. Significant differences were revealed between the Russian populations and the U.S. reference base that was used recently in the forensic medical examination of the RF. A database of the allelic frequencies of 15 microsatellite loci that are used for DNA identification and forensic medical examination was created; the database has the potential of becoming the reference for performing forensic medical examinations in Russia. The spatial organization of genetic diversity over the panel of the STR markers that are used for DNA identification was revealed. It represents the general regularities of geographical clusterization of human populations over various types of genetic markers. The necessity to take into account a population's genetic structure during forensic medical examinations and DNA identification of criminal suspects was substantiated.

[Genetic diversity of X-chromosome in populations of aboriginal Siberian ethnic groups: linkage disequilibrium structure and haplotype philogeography of ZFX locus].

The structure of gene pool of the Siberian aboriginal population has been described based on the data on polymorphism of ZFX gene located on X-chromosome. In ten populations under study 49 haplotypes have been determined, three of which are presented with high frequency. Comparing the obtained results with the available data from HapMap project unique "African" haplotypes were revealed, which occurred in Yoruba population with the frequency of 3-7% and were not found in other populations. A coefficient of genetic differentiation of the Siberian ethnic groups under study amounted to 0.0486. Correlation analysis involving Mantel test did not reveal any significant correlations between a matrix of genetic distances and the matrices of geographic, linguistic and anthropological differences, where a maximum coefficient was obtained at the comparison with the anthropological matrix. Phylogenetic analysis proved strong isolation of African population from the other investigated ethnic groups. The Siberian populations were subdivided into two separate clusters: the first one included Yakuts, Buryats and Kets, while the second cluster included Altaians, Tuvinians and Khanty. A principal component analysis enabled to combine the investigated populations in three groups, which clearly differed by a degree of manifestation of Caucasoid and Mongoloid components. The first group included Europe inhabitants and one of Khanty populations, the second one--populations of South Siberia and China inhabitants. Mongoloid populations of East Siberia, the Japanese and Kets were combined in the third group. The results of barrier analysis revealed similar structure of genetic differentiation in the Siberian population. Linkage disequilibrium structure was obtained for six ethnic groups of Siberia. A unified linkage block by ten SNP of ZFX gene was found in five of the presented ethnic groups (excluding Ket population).

[Comparative characteristics of the gene pool of Teleuts inferred from Y-chromosomal marker data].

The gene pool structure of Teleuts was examined and Y-chromosomal haplogroups composition and frequencies were determined. In the gene pool of Teleuts, five haplogroups, C3xM77, N3a, R1b*, R1b3, and R1a1, were identified. Evaluation of the genetic differentiation of the samples examined using analysis of molecular variance (AMOVA) with two marker systems (frequencies of haplogroups and Y-chromosomal microsatellite haplotypes) showed that Bachat Teleuts were equally distant from Southern and Northern Altaians. In Siberian populations, the frequencies and molecular phylogeny of the YSTR haplotypes within Y-chromosomal haplogroup R1a1 were examined. It was demonstrated that Teleuts and Southern Altaians had very close and overlapping profiles of R1a1 haplotypes. Population cluster analysis of the R1a1 YSTR haplotypes showed that Teleuts and Southern Altaians were closer to one another than to all remaining Siberian ethnic groups. Phylogenetic analysis of N3a haplotypes suggested specificity of Teleut haplotypes and their closeness to those of Tomsk Tatars. Teleuts were characterized by extremely high frequency of haplogroup R1b*, distinguished for highly specific profile of YSTR haplotypes and high haplotype diversity. The results of the comparative analysis suggested that the gene pool of Bachat Teleuts was formed on the basis of at least two heterogeneous genetic components, probably associated with ancient Turkic and Samoyedic ethnic components.

[The origin of Yakuts: analysis of Y-chromosome haplotypes].

Gene pool structure of Sakha Republic (Yakutia) native population has been studied: we defined composition and frequencies of Y-chromosome haplogroups for Yakuts. Six haplogroups: C3 x M77, C3c, N*, N2, N3a and R1a1 have been revealed in Yakut gene pool. A greater part of Y-chromosome in Yakut population belongs to N3a haplogroup (89%). All investigated Yakut population samples have low values of gene diversity, calculated based on haplogroup frequencies. Gene differentiation of the investigated samples estimated using the analysis of molecular variance (AMOVA) by two marker systems (haplogroup frequencies and microsatellite haplotypes of Y-chromosome) revealed a portion of interpopulation differences amounting to 0.24 and 2.85%, respectively. Frequencies and molecular phylogeny of YSTR-haplotypes were revealed for N3a haplogroup of Y-chromosome. Altogether forty haplotypes were found in Yakuts. Evenks and Yakuts are characterized by overlapping and very specific spectrum of N3a haplotypes, which is not typical for other Siberian ethnic groups. Cluster analysis of populations by N3a YSTR-haplotypes shows Yakut isolation from Turkic-speaking populations in the South Siberia. Genetic diversity generation time for a specific spectrum of Yakut haplotypes was estimated as 4.45 +/- 1.96 thousand years. As opposed to the data on mtDNA, the obtained results give an evidence for significant contribution of a local palaeolithic component into Y-chromosomal Yakut gene pool. Ethnogenetic reconstruction of the present picture of genetic diversity in N3a haplogroup in the territory of Siberia is under consideration.

[Gene pool differences between northern and southern Altaians inferred from the data on Y-chromosomal haplogroups].

Y-chromosomal haplogroups composition and frequencies were analyzed in Northern and Southern Altaians. In the gene pool of Altaians a total of 18 Y-chromosomal haplogroups were identified, including C3xM77, C3c, DxM15, E, F*, J2, I1a, I1b, K*, N*, N2, N3a, O3, P*, Q*, R1*, R1a1, and R1b3. The structured nature of the Altaic gene pool is determined by the presence of the Caucasoid and Mongoloid components, along with the ancient genetic substratum, marked by the corresponding Western and Eastern Eurasian haplogroups. Haplogroup R1a1 prevailed in both ethnic groups, accounting for about 53 and 38% of paternal lineages in Southern and Northern Altaians, respectively. This haplogroup is thought to be associated with the eastward expansion of early Indo-Europeans, and marks Caucasoid element in the gene pools of South Siberian populations. Similarly to haplogroup K*, the second frequent haplogroup Q* represents paleo-Asiatic marker, probably associated with the Ket and Samoyedic contributions to the Altaic gene pool. The presence of lineages N2 and N3a can be explained as the contribution of Finno--Ugric tribes, assimilated by ancient Turks. The presence of haplogroups C3xM77, C3c, N*, and 03 reflects the contribution of Central Asian Mongoloid groups. These haplogroups, probably, mark the latest movements of Mongolian migrants from the territory of contemporary Tuva and Mongolia. The data of factor analysis, variance analysis, cluster analysis, and phylogenetic analysis point to substantial genetic differentiation of Northern and Southern Altaians. The differences between Northern and Southern Altaians in the haplogroup composition, as well as in the internal haplotype structure were demonstrated.

[Frequencies of Y chromosome binary haplogroups in Belarussians].

The compositions and frequencies of Y-chromosome haplogroups identified by genotyping 23 biallelic loci of its nonrecombining region (YAP, 92R7, DYF155S2, 12f2, Tat, M9, M17, M25, M89, M124, M130, M170, M172, M174, M173, M178, M201, M207, M242, M269, P21, P25, and P37) have been determined in a sample of 68 Belarussians. Eleven haplogroups have been found in the Belarussian gene pool (E, F*, G, I, I1b, J2, N3a*, Q*, R1*, R1a1, and R1b3). Haplogroup R1a1 is the most frequent; it includes 46% of all Y chromosomes in this sample. The frequencies of haplogroups I1b and I are 17.6 and 7.3%, respectively. Haplogroup N3a* is the next in frequency. The frequencies of haplogroups E, J2, and R1b3 are 4.4% each; that of R1* is 3%; and those of F*, G, and Q* are 1.5% each.

[Structure of the gene pool of eastern Ukrainians from Y-chromosome haplogroups]. / Struktura genofonda vostochnykh Ukraintsev po gaplogruppam Y-khromosomy.

Y chromosomes from representative sample of Eastern Ukrainians (94 individuals) were analyzed for composition and frequencies of haplogroups, defined by 11 biallelic loci located in non-recombining part of the chromosome (SRY1532, YAP, 92R7, DYF155S2, 12f2, Tat, M9, M17, M25, M89, and M56). In the Ukrainian gene, pool six haplogroups were revealed: E, F (including G and I), J, N3, P, and R1a1. These haplogroups were earlier detected in a study of Y-chromosome diversity on the territory of Europe as a whole. The major haplogroup in the Ukrainian gene pool, haplogroup R1a1 (earlier designated HG3), accounted for about 44% of all Y chromosomes in the sample examined. This haplogroup is thought to mark the migration patterns of the early Indo-Europeans and is associated with the distribution of the Kurgan archaeological culture. The second major haplogroup is haplogroup F (21.3%), which is a combination of the lineages differing by the time of appearance. Haplogroup P found with the frequency of 9.6%, represents the genetic contribution of the population originating from the ancient autochthonous population of Europe. Haplogroups J and E (11.7 and 4.2%, respectively) mark the migration patterns of the Middle-Eastern agriculturists during the Neolithic. The presence of the N3 lineage (9.6%) is likely explained by a contribution of the assimilated Finno-Ugric tribes. The data on the composition and frequencies of Y-chromosome haplogroups in the sample studied substantially supplement the existing picture of the male lineage distribution in the Eastern Slav population.

[MtDNA and Y-chromosome lineages in the Yakut population]. / Linii mtDNK i Y-khromosomy v populiatsii iakutov.

The structure of female (mtDNA) and male (Y-chromosome haplotypes) lineages in the Yakut population was examined. To determine mtDNA haplotypes, sequencing of hypervariable segment I and typing of haplotype-specific point substitutions in the other parts of the mtDNA molecule were performed. Y haplogroups were identified through typing of biallelic polymorphisms in the nonrecombining part of the chromosome. Haplotypes within haplogroups were analyzed with seven microsatellite loci. Mitochondrial gene pool of Yakuts is mainly represented by the lineages of eastern Eurasian origin (haplogroups A, B, C, D, G, and F). In Yakuts haplogroups C and D showing the total frequency of almost 80% and consisting of 12 and 10 different haplopypes, respectively, were the most frequent and diverse. The total part of the lineages of western Eurasian origin ("Caucasoid") was about 6% (4 haplotypes, haplogroups H, J, and U). Most of Y chromosomes in the Yakut population (87%) belonged to haplogroup N3 (HG16), delineated by the T-C substitution at the Tat locus. Chromosomes of haplogroup N3 displayed the presence of 19 microsatellite haplotypes, the most frequent of which encompassed 54% chromosomes of this haplogroup. Median network of haplogroup N3 in Yakuts demonstrated distinct "starlike phylogeny". Male lineages of Yakuts were shown to be closest to those of Eastern Evenks.

[Haplotype of Y-chromosomes in the Central Asia population]. / Gaplotipy Y-khromosomy v populiatsiiakh Srednei Azii.

The distribution of alleles and haplotypes of three diallellic Y-specific loci (YAP, DYF155S2, and Tat) in the populations of Kyrgyz, Uzbeks and Tajiks was analyzed. In Kyrgyzes and Uzbeks, a relatively high frequency of the DYF155S2 deletion (20 and 12.5%, respectively) and the C allele at the Tat locus (11.2 and 8.3%, respectively) were revealed. In the populations of southern Kyrgyzes and Uzbeks, two chromosomes carrying the YAP+ allele were detected. In both cases the YAP+ allele was found within the YAP+/DYF155S2+/TatT haplotype. The Tajik population was monomorphic in respect to the polymorphisms studied. The Tajiks demonstrated the presence of only the YAP-/DYF155S2+/TatT haplotype. This haplotype appeared to be most frequent in Kyrgyz (78.8%) and Uzbeks (83.3%). The question on the origin and the distribution of Y-chromosome variants in Eurasia are discussed.