Mutations at 17 STR loci in Chinese population

Knowledge about mutation rates and the mutational process of short-tandem-repeat (STR) or microsatellite loci used in forensic analysis is crucial for the correct interpretation of resulting genetic profiles. We analysed a total of 19,754 samples from 6532 paternity testing cases at 17 STR loci which are commonly applied to forensics. The parenthood in each of these cases was highly validated (probability>99.99%). We identified 178 mutations. Locus-specific mutation rate estimates varied between 7.0 x 10(-5) and 2.2 x 10(-3), and the overall average mutation rate estimate was 8.4 x 10(-4). The observed mutational features for STRs have important consequences for forensic application such as the definition of criterions for exclusion in paternity testing and the interpretation of DNA profiles in identification analysis. In order to enrich the reference data of STRs mutations which are valuable for forensic application, we suggest the establishment of such database and ask the whole forensic community for data contribution including China.     

Y-STR mutational rates determination in South Portugal Caucasian population

Y-STR mutational rate estimation is very important for the correct evaluation of typing results in forensic casework and specially kinship genetic studies. In this work we studied 95 Southern Portuguese Caucasian father/son pairs in order to estimate mutational rates for the 17 Y-STRs multiplex used in routine casework. In a total of 1615 allele transfers three single step mutations were detected in DYS385a, DYS439, and DYS448, with an estimated mutation rate of 10,526 × 10⁻³ (95%CI 0.265 × 10⁻³ to 20.788 × 10⁻³). The estimated average mutation rate is 1.858 × 10⁻³ (95%CI 8.08 × 10⁻⁴ to 2.908 × 10⁻³). It would be important to characterize more father/son pairs in order to estimate more reliable allele specific mutation rates for the most widely used Y-STRs markers in forensic genetics.     

Autosomal and Y-STR mutations in Lithuanian population

The new approach is given in this work combines autosomal and Y-chromosomal short tandem repeats (STRs) data in paternity testing with father/son pairs taking into account mutation events. Our results show that Y-STRs can identify nonpaternity cases with high accuracy but need to be validated with autosomal STR to establish paternity. Autosomal and Y-STR mutations give disputing questions in paternity testing as well.     

云南汉族家系Y—STR基因座突变率研究

目的研究Y—filer试剂盒中DYS19等基因座在云南省汉族家系样本中的突变率。方法应用Y—filer试剂盒中的DYS456等16个Y—STR基因座对云南省30个汉族家系爷／孙、叔／侄和兄弟／堂兄弟亲权关系的106份样本进行基因分型检测,对DYS19等基因座分型与家系其他成员不同的样本分别进行了单位点的测序。结果6个（周姓、徐姓、王姓、袁姓、许姓、李姓）不同父系姓氏7例样本的10个Y—STR基因座发生突变,分别是DYS19、DYS385各2例,DYS389Ⅰ、DYS389Ⅱ、DYS390、DYS458、DYS393、DYS635各1例,总突变率为5．549‰;王姓、袁姓、许姓家系中各有1例样本分别在2个Y—STR基因座上发生了突变。结论男性家系中随机样本Y—STR基因座的突变率高于父子对样本;用Y—STR基因座进行父系亲权鉴定和男性嫌疑人的家系排查时,既使有2个Y—STR基因座分型不同时也不要轻易排除其来源于同一父系家系。     

Unexpected patterns in Y-STR analyses and implications for profile identification

Y-STR analysis is widely used in many fields, such as paternity testing, genealogy studies and in male/female mixtures. In many rape cases, Y-STRs are also useful for the determination of contributors’ number. Here we described a father/son pair with double peaks at DYS439 and DYS635 loci. This case should focus the attention on forensic interpretation of Y-haplotype profiles, because multiple alleles at various loci do not forcibly indicate that the sample originates from a mixture.We also report a case of two half-brothers with null allele at DYS448.Since DYS439 and DYS635 loci are located in the AZFa region and DYS448 locus in the AZFc region, we performed a molecular genetics study of these regions to evaluate a possible correlation between Y-STR profiles and Y chromosome deletions involved in infertility.     

Combining autosomal and Y-chromosomal short tandem repeat data in paternity testing with male child: methods and application

Paternity testing is being increasingly requested with the aim of challenging presumptive fatherhood. The ability to establish the biological father is usually based on the genotyping of autosomal short tandem repeat (STR) in alleged father, mother and child, but the use of Y-chromosomal STR has gained interest in the last few years. In this work, we propose a new probabilistic approach that combines autosomal and Y-chromosomal STR data in paternity testing with father/son pairs taking into account mutation events. We also suggest a new two-stage approach where we first type Y-STRs and possibly autosomal STR for the putative father and son, conditional on Y-STR results. We applied this approach to 22 cases. Our results show that Y-STRs can identify nonpaternity cases with high accuracy but need to be validated with autosomal STR to establish paternity. Moreover, the two-stage approach is less costly than the standard approach and is very useful in motherless cases.     

快速突变Y-STRs分子标记的法医遗传学研究进展

Y染色体短串联重复序列在性犯罪案件及父系亲缘关系鉴定中具有特殊的应用价值,但是,采用常规标准的Y-STRs尚不能区分同一父系来源的男性个体。13个快速突变Y-STRs被证明可以相对提高男性谱系分化的分辨率和同一父系男性个体的相对分离,拓展了Y-STRs在法庭科学领域的应用范围和价值。     

Evaluation of 13 rapidly mutating Y-STRs on a Dravidian pedigree

The effectiveness of a rapidly mutating Y-STRs multiplex assay (RM Y-STRs) containing 13 RM Y-STR markers was compared with the AmpFℓSTR™ Yfiler™ PCR Amplification Kit (Yfiler) with conventional Y-STR markers for their efficiency in differentiating males within the same paternal lineage. Samples from 4 generations comprising 16 Dravidian males (15 father-son pairs) were analysed with both assays. Mutations were observed in 3 father-son pairs in the RM Y-STRs profiles while only 2 mutations were observed in the Y-filer profiles. Even though not many mutations were observed as anticipated, this study still emphasised the importance of RM Y-STRs when differentiation between males within the same paternal lineage is required and also indicated the need for mutation rates for different populations.     

Analysis of mutations in father–son pairs with 17 Y-STR loci

We have examined 389 father/son sample pairs from U.S. Caucasians, African Americans, Hispanics and Asians using the 17 Y-STR loci in the Yfiler™ kit and observed a total of 24 differences between father and son. Thirteen mutations resulted in the gain of a repeat in the son and 11 resulted in a loss of a repeat. All samples resulted in single repeat mutations except one sample which contained a two repeat loss at Y-GATA-H4. Furthermore, two different sample pairs were found to have two mutations. An African American sample pair had a mutation at DYS458 and a second at DYS635 and an Asian sample pair had mutations at DYS439 and Y-GATA-H4.     

Mutation rates at 14 STR loci in the population from Pernambuco, Northeast Brazil

Definition about mutation rates of short tandem repeats (STRs) loci used in forensic analysis are useful for the correct interpretation of resulting genetic profiles and the definition of criterions for exclusion in paternity testing. Germline mutation of 14 STR loci was studied for 54,105 parent–child allelic transfers from 2575 paternity testing cases carried out during 2000–2007 from the Pernambuco State, Northeast Brazil. The parenthood in each of these cases was highly validated (probability > 99.99%). We identified 43 mutations at 12 loci. Locus-specific mutation rate estimates varied between 2 × 10⁻⁴ and 2 × 10⁻³, and the overall mutation rate estimate was 8 × 10⁻⁴. Mutation events in the male germline were more frequent than in the female germline. The majority of the mutations could be explained by losses or gains of one repeat unit and there was no evidence for selection between insertion or deletion changes. Our data were compared with those of Portuguese and North-American populations for CSF1PO, D18S51, D21S11, D7S820, TH01, TPOX and demonstrated, despite the great difference in the size of the sample, that mutation rates of STR loci in a mixed population do not differ from that encountered in different populations.     

中国汉族人群17个Y-STR基因座突变情况分析

目的 调查分析17个Y-STR基因座等位基因突变的情况.方法 收集中国汉族人群867对父子共1 649份男性血样本.采用YfilerTM复合扩增试剂盒进行17个Y-STR基因座分型,共检测出14 739次等位基因传递,统计各基因座发生等位基因突变的频率.结果 在17个基因座中发现涉及13个基因座共41次突变,其中一步突变40次(97.6％),两步突变1次(2.4％);突变共涉及40对父子,其中39对仅1个基因座发生突变(97.5％),1对同时有2个基因座发生突变(2.5％);平均突变率为2.8×10-3(95％CI 2.0～3.8×10-3).等位基因突变时获得重复单位数19次,丢失重复单位数22次,两者比例接近.结论 中国汉族人群Y-STR基因座突变可涉及多数基因座,突变率在2.8×10-3左右,在数据库的建立与应用中应重视,注意采用相关方法进行甄别.     

Validation and uses of a Y-chromosome STR 10-plex for forensic and paternity laboratories

Y-chromosome short tandem repeats (Y-STRs) provide valuable information in cases of rape and questioned paternity, and they allow for the genetic identification of male lineages. The present study validated a Y-STR 10-plex on the ABI PRISM 3100 Genetic Analyzer for use in forensic and paternity laboratories at Orchid Cellmark. Following optimization of the polymerase chain reaction, father-son pairs were analyzed to ensure that each pair generated identical haplotypes. This study demonstrated that the 10-plex is sensitive to 0.125 ng of input DNA and that female samples mixed with male samples did not interfere with Y-STR haplotyping. In a sample of 525 males, there were three instances of locus multiplication, two at DYS19 and one at DYS435. Overall, haplotype diversity was 0.996, suggesting that the 10-plex can effectively distinguish among male lineages.     

26个Y-STR基因座遗传多态性及突变调查

目的调查26个Y-STR基因座的突变率和遗传多态性,研究其法医学应用效能。方法本文以575对蒙古族父子对为模板,统计26个Y-STR基因座的突变率,并且研究26个Y-STR基因座在黑龙江省蒙古族、江西省汉族及福州市汉族等3个地区777个无关男性个体中的遗传多态性,评估该试剂盒的法医学应用价值。结果26个Y-STR基因座在575个蒙古族父子对中观察到52次突变,在46个父子对中观察到突变现象,平均突变速率为1.93×10^-3。遗传多态性研究中,黑龙江236名蒙古族检出235种分型,单倍型多样性为0.999964;323名福建汉族检测出320种分型,单倍型多样性为0.999942;218名江西汉族检测出217种分型,单倍型多样性为0.999958。结论快速突变基因座可以帮助增加系统的识别能力,但在Y-STR数据库家系查询应注意突变的影响。系统中所选择分析的基因座对该系统在法医学应用中的分辨能力至关重要,实验结果表明该体系在案件检验及数据库建设中具有良好的应用价值。     

Y-STR基因座应用于刑事案件的独特作用

目的探讨Y-STR基因座在刑事案件中的应用价值。方法采用Y-STR荧光标记复合扩增技术,结合案例应用。结果Y-STR基因座对于涉及男女混合、多名男性混合样本、性别鉴定、父权鉴定等案例中具有特有应用价值。结论Y-STR基因座可应用于法庭科学中的个体识别与同一认定,但在应用中要注意各种特例的发生。     

中国汉族人群41个STR基因座突变情况的观察分析

目的调查41个STR基因座在中国汉族人群中的突变情况。方法收集1 932个三联体家系4 546份血样本,采用AGCU_21+1、AGCU_EX22、Global Filer_Express~(TM)系统扩增41个STR基因座分型,统计各基因座发生突变的频率。结果 150个三联体在32个基因座共观察到154次突变,平均突变率为1.0×10~(-3)(95%CI:0.8~1.1×10~(-3)),突变率最高的是基因座SE33。其中一步突变152次(98.7%),两步突变2次(1.3%);146个三联体仅1个基因座发生突变(97.3%),4个三联体在2个基因座发生突变(2.7%);父、母来源突变比率约为4.7:1。结论 STR基因座等位基因突变现象较为常见,亲子鉴定时应引起注意。     

荧光复合扩增4个Y染色体STR的单倍型及其法医学应用

目的建立一套Y染色体STR的双色荧光复合扩增系统,调查4个Y-STR基因座单倍型分布情况及其在混合斑物证检验中的法医学应用前景。方法荧光标记引物复合扩增Y-GATA-A10、DYS531、DYS557和DYS448四个Y染色体特异性STR基因座,并用ABⅠ310遗传分析仪对扩增产物进行检测、分型。结果在成都汉族120名无关男性个体中,四个基因座分别检出5、5、8、7个等位基因,共检出78种单倍型,单倍型基因多样性为0.9881。对3例本教研室不能用常规常染色体STR对男性成份作出同一认定的混合斑检材,该系统成功的作出了与嫌疑人血液Y-STR基因型一致的鉴定结论。结论建立的Y-STR荧光标记复合扩增系统具有很高的识别能力,对建立Y染色体STR数据库,研究群体遗传学和进行法医学混合斑物证鉴定有重要意义。     

Haplotypes for 13 Y-chromosomal STR loci in South Tunisian population (Sfax region)

Nine Y-STR loci from the "minimal haplotype" (DYS19, DYS385a/b, DYS389I, DYS389II, DYS390, DYS391, DYS392, DYS393) included in Y-STR Haplotype Reference Databases (YHRD) with 4 additional Y-STRs (DYS436, DYS437, DYS438, DYS439) were analyzed by PCR using duplex and Y-PLEX 12 kit, followed by automatic genotyping in a sample of 105 Tunisian males originating from Sfax region (south Tunisia). Allelic frequencies and gene diversities for each Y-STR locus were determined. The high haplotype diversity (0.9932) and discrimination capacity (0.7714) show the usefulness of these loci for human identification in forensic studies and paternity tests in Tunisia. The most common haplotype was shared by 4.7% (5 individuals) of the sample was only found in samples from the Tunisian population reported in YHRD. One private allele for DYS392 (allele 17) was discovered and duplications were observed for five loci (DYS19, DYS389I, DYS393, DYS437 and DYS439).     

Analysis of non-suspect samples lacking visually identifiable sperm using a Y-STR 10-plex

Y-STRs are valuable in the investigation of sexual assaults in which autosomal STR genotype interpretation is challenging. To detect male DNA from compromised sexual assault evidence, 45 non-suspect samples were differentially extracted and analyzed with 10 Y-STRs. These samples were positive for the presence of human seminal fluid, but were negative for spermatozoa by microscopic examination. Y-STR data were obtained in approximately 86.2% of the epithelial or sperm fractions. On samples yielding incomplete profiles, results were obtained on an average of 5 loci per sample. The inability to obtain results may be due to insufficient amplifiable male DNA, PCR inhibition, or unfounded accusations of sexual assault. This study indicates that it is possible to obtain a male STR profile even in the absence of visually identifiable spermatozoa. Furthermore, Y-STR loci should become components of CODIS if they are to be used in solving non-suspect sexual assaults.     

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.     

Mutation in the STR locus D21S1 1 of father causing allele mismatch in the child

We analyzed a case of paternity dispute with 15 autosomal STR loci and found a mismatch in one of the alleles of the locus D21S11 in the child. The composition of the alleles of this locus in the mother, suspicious father, and child were 29/32, 29/29, and 29/30, respectively. The combined paternity index (2.4 x 10(10)) and paternity probability (0.9999) suggest that the suspicious father is the biological father of the child. Further analysis of 6 Y chromosome STR loci revealed matching of all the Y chromosomal alleles of the child with that of the suspicious father. Since there was a perfect match of all the paternal alleles inherited (15 autosomal and 6 Y chromosomal) in the child with that of the suspicious father except the allele D21S11, it is suggested that this might be a case of mutation. Cloning and sequencing of all the alleles of the locus D21S11 of the suspicious father, mother, and the child helped in determining that the suspicious father contributed the mutated allele.