中国西南地区藏族人群遗传亚结构研究

藏族为中国西南地区典型的少数民族,分为卫藏、康巴、安多和嘉绒等多个支系。然而,对藏族支系人群的遗传结构,特别是各分支人群的父系、母系遗传结构却缺乏深度解析。本研究基于个体水平的常染色体、父系来源的Y染色体和母系来源的线粒体3个类别遗传信息,对西藏地区卫藏藏族、四川甘孜地区康巴藏族、青海地区安多藏族和四川阿坝地区嘉绒藏族共4个藏族群体进行研究,以揭示其遗传亚结构关系。采用微测序技术检测各位点分型,利用PowerPlex~?Y23和DNATyper~(TM)Y26试剂盒检测Y-STRs基因座分型,通过热图和主成分分析、祖先成分分析、单倍群频率统计、网络图及多维尺度分析等探讨其遗传亚结构。结果表明,常染色体和Y染色体遗传标记可将4个藏族人群分为3类:青藏高原的卫藏藏族为一类,高原周边地区的康巴藏族和安多藏族的遗传结构类似分为一类,"藏彝走廊"中嘉绒藏族的遗传结构与其他藏族人群差异显著而为一类。不同藏族分支人群在线粒体遗传信息方面无明显差异性。上述多类别遗传信息的分析结果为深入了解藏族不同分支人群的遗传亚结构提供了新视角。     

云南bo人源流的父系和母系遗传研究

对云南人32份男性DNA样本进行Y染色体单倍型以及mitochondrialDNA(mtDNA)单倍型分析,结果发现云南人的父系和母系遗传组分都表现出典型的南方人群的遗传特征。由人的数据结合已经发表的东亚人群的Y染色体和mtDNA单倍型(haplotype)数据进行MultidimensionalScaling(MDS)分析,结果表明,在MDS分布图中人群体的Y染色体单倍型和mtDNA单倍型都与南方人群聚在一起。这一结果支持人的遗传族源为东亚南方人群后裔,与考古学的推论相一致。结合历史和考古学证据来探讨人的起源和史前迁移,为揭开“人悬棺”这种独特的考古文化的起源和史前传播提供遗传学的研究证据。     

云南bo人源流的父系和母系遗传研究

对云南bo人32份男性DNA样本进行Y染色体单倍型以及mitochondrial DNA (mtDNA)单倍型分析，结果发现云南bo人的父系和母系遗传组分都表现出典型的南方人群的遗传特征。由bo人的数据结合已经发表的东亚人群的Y染色体和mtDNA单倍型(haplotype)数据进行Multidimensional Scaling(MDS)分析，结果表明，在MDS分布图中bo人群体的Y染色体单倍型和mtDNA单倍型都与南方人群聚在一起。这一结果支持bo人的遗传族源为东亚南方人群后裔，与考古学的推论相一致。结合历史和考古学证据来探讨bo人的起源和史前迁移，为揭开“bo人悬棺”这种独特的考古文化的起源和史前传播提供遗传学的研究证据。     

信息

“东亚现代人史前迁徙的遗传学研究”取得新进展东亚现代人的史前迁徙一直是人类学界颇多争议的问题之一。以前的遗传学研究揭示了东亚南方和北方人群在遗传背景上存在一定的差异,但如何解释这种遗传差异以及它同东亚现代人史前迁徙路线的关系是大家争论的焦点。昆明动物研究所“引进国外杰出人才”计划获得者、副所长宿兵研究员领导的研究小组采用父系遗传的Y染色体的遗传标记,对40个东亚南北方代表群体,共2332个男性个体进行了系统的比较分析。他们的研究结果表明,南方群体的Y染色体单倍型较北方群体更为丰富,并存在南方群体特有的单倍型…     

中国西南地区3个隔离人群遗传亚结构分析

中国西南地区分布着众多少数民族,同时也包含许多地理和遗传隔离的人群,然而这些族群的遗传结构,特别是父系遗传结构缺乏深度解析。本研究采用Y染色体捕获及Illumina测序技术,对西南地区3个隔离人群男性无关个体样本,包括四川平武县的白马人、石棉县的木雅人及云南景洪市空格人,通过定点复合扩增检测,直接计数法计算相关单倍群频率,应用Past3.0软件进行PCA (principle component analysis, PCA)主成分分析并绘制群体聚类树,研究了3个族群的父系遗传结构,并探讨其遗传亚结构关系。本研究共观察到云南空格人三种Y染色体单倍群、四川白马人四种Y染色体单倍群以及木雅人五种Y染色体单倍群。结果表明,空格人与佤族的父系遗传关系最近;而白马人和木雅人主要集中在D单倍群及其下游,研究提示着白马人和四川羌族的父系遗传关系最近;木雅人与昌都地区藏族和林芝地区藏族父系遗传关系最近。本文对不同族群遗传结构的分析,丰富了我国隔离人群遗传关系的研究成果。     

和田维吾尔族人群Y染色体遗传多样性分析北大核心

[目的]分析和田维吾尔族人群Y染色体遗传多样性及与不同人群的差异。[方法]运用基因芯片技术检测860个Y-SNP位点,挑选相关位点利用Genomestudio进行分析。[结果]共检出24种单倍群。其中,单倍群R-M207和O-M175(38.10%、14.28%)在和田维吾尔族中具有较高的频率。主成分和聚类分析显示:和田维吾尔族人群与南亚、中亚、西部欧亚人群有较近的亲缘关系;与东亚、美洲、西伯利亚人群遗传结构之间差异比较大。[结论]1和田维吾尔族Y染色体SNP突变位点多样性丰富,其中主单倍群的多样性为55%。2和田维吾尔族Y染色体的两大主单倍群:R-M207(38.10%)和O-M175(14.28%)。3和田和吐鲁番两个维吾尔族群体单倍群频率和类型十分接近无显著性差异(F=0.833,P=0.367)。4和田维吾尔族人群的单倍群频率显示明显的亚欧混合现象。     

和田维吾尔族人群Y染色体遗传多样性分析

[目的]分析和田维吾尔族人群Y染色体遗传多样性及与不同人群的差异。[方法]运用基因芯片技术检测860个Y-SNP位点,挑选相关位点利用Genomestudio进行分析。[结果]共检出24种单倍群。其中,单倍群R-M207和O-M175(38.10%、14.28%)在和田维吾尔族中具有较高的频率。主成分和聚类分析显示:和田维吾尔族人群与南亚、中亚、西部欧亚人群有较近的亲缘关系;与东亚、美洲、西伯利亚人群遗传结构之间差异比较大。[结论]1和田维吾尔族Y染色体SNP突变位点多样性丰富,其中主单倍群的多样性为55%。2和田维吾尔族Y染色体的两大主单倍群:R-M207(38.10%)和O-M175(14.28%)。3和田和吐鲁番两个维吾尔族群体单倍群频率和类型十分接近无显著性差异(F=0.833,P=0.367)。4和田维吾尔族人群的单倍群频率显示明显的亚欧混合现象。     

基于高密度SNP数据的东亚人群遗传结构研究

目的 东亚疆域辽阔,民族众多,有着广泛多样的语言。中国34个省级行政区可划分为7个地理分区,人群主要分属世界七大语系。已有研究主要集中在东亚人群的起源、迁徙、融合等遗传历史。本文基于5 147份世界人群个体的高密度单核苷酸多态性（SNP）数据,从地域及语言两个角度研究东亚人群尤其是中国人群与世界其他人群的遗传关系,研究中国人群的遗传关系和遗传结构。方法 收集了5 147份世界人群个体的高密度SNP数据,并对其进行质控、合并。通过频率差异分析方法对最终获得的32 789个SNP进行统计学检验,并进一步使用主成分分析、系统发育树、祖先成分分析和D检验统计等方法,对东亚人群与世界其他人群的遗传关系,以及中国人群的遗传关系和遗传结构进行研究。结果 研究发现东亚人群与非洲、美洲和欧洲人群存在显著差异。中国人群可分为7个亚群,不同人群间的遗传聚类与其地理分布、语系语族和族源历史有很强的相关性。结论 本文研究了中国人群与世界人群的遗传关系和差异,并系统研究了中国人群的遗传亚结构。这将丰富东亚人群的群体遗传学、法医遗传学等研究基础,为个体化医疗等工作提供数据支撑。     

接触与混合——从Y染色体的角度看东乡人群及其语言的关系

东乡族是甘肃省特有的少数民族, 语言上隶属于阿尔泰语系蒙古语族, 其族源至今尚不明确。文章根据东乡人群和其他参考人群的Y 染色体单倍群数据所绘制的多维尺度分析图、树型聚类图、主成分分析图以及网络结构图分析结果显示, 东乡人在遗传结构上更靠近中亚族群, 而与蒙古人群距离甚远。通过计算汉藏人群、蒙古人群和中亚人群对东乡人群的遗传贡献率, 进一步证实了这种差距。据此, 本文认为：中国西北地区的东乡人群的父系遗传成分主要源于中亚地区操突厥语及波斯语的人群, 而非蒙古族。东乡族的这种父系遗传来源与其语言分类上的不匹配, 可以用精英主导模型来进行解释, 他们的祖先应该是被蒙古族在语言、文化上同化了的中亚人群。     

广西壮族人群线粒体ＤＮＡ序列遗传多态性分析

测定了８３例广西壮族人的线粒体ＤＮＡ（mtDNA）第一高变区５１５bp的序列,并从这一母系遗传标记的角度对壮族人群的起源和群体的遗传结构进行了探讨,在所测定的８３个个体中,共检测到６６个单倍型,包括７１个多态位点,显示了高度的遗传多样性,对单倍型的系统发育分析表明：壮族人群内部存在一定的分化,不同地区的壮族人群在mtＤＮＡ遗传变异上有一定的差异,其中柳州和河池地区的个体有一半以上属于聚类簇Ⅱ,而南宁和百色地区的个体属于聚类族Ⅰ的较多,结合已相关报道的人群比较分析显示,壮族和我国北方民族群体亲缘关系较远,而与南方的少数民族及南方汉族亲缘关系较近,壮族人群中单倍型辐射型体分布,系统树中壮族人群与其他人群聚类先后次序都表明壮族是一个较为典型的南方群体。     

Y-chromosome Genotyping and Genetic Structure of Zhuang Populations

Zhuang, the largest ethnic minority population in China, is one of the descendant groups of the ancient Bai-Yue. Linguistically, Zhuang languages are grouped into northern and southern dialects. To characterize its genetic structure, 13 East Asian-specific Y-chromosome biallelic markers and 7 Y-chromosome short tandem repeat (STR) markers were used to infer the haplogroups of Zhuang populations. Our results showed that O*, O2a, and O1 are the predominant haplogroups in Zhuang. Frequency distribution and principal component analysis showed that Zhuang was closely related to groups of Bai-Yue origin and therefore was likely to be the descendant of Bai-Yue. The results of principal component analysis and hierarchical clustering analysis contradicted the linguistically derived north-south division. Interestingly, a west-east clinal trend of haplotype frequency changes was observed, which was supported by AMOVA analysis that showed that between-population variance of east-west division was larger than that of north-south division. O* network suggested that the Hongshuihe branch was the center of Zhuang. Our study suggests that there are three major components in Zhuang. The O* and O2a constituted the original component; later, O1 was brought into Zhuang, especially eastern Zhuang; and finally, northern Han population brought O3 into the Zhuang populations.     

云南18个民族Y染色体双等位基因单倍型频率的主成分分析

世居云南的少数民族中。壮、傣、水、布依、布朗、德昂、佤、彝、白、怒、哈尼、傈僳、拉祜、纳西、景颇、阿昌、基诺和独龙18个民族是由“羌”、“濮”、“越”3大部落群体演化而来,是云南的土著居民。利用PCR-RFLP方法对这18个土著民族进行Y染色体上13个双等位基因位点进行基因分型。结果显示,不同历史族源的民族群体在Y染色体双等位基因单倍型分布上具有一定的差异：在百越后裔民族群体中以单倍型H11、H12为主要分布;在氐羌后裔民族中以单倍型H5、H6和H8为主要分布;在百濮后裔民族群体中主要单倍型分布为H6、H8和H11。进一步主成分分析表明,百越后裔民族群体和氐羌后裔民族在主成分图上聚为两组,提示父系基因库有不同的来源,与历史记载相印证。     

Differentiation of mitochondrial DNA and Y chromosomes in Russian populations

The genetic composition of the Russian population was investigated by analyzing both mitochondrial DNA (mtDNA) and Y-chromosome loci polymorphisms that allow for the different components of a population gene pool to be studied, depending on the mode of DNA marker inheritance. mtDNA sequence variation was examined by using hypervariable segment I (HVSI) sequencing and restriction analysis of the haplogroup-specific sites in 325 individuals representing 5 Russian populations from the European part of Russia. The Y-chromosome variation was investigated in 338 individuals from 8 Russian populations (including 5 populations analyzed for mtDNA variation) using 12 binary markers. For both uniparental systems most of the observed haplogroups fell into major West Eurasian haplogroups (97.9% and 99.7% for mtDNA and Y-chromosome haplogroups, respectively). Multidimensional scaling analysis based on pairwise F(ST) values between mtDNA HVSI sequences in Russians compared to other European populations revealed a considerable heterogeneity of Russian populations; populations from the southern and western parts of Russia are separated from eastern and northern populations. Meanwhile, the multidimensional scaling analysis based on Y-chromosome haplogroup F(ST) values demonstrates that the Russian gene pool is close to central-eastern European populations, with a much higher similarity to the Baltic and Finno-Ugric male pools from northern European Russia. This discrepancy in the depth of penetration of mtDNA and Y-chromosome lineages characteristic for the most southwestern Russian populations into the east and north of eastern Europe appears to indicate that Russian colonization of the northeastern territories might have been accomplished mainly by males rather than by females.     

Gene pool of ethnic groups of the caucasus: results of integrated study of the Y chromosome and mitochondrial DNA and genome-wide data

Genetic diversity has been analyzed in 22 ethnic groups of the Caucasus on the basis of data on Y-chromosome and mitochondrial DNA (mtDNA) markers, as well as genome-wide data on autosomal single-nucleotide polymorphisms (SNPs). It has been found that the West Asian component is prevailing in all ethnic groups studied except for Nogays. This Near Eastern ancestral component has proved to be characteristic of Caucasian populations and almost entirely absent in their northern neighbors inhabiting the Eastern European Plain. Turkic-speaking populations, except Nogays, did not exhibit an increased proportion of Eastern Eurasian mtDNA or Y-chromosome haplogroups compared to some Abkhaz-Adyghe populations (Adygs and Kabardians). Genome-wide SNP analysis has also shown substantial differences of Nogays from all other Caucasian populations studied. However, the characteristic difference of Nogays from other populations of the Caucasus seems somewhat ambiguous in terms of the R1a1a-M17(M198) and R1b1b1-M73 haplogroups of the Y chromosome. The state of these haplogroups in Turkic-speaking populations of the Caucasus requires further study.     

Phylogeography of mitochondrial DNA and Y-chromosome haplogroups reveal asymmetric gene flow in populations of Eastern India

Polymorphisms in mitochondrial (mt) DNA and Y-chromosomes of seven socially and linguistically diverse castes and tribes of Eastern India were examined to determine their genetic relationships, their origin, and the influence of demographic factors on population structure. Samples from the Orissa Brahmin, Karan, Khandayat, Gope, Juang, Saora, and Paroja were analyzed for mtDNA hypervariable sequence (HVS) I and II, eight Y-chromosome short tandem repeats (Y-STRs), and lineage-defining mutations diagnostic for Indian- and Eurasian-specific haplogroups. Our results reveal that haplotype diversity and mean pairwise differences (MPD) was higher in caste groups of the region (>0.998, for both systems) compared to tribes (0.917-0.996 for Y-STRs, and 0.958-0.988 for mtDNA haplotypes). The majority of paternal lineages belong to the R1a1, O2a, and H haplogroups (62.7%), while 73.2% of maternal lineages comprise the Indian-specific M*, M5, M30, and R* mtDNA haplogroups, with a sporadic occurrence of West Eurasian lineages. Our study reveals that Orissa Brahmins (a higher caste population) have a genetic affinity with Indo-European speakers of Eastern Europe, although the Y-chromosome data show that the genetic distances of populations are not correlated to their position in the caste hierarchy. The high frequency of the O2a haplogroup and absence of East Asian-specific mtDNA lineages in the Juang and Saora suggest that a migration of Austro-Asiatic tribes to mainland India was exclusively male-mediated which occurred during the demographic expansion of Neolithic farmers in southern China. The phylogeographic analysis of mtDNA and Y-chromosomes revealed varied ancestral sources for the diverse genetic components of the populations of Eastern India.     

mtDNA and Y-chromosome polymorphisms in four Native American populations from southern Mexico.

mtDNA sequence variation was examined in 60 Native Americans (Mixtecs from the Alta, Mixtecs from the Baja, Valley Zapotecs, and Highland Mixe) from southern Mexico by PCR amplification and high-resolution restriction endonuclease analysis. Four groups of mtDNA haplotypes (haplogroups A, B, C, and D) characterize Amerind populations, but only three (haplogroups A, B, and C) were observed in these Mexican populations. The comparison of their mtDNA variation with that observed in other populations from Mexico and Central America permits a clear distinction among the different Middle American tribes and raises questions about some of their linguistic affiliations. The males of these population samples were also analyzed for Y-chromosome RFLPs with the probes 49a, 49f, and 12f2. This analysis suggests that certain Y-chromosome haplotypes were brought from Asia during the colonization of the Americas, and a differential gene flow was introduced into Native American populations from European males and females.     

Brief communication: mtDNA variation in North Cameroon: lack of Asian lineages and implications for back migration from Asia to sub-Saharan Africa

The hypervariable region-1 and four nucleotide positions (10400, 10873, 12308, and 12705) of the coding region of mitochondrial DNA (mtDNA) were analyzed in 441 individuals belonging to eight populations (Daba, Fali, Fulbe, Mandara, Uldeme, Podokwo, Tali, and Tupuri) from North Cameroon and four populations (Bakaka, Bassa, Bamileke, and Ewondo) from South Cameroon. All mtDNAs were assigned to five haplogroups: three sub-Saharan (L1, L2, and L3), one northern African (U6), and one European (U5). Our results contrast with the observed high frequencies of a Y-chromosome haplogroup of probable Asian origin (R1*-M173) in North Cameroon. As a first step toward a better understanding of the evident discrepancy between mtDNA and Y-chromosome data, we propose two contrasting scenarios. The first one, here termed "migration and asymmetric admixture," implies a back migration from Asia to North Cameroon of a population group carrying the haplotype R1*-M173 at high frequency, and an admixture process restricted to migrant males. The second scenario, on the other hand, temed "divergent drift," implies that modern populations of North Cameroon originated from a small population group which migrated from Asia to Africa and in which, through genetic drift, Y-chromosome haplotype R1*-M173 became predominant, whereas the Asian mtDNA haplogroups were lost.     

云南16个少数民族群体的线粒体DNA多态性研究

利用PCR—RFLP法对傣族、白族、蒙古族、彝族等10个少数民族的16个群体共654人进行了mtDNA编码区多态性分析,共检测到17种单倍群,其中4种为未能确认的单倍群。单倍群频率分布和主成分图共同显示,百越系的3个民族共6个群体有高频的B、F单倍群,聚集在图的下部,表现出鲜明的南方群体特征;蒙古族的2个群体有高频的A、D单倍群,聚在图的上部,具有典型的北方群体特征;氐羌系的5个民族共7个群体全部或绝大多数都兼有南北方高频单倍群,位于图的中间,提示他们同时具有南北方群体的一些母系遗传特征。同一民族不同群体间的单倍群频率分布存在差异,但差异不很大,一般小于不同族源民族间的差异,但不一定都小于同一族源民族间的差异。     

Uniparental genetic markers in South Amerindians

A comprehensive review of uniparental systems in South Amerindians was undertaken. Variability in the Y-chromosome haplogroups were assessed in 68 populations and 1,814 individuals whereas that of Y-STR markers was assessed in 29 populations and 590 subjects. Variability in the mitochondrial DNA (mtDNA) haplogroup was examined in 108 populations and 6,697 persons, and sequencing studies used either the complete mtDNA genome or the highly variable segments 1 and 2. The diversity of the markers made it difficult to establish a general picture of Y-chromosome variability in the populations studied. However, haplogroup Q1a3a* was almost always the most prevalent whereas Q1a3* occurred equally in all regions, which suggested its prevalence among the early colonizers. The STR allele frequencies were used to derive a possible ancient Native American Q-clade chromosome haplotype and five of six STR loci showed significant geographic variation. Geographic and linguistic factors moderately influenced the mtDNA distributions (6% and 7%, respectively) and mtDNA haplogroups A and D correlated positively and negatively, respectively, with latitude. The data analyzed here provide rich material for understanding the biological history of South Amerindians and can serve as a basis for comparative studies involving other types of data, such as cultural data.     

High-resolution analysis of Y-chromosomal polymorphisms reveals signatures of population movements from central Asia and West Asia into India

Linguistic evidence suggests that West Asia and Central Asia have been the two major geographical sources of genes in the contemporary Indian gene pool. To test the nature and extent of similarities in the gene pools of these regions we have collected DNA samples from four ethnic populations of northern India, and have screened these samples for a set of 18 Y-chromosome polymorphic markers (12 unique event polymorphisms and six short tandem repeats). These data from Indian populations have been analysed in conjunction with published data from several West Asian and Central Asian populations. Our analyses have revealed traces of population movement from Central Asia and West Asia into India. Two haplogroups, HG-3 and HG-9, which are known to have arisen in the Central Asian region, are found in reasonably high frequencies (41.7% and 14.3% respectively) in the study populations. The ages estimated for these two haplogroups are less in the Indian populations than those estimated from data on Middle Eastern populations. A neighbour-joining tree based on Y-haplogroup frequencies shows that the North Indians are genetically placed between the West Asian and Central Asian populations. This is consistent with gene flow from West Asia and Central Asia into India.