深圳无偿献血人群中李姓、王姓和张姓无关男性个体Y-STR单倍型遗传多态性

为研究姓氏群体Y染色体特异STR单倍型的遗传多态性, 采用PCR复合扩增和ABI PrismTM 3100基因测序仪荧光检测方法对DYS426等9个Y-STR基因座进行基因分型, 检测深圳地区李姓无关男性个体血样139份、王姓无关男性个体118份、张姓无关男性个体119份。结果在139份李姓群体中, 共检出126种单倍型, 其中118种单倍型仅出现1次, 检出频率最高的1种单倍型出现6次, 单倍型多样性为0.9974; 118份王姓无关男性样本中, 共检出105种单倍型, 其中94种单倍型仅出现1次, 检出频率最高的1种单倍型出现4次, 单倍型多样性为0.9953; 张姓无关男性样本中, 共检出101种单倍型, 其中88种单倍型仅出现1次, 检出频率最高的1种单倍型出现4次, 单倍型多样性为0.9964。结果表明: 深圳地区李、王、张姓氏无关男性个体Y-STR单倍型的遗传多态性丰富, 与以往的汉族无关男性群体遗传资料相比较, 差异不显著。     

A preliminary study on the origin of Koreans based on Y-STR variation

To investigate the origin of Koreans, we examined the 12-locus Y-chromosome short tandem repeat (Y-STR) variation in a sample of 310 unrelated males from three localities (Gochang, Andong and Geoje) in Korea and statistically analyzed the previously published four Y-STR databases (n = 1655) of Korean population. The median joining network of 9-locus Y-STR haplotypes inferred as haplogroup O2b-SRY₊₄₆₅ showed a “star cluster” indicative of a population expansion from a centrally positioned haplotype. The central haplotype in the “star cluster” was the most frequently occurring Y-STR haplotype among the Korean male gene pool (6%, 127 of 1965, 10,14,12,13,14,16,13,13,23, for loci DYS391, DYS389I, DYS439, DYS438, DYS437, DYS19, DYS392, DYS393, and DYS390), which was shared among all seven datasets. Based on the “star cluster” pattern from both our data (41%, 128 of 310) and those previously published (34%, 563 of 1655), we suggest that the most frequent Y-STR haplotype among the Korean male gene pool seems to be the Korean modal (ancestral) haplotype. Further study with additional Y-STR and Y-SNP data of the east Asian populations as well as Korean population are needed to providing a genetic clue for the “star cluster” (O2b-SRY₊₄₆₅) associated with the ethnohistoric events of the Koreans.     

Genetic signatures of coancestry within surnames

Surnames are cultural markers of shared ancestry within human populations. The Y chromosome, like many surnames, is paternally inherited, so men sharing surnames might be expected to share similar Y chromosomes as a signature of coancestry. Such a relationship could be used to connect branches of family trees, to validate population genetic studies based on isonymy, and to predict surname from crime-scene samples in forensics. However, the link may be weak or absent due to multiple independent founders for many names, adoptions, name changes and nonpaternities, and mutation of Y haplotypes. Here, rather than focusing on a single name, we take a general approach by seeking evidence for a link in a sample of 150 randomly ascertained pairs of males who each share a British surname. We show that sharing a surname significantly elevates the probability of sharing a Y-chromosomal haplotype and that this probability increases as surname frequency decreases. Within our sample, we estimate that up to 24% of pairs share recent ancestry and that a large surname-based forensic database might contribute to the intelligence-led investigation of up to approximately 70 rapes and murders per year in the UK. This approach would be applicable to any society that uses patrilineal surnames of reasonable time-depth.     

Namesakes or relatives? Approaches to investigating the relationship between Y chromosome haplogroups and surnames

Population genetics successfully applies surnames as quasi-genetic markers when estimating similarity between populations and calculating the level of random inbreeding. These calculations are based on the isonymy coefficient, which assumes that every surname is monophyletic, i.e., it originated from a single common ancestor and all namesakes are therefore relatives. On the other hand, there is a general opinion that a typical Russian surname is polyphyletic: it originated multiple times and most namesakes are, therefore, not related to each other. Combined studies of Y chromosomes and surnames now allow us to address this issue. This study discusses approaches to statistical evaluation of Y chromosome haplogroup frequencies in groups of people bearing the same surname (namesakes). The proposed index of accumulated haplogroup frequency eliminates the artifactual effect of a randomly increased haplogroup frequency in namesakes by subtracting its population (expected) frequency from the observed value, while the expected frequency is calculated as the weighted average of the frequencies of this haplogroup in the populations where the surname carriers come from. From the total sample (comprising 1244 persons from 13 populations of the historical Russian area), 123 individuals carrying 14 most frequent surnames were chosen. A comparison of the haplogroup frequencies in these 14 namesake groups and in 14 respective population control groups compiled from the total sample showed that accumulation of certain Y chromosome haplogroups was nonrandom even in carriers of widespread surnames. An analysis of Y-STR haplotypes rather than Y-SNP haplogroups could provide a better insight into relationships between namesakes and will be the subject of further research.     

Namesakes or relatives? Approaches to investigating the relationship between Y chromosomal haplogroups and surnames

Population genetics successfully applies surnames as quasi-genetic markers when estimating similarity between populations and calculating a measure of random inbreeding. These calculations are based on an isonomy coefficient which assumes that every surname is monophyletic: that it originated from single common ancestor and all namesakes are therefore relatives. On the other hand, there is a general opinion that a typical Russian surname is polyphyletic: it originated multiple times and most namesakes are therefore not related to each other. Combined studies of Y chromosomes and surnames now allow us to address this issue. In this study, we discuss approaches for statistical evaluation of Y chromosomal haplogroup frequencies in groups of people bearing the same surname (namesakes). We propose an 'Index of Accumulated Haplogroup Frequency', which allows for errors due to random (artifactual) effects increasing a haplogroup frequency in a group of namesakes by subtracting the population frequency of this haplogroup. This population frequency is calculated as the weighted average of the frequencies of this haplogroup in the populations that the carriers of this surname come from. Fom the total sample (comprising 1244 persons from 13 populations of the historical Russian area) we chose 123 persons carrying 14 surnames which were the most frequent in the total sample. Haplogroup frequencies in these 14 "surname" groups were compared with the respective 14 "population" control groups compiled from the total sample as described above. We found that even these widespread surnames exhibit non-random accumulation of specific Y chromosomal haplogroups. More detailed analyses of the relationships between namesakes could be carried out using Y-STR haplotypes rather than Y-SNP haplogroups, and will be the subject of a future study.     

Thomas Jefferson's Y chromosome belongs to a rare European lineage

We have characterized the Y chromosome carried by President Thomas Jefferson, the general rarity of which supported the idea that he, or a patrilineal relative, fathered the last son of his slave Sally Hemings. It belongs to haplogroup K2, a lineage representing only approximately 1% of chromosomes worldwide, and most common in East Africa and the Middle East. Phylogenetic network analysis of its Y-STR (short tandem repeat) haplotype shows that it is most closely related to an Egyptian K2 haplotype, but the presence of scattered and diverse European haplotypes within the network is nonetheless consistent with Jefferson's patrilineage belonging to an ancient and rare indigenous European type. This is supported by the observation that two of 85 unrelated British men sharing the surname Jefferson also share the President's Y-STR haplotype within haplogroup K2. Our findings represent a cautionary tale in showing the difficulty of assigning individual ancestry based on a Y-chromosome haplotype, particularly for rare lineages where population data are scarce.     

Croatian national reference Y-STR haplotype database

A reference Y-chromosome short tandem repeat (STR) haplotype database is needed for Y-STR match interpretation as well as for national and regional characterization of populations. The aim of this study was to create a comprehensive Y-STR haplotype database of the Croatian contemporary population and to analyze substructure between the five Croatian regions. We carried out a statistical analysis of the data from previously performed genetic analyses collected during routine forensic work by the Forensic Science Centre "Ivan Vu?eti?". A total of 1,100 unrelated men from eastern, western, northern, southern and central Croatia were selected for the purpose of this study. Y-STRs were typed using the AmpFISTR Yfiler PCR amplification kit. Analysis of molecular variance calculated with the Y chromosome haplotype reference database online analysis tool included 16 population samples with 20,247 haplotypes. A total of 947 haplotypes were recorded, 848 of which were unique (89.5%). Haplotype diversity was 0.998, with the most frequent haplotype found in 9 of 1,100 men (0.82%). Locus diversity varied from 0.266 for DYS392 to 0.868 for DYS385. Discrimination capacity was 86.1%. Our results suggested high level of similarity among regional subpopulations within Croatia, except for mildly different southern Croatia. Relative resemblance was found with Bosnia and Herzegovina and Serbia. Whit Atheys' Haplogroup Predictor was used to estimate the frequencies of Y-chromosome haplogroups. I2a, R1a, E1b1b and R1b haplogroups were most frequent in all Croatian regions. These results are important in forensics and contribute to the population genetics and genetic background of the contemporary Croatian population.     

7个Y-STR基因座荧光标记复合分型及在中国汉族群体中遗传多态性的研究

建立了FAM（蓝色荧光）标记的DYS456、DYS464a/b/c/d和DYS527a/b和JOE(绿色荧光)标记的DYS531、DYS709、DYS448和DYS522 7个Y染色体STR基因座(相当于11个位点)复合扩增分型体系。利用ABI3100遗传分析仪调查中国广东汉族151例和河南106例汉族无关男性个体的遗传多态性分布, 并探讨在法医学中的应用价值。结果显示, 此方法能作出正确分型的最低基因组DNA量为0.02 ng; 在女性成份为男性成份150倍的混合DNA样本(总DNA量为160 ng)中能正确检出全部7个Y-STR基因座的基因型。 广东和河南2个汉族男性群体中, 观察到的单体型分别有150、105种, 其中仅观察到1次的单体型分别有149、104种, 单体型多样性(HD)分别为0.999912、0.999820; 这组Y-STR单体型在两个群体中的分布差异有统计学显著意义(秩和检验: P<0.001)。此7个Y-STR基因座多态性分析适用于法医学实践和人类进化的研究。     

Y-chromosomes and the extent of patrilineal ancestry in Irish surnames

Ireland has one of the oldest systems of patrilineal hereditary surnames in the world. Using the paternal co-inheritance of Y-chromosome DNA and Irish surnames, we examined the extent to which modern surname groups share a common male-line ancestor and the general applicability of Y-chromosomes in uncovering surname origins and histories. DNA samples were collected from 1,125 men, bearing 43 different surnames, and each was genotyped for 17 Y-chromosome short tandem repeat (STR) loci. A highly significant proportion of the observed Y-chromosome diversity was found between surnames demonstrating their demarcation of real and recent patrilineal kinship. On average, a man has a 30-fold increased chance of sharing a 17 STR Y-chromosome haplotype with another man of the same surname but the extent of congruence between the surname and haplotype varies widely between surnames and we attributed this to differences in the number of early founders. Some surnames such as O’Sullivan and Ryan have a single major ancestor, whereas others like Murphy and Kelly have numerous founders probably explaining their high frequency today. Notwithstanding differences in their early origins, all surnames have been extensively affected by later male introgession. None examined showed more than about half of current bearers still descended from one original founder indicating dynamic and continuously evolving kinship groupings. Precisely because of this otherwise cryptic complexity there is a substantial role for the Y-chromosome and a molecular genealogical approach to complement and expand existing sources.     

陕西渭南地区汉族人群17个Y-STR基因座多态性及遗传关系分析

调查陕西渭南地区汉族群体17个Y-STR基因座的多态性,探讨其群体遗传学及法医学应用价值。应用Y-fi ler荧光标记复合扩增系统,对413名陕西渭南地区汉族无关男性个体17个Y-STR基因座进行复合扩增,用ABI3130遗传分析仪进行基因分型,计算各基因座的群体遗传学参数,并结合已经发表的其他10个群体相应基因座的单倍型资料,分析各群体间的遗传距离。413名陕西渭南汉族个体共检出405种单倍型,其中397种单倍型仅出现1次,单倍型多样性达0.9999,基因多样性(GD)为0.4130(DYS391)~0.9734(DYS385a/b),累计GD值为0.9999。遗传距离分析提示,陕西渭南汉族与辽宁满族的遗传距离最小(0.00110),与青海藏族的遗传距离最大(0.22333)。结果表明,17个Y-STR基因座在陕西渭南汉族群体中具有丰富的遗传多态性和较高的非父排除能力,在法医学和人类群体遗传学研究中具有重要价值。     

2个新Y-STR基因座的序列分析和在广东汉族群体中的多态性研究

分析了Y染色体2个新STR基因座DYS522和DYS527的序列结构及其在151例广东汉族男性无关个体中的遗传多态性。结果显示, DYS522基因座为单拷贝, 核心序列gata, 观察到重复数目为9~13次。DYS527基因座有双拷贝, 每一个拷贝的序列结构有6个稳定的重复序列和2个数目变异的重复序列, 如(GGAA)₃…(GGAA)₂…(GGAA)₂…(GGAA)₃…(GGAA)₄…(GGAA)₃…(GAAA)_m(GGAA)_n。在广东汉族男性群体中观察到2个数目变异的核心序列重复总数目(m+n)为18~26次。还发现1个稀有的拷贝“15.3”。在广东汉族男性群体中, 2个基因座所组成的单倍型有63种, 出现最多的单倍型为11/21-22, 频率为0.0728, 仅出现1次的单倍型有29种, 频率为0.0066。本系统单倍型多样性(HD)为0.9780, 个体识别力(DP)达0.9715。在38对父子遗传中未发现DYS522和DYS527基因座发生变异。这2个Y-STR具有种属差异, 能够区分“男人”和“非人”雄性动物。因此, DYS522和DYS527基因座具有高度的多态性, 适用于法医学实践和人类进化的研究。     

辽宁满族11个Y-STR基因座多态性及遗传关系的分析

调查了辽宁满族群体11个Y-STR基因座的多态性分布, 探讨其群体遗传学及法医学应用价值。应用Powerplex Y System荧光标记复合扩增系统检测203名满族无关男性个体的11个Y-STR基因座, 用ABI310遗传分析仪进行基因分型, 计算等位基因和单倍型频率, 并结合已公开发表的国内其他16个群体相应基因座的遗传学资料, 分析其遗传距离和聚类关系。满族个体中共检出189种单倍型, 单倍型频率多样性0.9991, 基因多样性GD值在0.4594(DYS391)～0.9258(DYS385a/b); 从遗传距离分析发现, 满族和东北汉族的遗传距离最小(0.0015), 与维吾尔族的遗传距离最大(0.1485)。结果表明, 11个Y-STR基因座在满族群体中具有较好的遗传多态性, 适用于当地区的法医学应用。与其他民族群体遗传多样性的研究, 对了解满族的起源、迁移以及相互关系有重要意义。     

德州汉族人群37个Y⁃STR基因座遗传多态性分析

调查德州汉族人群598名男性无关个体37个Y-STR基因座的遗传多态性,分析其在法医学和群体遗传学方面的应用价值,用AGCU Y37荧光检测试剂盒对德州汉族群体的37个Y-STR基因座进行扩增,用3500xL基因分析仪对其进行检测。用MEGA 7.0软件,通过邻接法（neighbor-joining, NJ）构建德州汉族群体和其他15个参考群体的系统发生树,探索群体间的遗传关系。结果共检出593种单倍型,基因多样性（genetic diversity, GD）值为0.113 9（DYS645）～0.971 4（DYS385a/b）,单倍型多样性（haplotype diversity, HD）和识别能力（discriminative capacity, DC）分别为0.999 971 989和0.991 6。结果表明,这37个Y-STR基因座在德州汉族人群中有较高的多态性分布。群体遗传分析中,遗传距离、多维尺度分析( multi-dimensional scaling,MDS) 和系统发生树分析结果表明,德州汉族与其他地区的汉族群体遗传距离更近。不同群体的遗传特征与语系划分、历史形成、地理分布等方面具有一致性。研究结果可为德州汉族人群的法庭科学和群体遗传学研究提供基础数据支持。     

广东汉族22个Y-STR基因座遗传多态性及遗传关系分析

调查了广东汉族群体22个 Y-STR基因座的遗传多态性分布情况, 探讨其群体遗传学及法医学应用价值。通过自行建立的两组Y-STR荧光标记复合扩增体系(MultiplexⅠ: DYS505, DYS533, DYS576, DYS588, DYS634, DYS643; MultiplexⅡ: DYS461, DYS481, DYS504, DYS508, DYS607)和应用进口Powerplex Y System (DYS19, DYS389Ⅰ/Ⅱ, DYS390, DYS391, DYS392, DYS393, DYS385, DYS437, DYS438, DYS439), 对广东汉族216 名无关男性个体进行22 个STR基因座的复合分型, 用ABI310基因分析仪对扩增产物进行检测, 统计22 个Y-STR基因座的群体遗传学参数, 并结合已公开发表的其他12 个群体“扩展单倍型”的数据资料, 分析广东汉族群体遗传距离和聚类关系。3 组复合扩增系统均可成功进行分型, 基因多样性GD值在0.3299(DYS634)~ 0.9425(DYS385); 22 个Y-STR基因座共同构成的单倍型214 种, 单倍型多样性为0.9999。广东汉族和潮汕汉族的遗传距离最近(-0.0030), 与东北汉族的遗传距离最远(0.0195)。22 个Y-STR基因座联合检测具有丰富的遗传多态性, 对建立Y染色体STR数据库, 研究群体遗传学和进行法医学应用有重要意义。     

Surnames and the Y chromosome

A randomly ascertained sample of males with the surname "Sykes" was typed with four Y-chromosome microsatellites. Almost half the sample shared the same Y-chromosome haplotype, which has not been observed in control samples either from the same geographic region or from the United Kingdom as a whole. This points to a single surname founder for extant Sykes males, even though written sources had predicted multiple origins. The distribution of other Sykes Y-chromosome haplotypes were not significantly different from those in controls and may be accounted for by the historical accumulation of nonpaternity during the past 700 years, in which case the average rate estimate is 1.3%/generation. If this pattern is reproduced with other surnames, it may have important forensic and genealogical applications.     

中国云南白族和新疆维族7个Y-STR基因座的遗传多态性

利用AB I3100遗传分析仪, 我们调查了7个Y-STR基因座构成的单体型在中国云南白族133例和新疆维族105例无关男性个体中的分布。7个Y-STR基因座包括DYS456、DYS464 a/b/c/d、DYS527 a/b、DYS531、DYS709、DYS448和DYS522。结果显示,云南白族和新疆维族2个民族男性群体中,分别观察到133、105种单体型, 均为仅观察到1次的单体型,单体型多样性(HD)均趋近于1, 比较这种单体型在两个群体中的分布差异,显示有统计学显著意义(秩和检验: P<0.001)。中国云南白族和新疆维族7个Y-STR基因座具有较高的多态性, 为法医学实践和群体遗传学的研究提供了有用的基础资料。     

High Y-chromosomal diversity and low relatedness between paternal lineages on a communal scale in the Western European Low Countries during the surname establishment

There is limited knowledge on the biological relatedness between citizens and on the demographical dynamics within villages, towns and cities in pre-17th century Western Europe. By combining Y-chromosomal genotypes, in-depth genealogies and surname data in a strict genetic genealogical approach, it is possible to provide insights into the genetic diversity and the relatedness between indigenous paternal lineages within a particular community at the time of the surname adoption. To obtain these insights, six Flemish communities were selected in this study based on the differences in geography and historical development. After rigorous selection of appropriate DNA donors, low relatedness between Y chromosomes of different surnames was found within each community, although there is co-occurrence of these surnames in each community since the start of the surname adoption between the 14th and 15th century. Next, the high communal diversity in Y-chromosomal lineages was comparable with the regional diversity across Flanders at that time. Moreover, clinal distributions of particular Y-chromosomal lineages between the communities were observed according to the clinal distributions earlier observed across the Flemish regions and Western Europe. No significant indication for genetic differences between communities with distinct historical development was found in the analysis. These genetic results provide relevant information for studies in historical sciences, archaeology, forensic genetics and genealogy.     

中国南方汉族人群6个Y-STR基因座 遗传多态性及法医学应用

为研究中国南方汉族人群DYS393等6个Y-STR基因座的遗传多态性并用于法医学鉴定,通过采用PCR复合扩增和基因测序仪荧光检测方法,检查204个无关男性个体,调查南方汉族的6个Y-STR基因座的单倍型频率,并对93对真父子和38对非父子的亲子鉴定样本进行检测。结果DYS393基因座检出5个等位基因,DYS19基因座检出6个等位基因,DYS389Ⅱ基因座检出8个等位基因,DYS390基因座检出6个等位基因,DYS391基因座检出4个等位基因,DYS385 基因座检出44个等位基因,共检出176种单倍型。93对真父子中,观察到2例分别有1个基因座突变。检测38对非父子,有1个或2个Y-STR基因座排除的案例各有1例（2.6%）;有3 个和3个以上的Y-STR基因座可以排除父子关系的案例为35例（92.1%）;6个Y-STR基因座不能排除父子关系的为1例。结果表明6个Y-STR基因座具有丰富的遗传多态性,可用于法医学个体识别和亲子鉴定。Abstract: To study the genetic polymorphisms of six Y-chromosome specific STR loci in the southern Chinese Han population and apply it in forensic science, six Y-STR loci were amplified by multiple PCR and the PCR products were detected by using ABI PrismTM 377 Sequencer. The haplotype frequencies at 6 Y-STR loci were determined in a total of 204 unrelated males from southern Han population of China. Ninety-three father/son pairs with demonstrated paternity and thirty-eight non-paternity father/son pairs were detected by using our Y-STR system. As a result, the number of alleles for DYS393、DYS19、DYS389Ⅱ、DYS390、DYS391and DYS385 were 5, 6, 8, 6, 4 and 44 , respectively. A total of 176 haplotypes at 6 Y-STR loci were found. Two father/son pairs with single Y-STR mutation were observed in the 93 father/son pairs with demonstrated paternity. Among the 38 non-paternity father/son pairs, one case with one Y-STR exclusion of paternity, one case with two Y-STR exclusions and 35 cases with 3 or more Y-STR exclusions were observed. Non-exclusion of paternity at 6 Y-STR loci was found only in one case. This result indicated that the six Y-STR loci were highly polymorphic and are suitable for personal identification and paternity testing.