Marcin Woźniak

Complex interactions of the Eastern and Western Slavic populations with other European groups as revealed by mitochondrial DNA analysis

Mitochondrial DNA sequence variation was examined by the control region sequencing (HVS I and HVS II) and RFLP analysis of haplogroup-diagnostic coding region sites in 570 individuals from four regional populations of Poles and two Russian groups from northwestern part of the country. Additionally, sequences of complete mitochondrial genomes representing K1a1b1a subclade in Polish and Polish Roma populations have been determined. Haplogroup frequency patterns revealed in Poles and Russians are similar to those characteristic of other Europeans. However, there are several features of Slavic mtDNA pools seen on the level of regional populations which are helpful in the understanding of complex interactions of the Eastern and Western Slavic populations with other European groups. One of the most important is the presence of subhaplogroups U5b1b1, D5, Z1 and U8a with simultaneous scarcity of haplogroup K in populations of northwestern Russia suggesting the participation of Finno-Ugrian tribes in the formation of mtDNA pools of Russians from this region. The results of genetic structure analyses suggest that Russians from Velikii Novgorod area (northwestern Russia) and Poles from Suwalszczyzna (northeastern Poland) differ from all remaining Polish and Russian samples. Simultaneously, northwestern Russians and northeastern Poles bear some similarities to Baltic (Latvians) and Finno-Ugrian groups (Estonians) of northeastern Europe, especially on the level of U5 haplogroup frequencies. The occurrence of K1a1b1a subcluster in Poles and Polish Roma is one of the first direct proofs of the presence of Ashkenazi-specific mtDNA lineages in non-Jewish European populations.

A novel multiplex assay amplifying 13 Y-STRs characterized by rapid and moderate mutation rate.

As microsatellites located on Y chromosome mutate with different rates, they may be exploited in evolutionary studies, genealogical testing of a variety of populations and even, as proven recently, aid individual identification. Currently available commercial Y-STR kits encompass mostly low to moderately mutating loci, making them a perfect choice for the first two applications. Some attempts have been made so far to utilize Y-STRs to provide a discriminatory tool for forensic purposes. Although all 13 rapidly mutating Y-STRs were already multiplexed, no single assay based on single-copy markers allowing at least a portion of close male relatives to be differentiated from one another is available. To fill in the blanks, we constructed and validated an assay comprised of single-copy Y-STR markers only with a mutation rate ranging from 8×10(-3) to 1×10(-2). Performance of the resulting combination of nine RM Y-STRs and four moderately mutating ones was tested on 361 father-son pairs and 1326 males from 9 populations revealing an overall mutation rate of 1.607×10(-1) for the assay as a whole. Application of the proposed 13 Y-STR set to differentiation of haplotypes present among homogenous population of Buryats resulted in a threefold increase of discrimination as compared with 10 Y-STRs from the PowerPlex(®) Y.

Genetic data from Y chromosome STR and SNP loci in Ukrainian population

We have tested a sample of 154 unrelated males from Lviv region (Ukraine) for 11 Y-chromosomal single nucleotide polymorphisms (SNPs) and 17 Y-chromosomal STR loci (DYS19, DYS385a, DYS385b, DYS389I, DYS389II, DYS390, DYS391, DYS392, DYS393, DYS437, DYS438, DYS439, DYS448, DYS456, DYS458, DYS635, YGATA_H4.1). Haplotype and haplogroup diversity values were calculated for the population under study. Genetic distances (R(ST)) to 9 other Slavic populations were calculated based on 12 Y-STR loci. Haplotype frequencies and MDS plots were constructed based on genetic distances. Haplogroup frequency patterns revealed in Ukraine are similar to those characteristic of other European populations. However, it also allowed for identification a specific genetic component in Ukrainian sample which seems to originate from areas dwelled by Western Slavs, i.e. subhaplogroup R1a1a7, at frequency of 13.65%. Analysis of R(ST) distances and AMOVA revealed high level of heterogeneity between Slavic populations inhabiting the south and north part of Europe, determined geographically rather than by linguistic factors. It has also been found a closer similarity (in the values of R(ST)) between Ukrainian and Slovak populations than between Ukrainians and other Slavic population samples.

Similarities and Distinctions in Y Chromosome Gene Pool of Western Slavs

Analysis of Y chromosome Y-STRs has proven to be a useful tool in the field of population genetics, especially in the case of closely related populations. We collected DNA samples from 169 males of Czech origin, 80 males of Slovakian origin, and 142 males dwelling Northern Poland. We performed Y-STR analysis of 12 loci in the samples collected (PowerPlex Y system from Promega) and compared the Y chromosome haplotype frequencies between the populations investigated. Also, we used Y-STR data available from the literature for comparison purposes. We observed significant differences between Y chromosome pools of Czechs and Slovaks compared to other Slavic and European populations. At the same time we were able to point to a specific group of Y-STR haplotypes belonging to an R1a haplogroup that seems to be shared by Slavic populations dwelling in Central Europe. The observed Y chromosome diversity may be explained by taking into consideration archeological and historical data regarding early Slav migrations.

Analysis of forensically used autosomal short tandem repeat markers in Polish and neighboring populations

The purpose of this study was to evaluate the homogeneity of Polish populations with respect to STRs chosen as core markers of the Polish Forensic National DNA Intelligence Database, and to provide reference allele frequencies and to explore the genetic interrelationship between Poland and neighboring countries. The allele frequency distribution of 10 STRs included in the SGMplus kit was analyzed among 2176 unrelated individuals from 6 regional Polish populations and among 4321 individuals from Germany (three samples), Austria, The Netherlands, Sweden, Czech Republic, Slovakia, Belarus, Ukraine and the Russian Federation (six samples). The statistical approach consisted of AMOVA, calculation of pairwise Rst values and analysis by multidimensional scaling. We found homogeneity of present day Poland and consistent differences between Polish and German populations which contrasted with relative similarities between Russian and German populations. These discrepancies between genetic and geographic distances were confirmed by analysis of an independent data set on Y chromosome STRs. Migrations of Goths, Viking influences, German settlements in the region of Volga river and/or forced population resettlements and other events related to World War II are the historic events which might have caused these finding.

Variation of 15 Autosomal Microsatellite DNA Loci in the Russian Population

The allele frequencies of 15 autosomal STR loci (D3S1358, vWA, FGA, TH01, TPOX, CSF1PO, D5S818, D13S317, D7S820, D16S539, D2S1338, D8S1179, D21S11, D18S51, and D19S433) used in forensic medicine were determined for the Russian population of European Russia (N = 176). The power of discrimination (PD) and power of exclusion (PE) of the system of the 15 STR loci were 0.999 999 999 999 999 986 and 0.999 999 331 310 171 000, respectively. The allele and genotype frequency distributions in the Russian population corresponded to the Hardy-Weinberg equilibrium. The D2S1338, D18S51, D21S11, and FGA loci were identified as the most informative markers for the Russian population and proposed as a reference for forensic studies in the Russian Federation.

Population genetics of the STRs vWA, TH01, TPOX, CSF1PO, D5S818, D13S317, D7S820, D16S539, LPL, F13B, FESFPS, F13A01 and ACTBP2 in the Pomerania-Kujawy region of Poland

Allele frequencies for 13 STRs were obtained from a sample of 306-1041 unrelated individuals born in the Pomerania-Kujawy region of Poland.

Y chromosome haplotype diversity in Mongolic-speaking populations and gene conversion at the duplicated STR DYS385a,b in haplogroup C3-M407

Y chromosome microsatellite (Y-STR) diversity has been studied in different Mongolic-speaking populations from South Siberia, Mongolia, North-East China and East Europe. The results obtained indicate that the Mongolic-speaking populations clustered into two groups, with one group including populations from eastern part of South Siberia and Central Asia (the Buryats, Barghuts and Khamnigans) and the other group including populations from western part of Central Asia and East Europe (the Mongols and Kalmyks). High frequency of haplogroup C3-M407 (>50%) is present in the Buryats, Barghuts and Khamnigans, whereas in the Mongols and Kalmyks its frequency is much lower. In addition, two allelic combinations in DYS385a,b loci of C3-M407 haplotypes have been observed: the combination 11,18 (as well as 11,17 and 11,19) is frequent in different Mongolic-speaking populations, but the 11,11 branch is present mainly in the Kalmyks and Mongols. Results of locus-specific sequencing suggest that the action of gene conversion is a more likely explanation for origin of homoallelic 11,11 combination. Moreover, analysis of median networks of Y-STR haplotypes demonstrates that at least two gene conversion events can be revealed—one of them has probably occurred among the Mongols, and the other event occurred in the Barghuts. These two events give an average gene conversion rate range of 0.24–7.1 × 10–3 per generation.

Intra- and inter-population analysis of haplotype diversity in Yfiler® Plus system using a wide set of representative data from Polish population

Microsatellite loci in human Y chromosome (Y-STRs) proved to be efficient tools in population genetics and forensics [1,2]. Many multiplex amplification systems were developed that aid in fast and reliable Y-STR haplotyping [3–5]. A continuous trend of increasing the number of loci typed is apparent in the history of commercially available Y-STR kits. Yfiler Plus developed by Applied Biosystems is a recent addition to the set of kits available on the market. The system allows amplification of 27 Y-STR loci, comprising a standard set of so called “minimal haplotype” markers (as defined in the YHRD database) as well as additional markers, including those characterized by fast mutation rate [6]. To take full advantage of the increased resolution of Y chromosome haplotype analysis offered by the Yfiler Plus, it is necessary to collect population frequency data for as many population samples as possible. However, due to the relative novelty of the Yfiler Plus system, only limited set of population data is currently available [7–13]. The aim of this study was to obtain Yfiler Plus haplotypes from 496 males from Poland representing general population of the country, assess haplotype and locus-specific diversity and compare the data to other European populations, for which Yfiler Plus data are available. Additionally, 90 sons of the analysed men were typed to assess mutation rate of the markers included in the system. A total of 586 samples were collected as buccal swabs from males living in 16 different voivodships in Poland. Exact sampling location is not given, as polish population is characterized by outstanding homogeneity of Y chromosome lineages [14]. All samples were collected with informed consent for studies of gene frequency variation from anonymous donors after an appropriate permission for this study from the local Bioethics Committee was obtained. DNA was extracted using PrepFiler Express Forensic DNA Extraction Kit (ThermoFisher Scientific, Waltham, MA, USA) according to the manufacturer’s recommendations. DNA quantity was assessed by real-time PCR using the Quantifiler DUO Quantification Kit (ThermoFisher Scientific) and 7500 Real Time PCR System thermal cycler (ThermoFisher Scientific). Samples were amplified using Yfiler Plus PCR Amplification Kit (ThermoFisher Scientific) and GeneAmp PCR System 9700 (ThermoFisher Scientific) according to manufacturer’s instructions. Samples for capillary electrophoresis were prepared by mixing 1 mL of amplified product with 0.4 mL of 600 LIZ Size Standard