孔姓人群Y染色体遗传多态性研究及其法医学意义

目的获取孔姓人群Y-SNP和Y-STR遗传标记的信息,探索姓氏与Y染色体的关联性及法医学意义。方法采用等级复合扩增和SNaPshot技术检测255例孔姓男性和330例随机无关男性样本的12个Y-SNPs位点信息;采用Y filer试剂盒检测孔姓人群的17个Y-STRs基因座;应用Arlequin 3.5.1.2、Network4.6.1.1进行统计分析。结果12个Y-SNPs位点构成13种单倍群分型,孔姓人群和无关人群中最高分布频率的单倍群均为O3a2c1a-M117(21.57%,14.85%)。孔姓人群17个Y-STRs基因座构成的196种单倍型,多态性为0.993 9,单倍型14-12-25-28-19-15-12-19-12-11-12-22-12-11-14-10-19出现15次。O3-M122单倍群的中介网络树及不配对差异分析显示孔姓人群有两个中心星型分布,核苷酸不配对曲线呈单峰泊松分布。结论联合Y-SNP和Y-STR遗传标记分析表明孔姓人群存在复杂的基因交流,有多个姓氏起源,且在历史上经历过一定的扩张或持续增长,结合孔姓家谱历史分析其人群结构的遗传差异在法医学方面有潜在的应用价值。     

淮海战役士兵遗骸的Y染色体遗传类型鉴定

目的鉴定淮海战役士兵遗骸的Y染色体遗传类型,为寻找其父系亲属提供线索。方法采用古DNA的方法提取遗骸DNA,使用Yfiler试剂盒进行17个Y-STR基因座的复合扩增,推测样本的单倍群,并根据最新Y染色体谱系树挑选Y-SNP位点进行精细分型,再基于Y-SNP和Y-STR数据进行共享单倍型分析,获得与遗骸遗传关系最近的现代个体信息。结果 8份男性样本中的17个Y-STR基因座总共观察到8种Y-STR单倍型,进一步Y-SNP分析得出6种Y-SNP单倍群,分别是O2a1-M95+、O1a1-P203+、O3*-M122+/M234-、D1-M15+、C3*-ST和R1a1-M17+。结论本次对淮海战役士兵遗骸进行的Y染色体遗传类型鉴定对于推断陈年检材的地理来源具有一定的借鉴价值。     

DYS527a/b、DYF387S1a/b基因座多带与Y-SNP单倍群的关联性初探

目的 探讨DYS527a/b与DYF387S1a/b基因座多带分型与Y-SNP单倍群的关联性。方法 用YFilerPlus?试剂盒检测昆明地区DYS527a/b基因座为多带的295例无关男性样本,获取DYS527a/b、DYF387S1a/b和DYS385a/b等3个多拷贝基因座和各单拷贝基因座的基因型及其频率分布;用42个Y-SNP位点构成的AIYSNP42试剂盒对上述样本进行Y-SNP单倍群检测,探讨DYS527a/b基因座多带及其构成单倍型与相关单倍群的关联性。结果 295例样本中DYS527a/b基因座97.29%为三带分型、2.71%的为四带分型;DYF387S1a/b基因座54.24%的分型为三带、4.75%的分型为四带;DYS448基因座则检测出13.22%的分型缺失。Y-SNP位点共检测出O-M175和C-M130等7种单倍群,其中O-M175(135例)、C-M130(133例),分别为占45.76%和45.08%,而R1-M173、N-M231、D1-M174、J-M304和F-M89单倍群低于13例频率介于4.41%～0.34%之间。不同单倍群下Y-STR分型频率...     

内蒙古蒙古族人群17个Y-STR基因座频率分布及单倍型组成

目的调查17个Y-STR基因座在内蒙古蒙古族男性人群中的分布情况。方法收集184例蒙古族男性无关个体血样,Chelex-100提取DNA,PCR复合扩增17个Y-STR基因座,3130-XL全自动基因分析仪分型。结果 184例男性共检出181种不同的单倍型,其中178种为单一型,另有3种单倍型均检出2例,HD（单倍型）值为0.9998;17个Y-STR基因座座的GD值为0.4326～0.9296。结论 17个Y-STR基因座多数在内蒙古蒙古族男性人群中有较好分布,对法医学和人类群体遗传学研究具有重要价值。     

3个Y-STR的复合扩增及其单倍型

目的 建立复合扩增Y-STR基因座的体系,获得广东汉族人的单倍型频率。方法 复合扩增DYS439、DYS437和DYS434三个基因座,用聚丙烯酰胺凝胶电泳银染法进行基因分型,检测广东汉族327名无关男性个体的单倍型。结果 3个基因座分别检出6个、4个和4个等位基因,共38种单倍型,其单倍型的个体识别率为0.8796。结论 Y-STR基因座复合扩增体系和建立的Y染色体STR数据库,在法医学鉴定中有应用意义。     

甘南藏族人群17个Y-STR基因座遗传多态性

本文对中国甘肃甘南地区藏族535个男性健康无关个体进行17个Y-STR基因座遗传多态性调查。采用Chelex100法提取样本DNA,用AmpFlSTR Yfiler~(TM) PCR试剂盒进行扩增及检测。结果在17个Y-STR基因座共检出404种单倍型,单倍型型频率值在0.001 8~0.638 5之间。所调查的甘肃甘南藏族人群17个Y-STR基因座具有较好识别能力。     

南京汉族人群24个Y-STR基因座的遗传多态性

目的调查DYS391等24个Y-STR基因座在南京汉族人群的遗传多态性,考察其在法医学中的应用价值。方法应用AGCU Y-PLUS(24)PCR试剂盒对南京580名汉族无关男性个体进行Y-STR基因座扩增检测分型,用软件计算24个基因座的基因频率等群体遗传学参数,并与湖北、辽宁、广东、北京、成都汉族人群数据进行比较。结果南京580名汉族无关男性个体在24个Y-STR基因座共发现580种单倍型,各基因座的基因多样性(GD)为0.294 6~0.939 8,单倍型多样性(HD)为0.983 7。六地人群GD值的差异有统计学意义。结论 DYS391等24个Y-STR基因座在南京地区有法医学价值,可用于案件检验及家系排查。     

SNaPshot技术检测Y-SNP位点O3-M122单倍群的应用

目的采用SNaPshot技术检测案例检材O3-M122位点6个亚群的分型,并调查其在云南3个民族无关男性人群中的频率分布。方法建立5-plex Y-SNPs复合扩增体系,采用SNaPshot Multiplex试剂盒,检测案例检材O3-M122单倍群下O3*-M122、O3a*-M324、O3a3*-P201、O3a3b*-M7、O3a3c*-M134、O3a3c1*-M117共6个Y-SNPs分型,并对上述6个Y-SNPs在云南佤族、白族、傣族共174名无关男性个体中的分布进行调查。结果 17份案例检材均得到良好的分型结果。上述3个民族分别在3个、5个、5个位点上发现多态性,其中佤族O3a3*-P201分布频率最高(0.430 0);白族O3a*-M324频率最高(0.212 3);傣族O3a3c1*-M117频率最高(0.158 2)。结论多重PCR反应及SNaPshot技术的联合应用适用于法医案件检材DNA检测,3个民族多态性数据可为相关应用所参考。     

Y—STR基因座分型缺失分析

目的分析Y—STR基因座等位基因分型缺失数据,为法医学提供应用参考。方法收集浙江汉族4477名无关男性个体血样,自动工作站磁珠法提取DNA,Y—filer^TM试剂盒进行复合扩增,Gene Mapper IDv3．2分析软件分析Y-STR数据,统计出现基因分型缺失的概率。结果在4477名无关个体的Y—STR数据中,有来自23种单倍型的26个样本Y-STR分型各有1个短片段基因座的基因分型缺失,而其它长片段基因座的分型均完全正常。基因分型缺失的发生频率为0．518％。结论Y-STR基因座分型缺失具有一定的发生率,在日常检案中应注意防止误判。     

河南汉族人群27个Y-STR基因座遗传多态性

目的 调查27个Y-STR基因座在河南汉族男性人群中的遗传多态性.方法 应用Yfiler（R） Plus试剂盒,对河南地区1100名汉族男性无关个体血样进行PCR扩增,3500XL型遗传分析仪电泳检测,GeneMapper-ID-X软件进行等位基因分型.结果 1100名男性共检出1098种不同的单倍型,其中1094种为单一型,另有3种单倍型均检出2例,HD（单倍型）值为0.999995;27个Y-STR基因座的GD值为0.3833～0.9663.结论 27个Y-STR基因座多数在河南汉族男性人群中有较好分布,对法医学应用和人类群体遗传学研究具有重要价值.     

EA-YPredictor:基于Y-STR数据的家系特异性单倍群归属判别分析软件

目的Y染色体为男性所特有,其遗传标记蕴含着丰富的生物地理信息,故可溯源家系,在嫌疑人排查和追踪中发挥作用。Y-STR突变率较高,而Y-SNP突变率极低,几乎不会发生回复突变,所以后代男性群体携带祖先特有的Y-SNP。本研究期望通过现在我国Y库建设中通用的17个Y-STR的单倍型数据预测Y-SNP单倍群细支。方法基于前期观察,选取千人基因组计划III期中的513例东亚人群(中国及周边区域)作为基础数据集,在Java平台和Microsoft Excel软件框架下,以遗传距离计算和Y染色体进化树构建手段相联合研发Y-STR数据的家系特异性单倍群归属判别分析软件:EA-YPredictor。结果本研究揭示了15个单倍群大支下的核心单倍型。通过随机选取70个公开数据库样本,EA-YPredictor软件预测准确性达到92.8%(95%置信区间:[84.1%,97.6%])。结论在Y-SNP复合扩增检测尚无定论的情况下,本软件可基于二代测序样本对Y-STR数据库样本进行单倍群细支的准确预测,能适用于辅助家系单倍群判断。随着测序技术的不断换代和优化,更多高通量的Y-STR和Y-SNP数据补充将会使本软件进一步优化。此外,本软件对于Y数据库中Y-SNP遗传标记的筛查建库有一定指向作用。     

用Y-STR单倍型推断男性个体来源的分析

目的 利用17个Y-STR单倍型数据,推断分析浙江绍兴地区男性个体来源,为Y-STR数据库的建设与应用提供依据.方法 采集绍兴地区6县(市)区,104个镇(乡),1240个村的138个姓氏家族的7384份男性个体血样.采用YfilerTM复合扩增试剂盒进行17个Y-STR分型,所得数据进行县(市/区)/镇(乡/街道)/村/姓氏的组合和县(市/区)/镇(乡/街道)/村/姓氏/单倍型组合分布情况统计分析.结果 在7384份男性样本中,获得2 486种县(市/区)/镇(乡/街道)/村/姓氏组合,4957种县(市/区)/镇(乡/街道)/村/姓氏/单倍型组合,3149种Y-STR单倍型.其单倍型出现的次数从1至52次不等,其中仅出现1次的有2 471种(78.47％).对出现频率为17～ 52次的单倍型数据进行姓氏分析,发现平均有71.0％ (42.9％ ～87.5％)的人员来自同一姓氏,且在地域上多数为相邻镇或村的同姓人员.结论 利用Yfiler系统的17个Y-STR基因座单倍型数据,可以推断浙江绍兴地区男性个体的地域或姓氏来源.     

Population structure of Y chromosome SNP haplogroups in the United States and forensic implications for constructing Y chromosome STR databases

A set of 61 Y chromosome single-nucleotide-polymorphisms (Y-SNPs) is typed in a sample of 2517 individuals from 38 populations to infer the geographic origins of Y chromosomes in the United States and to test for paternal admixture among African-, European-, Hispanic-, Asian-, and Native-Americans. All of the samples were previously typed with the 11 core U.S. Y chromosome short tandem repeats (Y-STRs) recommended by SWGDAM, which revealed high levels of among ethnic group variation and low levels of among-population-within-ethnic-group variation. Admixture estimates vary greatly among populations and ethnic groups. The frequencies of non-European (3.4%) and non-Asian (4.5%) Y chromosomes are generally low in European-American and Asian-American populations, respectively. The frequencies of European Y chromosomes in Native-American populations range widely (i.e., 7-89%) and follow a West to East gradient, whereas they are relatively consistent in African-American populations (26.4+/-8.9%) from different locations. The European (77.8+/-9.3%) and Native-American (13.7+/-7.4%) components of the Hispanic paternal gene pool are also relatively constant among geographic regions; however, the African contribution is much higher in the Northeast (10.5+/-6.4%) than in the Southwest (1.5+/-0.9%) or Midwest (0%). To test for the effects of inter-ethnic admixture on the structure of Y-STR diversity in the U.S., we perform subtraction analyses in which Y chromosomes inferred to be admixed by Y-SNP analysis are removed from the database and pairwise population differentiation tests are implemented on the remaining Y-STR haplotypes. Results show that low levels of heterogeneity previously observed between pairs of Hispanic-American populations disappear when African-derived chromosomes are removed from the analysis. This is not the case for an unusual sample of European-Americans from New York City when its African-derived chromosomes are removed, or for Native-American populations when European-derived chromosomes are removed. We infer that both inter-ethnic admixture and population structure in ancestral source populations may contribute to fine scale Y-STR heterogeneity within U.S. ethnic groups.     

Forensic validation and implementation of Y-chromosome SNP multiplexes

We try to show the utility and possibility to use Y-SNP in forensic genetics. We have selected 27 Y-SNPs distributed in 4 multiplexes. The first step was seeking the minimal DNA quantity to amplify multiplexes and the second step was comparing results from Y-SNP multiplexes with results from a registered trademark Y-STR multiplex using the same sexual assault samples.     

Human Y-specific STR haplotypes in population of Serbia and Montenegro

Nine Y chromosome short tandem repeat (STR) loci (DYS19, DYS385, DYS389I, DYS389II, DYS390, DYS391, DYS392 and DYS393) were analyzed in group of 237 unrelated healthy males from population of Serbia and Montenegro in order to assess the frequencies of Y haplotypes. We observed 174 different haplotypes of which 146 (61.6%) were seen only once. Y-STR allelic frequencies in Serbia and Montenegro, in general, correspond to other European populations, except for the DYS19, DYS385 and DYS389II loci.     

Diversity of 17-locus Y-STR haplotypes in Upper (Southern) Egyptians

Seventeen Y-STR loci included in the AmpF?STR^® Yfiler™ PCR Amplification kit were typed in a population sample of 208 males from Upper (South) Egypt. Of 204 observed haplotypes, 200 were unique (96.6%) and 4 were found twice each. The 17 loci gave a discriminating power of 0.9998. DYS458 showed the highest diversity as a single-locus marker (h = 0.868) along with a high frequency of microvariants and new alleles (22% of the sample). Other loci revealed duplicated and null alleles. Comparative analysis with Y-STR datasets of relevant populations and submission of the haplotypes to the Y-STR Haplotype Reference Database (YHRD) were undertaken.     

荧光复合扩增检测3个Y—STR基因座单倍型

目的建立检测3个Y-STR基因座Y-GATA-A7.1、DYS456和DYS443的荧光复合扩增体系,并获取中国汉族人群单倍型频率分布。方法用荧光标记引物对郑州地区203名汉族男性无关个体进行3个基因座复合扩增,ABI3100型遗传分析仪检测、分型。结果Y-GATA-A7.1、DYS456和DYS443基因座分别检出5、6和6个等位基因,其基因多样性(GD值)分别为0.6692、0.5839和0.7053。三个基因座构成的单倍型共有44种,单倍型多样性(HD值)为0.9523。结论建立的3个Y-STR基因座荧光标记复合扩增系统具有很高的识别能力,可应用于法医学实践。     

Twelve short tandem repeat loci Y chromosome haplotypes: genetic analysis on populations residing in North America

A total of 2443 male individuals, previously typed for the 13 CODIS STR loci, distributed across the five North American population groups African American, Asian, Caucasian, Hispanic, and Native American were typed for the Y-STR loci DYS19, DYS385a/b, DYS389I/II, DYS390, DYS391, DYS392, DYS393, DYS437, DYS438 and DYS439 using the PowerPlex Y System. All population samples were highly polymorphic for the 12 Y-STR loci with the marker DYS385a/b being the most polymorphic across all sample populations. The Native American population groups demonstrated the lowest genetic diversity, most notably at the DYS393 and DYS437 loci. Almost all of the 12-locus haplotypes observed in the sample populations were represented only once in the database. Haplotype diversities were greater than 99.6% for the African Americans, Caucasians, Hispanics, and Asians. The Native Americans had the lowest haplotype diversities (Apaches, 97.0%; Navajo, 98.1%). Population substructure effects were greater for Y-haplotypes, compared with that for the autosomal loci. For the apportionment of variance for the 12 Y-STRs, the within sample population variation was the largest component (>98% for each major population group and approximately 97% in Native Americans), and the variance component contributed by the major population groups was less than the individual component, but much greater than among sample populations within a major group (11.79% versus 1.02% for African Americans/Caucasians/Hispanics and 15.35% versus 1.25% for all five major populations). When each major population is analyzed individually, the R(ST) values were low but showed significant among group heterogeneity. In 692 confirmed father-son pairs, 14 mutation events were observed with the average rate of 1.57x10(-3)/locus/generation (a 95% confidence bound of 0.83x10(-3) to 2.69x10(-3)). Since the Y-STR loci reside on the non-recombining region of the Y chromosome, the counting method is one approach suggested for conveying an estimate of the rarity of the Y-haplotype. Because the Y-STR loci are not all in disequilibrium to the same extent, the counting method is a very conservative approach. The data also support that autosomal STR frequencies can be multiplied by the upper bound frequency estimate of a Y-haplotype in the individual population group or those pooled into major population groups (i.e., Caucasian, African American, Hispanic, and Asian). These analyses support use of the haplotype population data for estimating Y-STR profile frequencies for populations residing in North America.