维吾尔族mtDNA及Y-STR遗传多样性研究进展

维吾尔族是新疆主要少数民族,人类历史上诸多民族及部落对现代维吾尔族的生成都有贡献,甚至可以说他们已经融合入现代的维吾尔族人群中。现有的历史记载和考古学资料难于解释历史较近的人群动态,故需要运用其他方法手段。以PCR扩增为基础的分子遗传学方法已成为探讨人群、种族迁演乃至人类的起源和进化的主导技术。本文主要对维吾尔族mtDNA及Y-STR遗传多样性研究进展做一综述。     

Sequence polymorphisms of forensic Y-STRs revealed by a 68-plex in-house massively parallel sequencing panel

Sequence polymorphisms of Y chromosome short tandem repeat (Y-STR) markers can be unveiled using next generation sequencing (NGS). Compared to capillary electrophoresis, NGS has the advantage of distinguishing between some alleles of the same length. Here, a 68-plex in-house panel covering 67 Y-STR loci and the sex determinant Amelogenin locus, was developed. The accuracy of this panel was 100% concordant with three standard reference samples. The sensitive was as low as 250 pg. A total of 466 length-based alleles, 806 sequence-based alleles, and 149 haplotypes were observed across 149 Chinese Han individuals. The total haplotype diversity and discrimination capacity was 1.0000 in detected samples. The DYS710 locus possessed the highest diversity by sequence among these Y-STRs, with 109 sequence-based alleles observed. Micro-variant alleles with the same length were observed in 39 Y-STR loci, with their sequence variations mainly attributable to repeat pattern variations. While the number of sequence-based alleles identified for DYS447, DYS449, DYS710, DYS720 and DYF387S1a/b was approximately three times that of their length-based alleles, flanking sequence variations were observed in 18 alleles. In addition, 201 sequence-based alleles in 42 loci were newly discovered. This significantly expanded the knowledge of human Y-STR sequence polymorphisms. Collectively, the 68-plex panel provided reliable Y-STR results as well as higher resolution for paternal lineage analysis.     

Paternal genetic structure of the Qiang ethnic group in China revealed by high-resolution Y-chromosome STRs and SNPs

The Qiang population mainly lived in Beichuan Qiang Autonomous County of Sichuan Province. It is one of the nomads in China, distributed along the Minjiang River. The Qiang population was assumed to have great affinity with the Han, the largest ethnic group in China, when it refers to the genetic origin. Whereas, it is deeply understudied, especially from the Y chromosome. Here in this study, we used validated high-resolution Y-chromosome single nucleotide polymorphisms (Y-SNPs) and short tandem repeats (Y-STRs) panels to study the Qiang ethnic group to unravel their paternal genetic, forensic and phylogenetic characteristics. A total of 422 male samples of the Qiang ethnic group were genotyped by 233 Y-SNPs and 29 Y-STRs. Haplogroup O-M175 (N = 312) was the most predominant haplogroup in the Qiang ethnic group, followed by D-M174 (N = 32) and C-M130 (N = 32), N-M231 (N = 27), and Q-M242 (N = 15). After further subdivision, O2a-M324 (N = 213) accounted for the majority of haplogroup O. Haplogroup C2b-Z1338 (N = 29), D1a-CTS11577 (N = 30). O2a2b1a1a1-F42 (N = 48), O2a1b1a1a1a-F11 (N = 35), and O2a2b1a1-M117 (N = 21) represented other large terminal haplogroups. The results unveiled that Qiang ethnic group was a population with a high percentage of haplogroup O2a2b1a1a1-F42 (48/422) and O2a1b1a1a1a-F11 (35/422), and O2a2b1a1-M117 (21/422), which has never been reported. Its haplogroup distribution pattern was different from any of the Han populations, implying that the Qiang ethnic group had its unique genetic pattern. Mismatch analysis indicated that the biggest mismatch number in haplogroup O2a2b1a1a1-F42 was 21, while that of haplogroup O2a1b1a1a1a-F11 was 20. The haplotype diversity of the Qiang ethnic group equaled 0.999788, with 392 haplotypes observed, of which 367 haplotypes were unique. The haplogroup diversity of the Qiang ethnic group reached 0.9767, and 53 terminal haplogroups were observed (The haplogroup diversity of the Qiang ethnic group was the highest among Qiang and all Han subgroups, indicating the larger genetic diversity of the Qiang ethnic group.). Haplogroup O2a2b1a1a1-F42 was the most predominant haplogroup, including 11.37 % of the Qiang individuals. Median-joining trees showed gene flow between the Qiang and Han individuals. Our results indicated that 1) the highest genetic diversity was observed in the Qiang ethnic group compared to any of the former studied Chinese population, suggesting that the Qiang might be an older paternal branch; 2) the haplogroup D-M174 individuals of Qiang, Tibetans and Japanese distributed in three different subclades, which was unable to identify through low-resolution Y-SNP panel; and 3) the Qiang had lower proportion of haplogroup D compared to Yi and Tibetan ethnic groups, showing that the Qiang had less genetic communication with them than with Han Chinese.     

Origin and evolution of two Yugur sub-clans in Northwest China: a case study in paternal genetic landscape

Background: Yugur is an ethnic group that was officially identified by the Chinese Government in 1953. Within the population there are two sub-clans distinctly identified as the Eastern Yugur and Western Yugur, partly because they have different local languages.

Aim: A parentage comparison was conducted between the two sub-clans to investigate their genetic relationship.

Subjects and methods: Male subjects were chosen from the two clans to investigate their paternal genetic landscape through typing 14 single nucleotide polymorphisms (SNP) and 12 short tandem repeats (STR) of the Y chromosome.

Results: Significant differences were revealed between the sub-clans at the haplogroup level. Genetic divergence was also observed by analyses of multidimensional scaling (MDS) and principal components (PC). Genetically, the Eastern Yugur are closer to the Han Chinese and Mongolian people than the Western Yugur. The Uygur people, who share a common ancestor (ancient Huihu) with the Yugur, were genetically separate from both sub-clans of Yugur. Moreover, the constructed phylogenetic network for haplogroup O provided further evidence that the two Yugur sub-groups present an underlying genetic difference.

Conclusion: Overall, the diffusion of Mongolians during the Mongol Period has affected the Eastern Yugur more than the Western Yugur. The genetic contribution of the Han people to the Eastern Yugur seems to be more pronounced than to the Western Yugur. Besides the two different contributions referred to above, small population size and genetic drift have resulted in the genetic differentiation of the current sub-clans of Yugur.     

Fetal male lineage determination by analysis of Y-chromosome STR haplotype in maternal plasma

The aim of this study is to determine the fetus Y-STR haplotype in maternal plasma during pregnancy and estimate, non-invasively, if the alleged father and fetus belong to the same male lineage. The study enrolled couples with singleton pregnancies and known paternity. All participants signed informed consent and the local ethics committee approved the study. Peripheral blood was collected in EDTA tubes (mother) and in FTA paper (father). Maternal plasma DNA was extracted by using NucliSens EasyMAG. Fetal gender was determined by qPCR targeting DYS-14 in maternal plasma and it was also confirmed after the delivery. From all included volunteers, the first consecutive 20 mothers bearing male fetuses and 10 mothers bearing female fetuses were selected for the Y-STR analysis. The median gestational age was 12 weeks (range 12–36). All DNA samples were subjected to PCR amplification by PowerPlex Y23, ampFLSTR Yfiler, and two in-house multiplexes, which together accounts for 27 different Y-STR. The PCR products were detected with 3500 Genetic Analyzer and they were analyzed using GeneMapper-IDX. Fetuses’ haplotypes (Yfiler format) were compared to other 5328 Brazilian haplotypes available on Y-chromosome haplotypes reference database (YHRD). As a result, between 22 and 27 loci were successfully amplified from maternal plasma in all 20 cases of male fetuses. None of the women bearing female fetuses had a falsely amplified Y-STR haplotype. The haplotype detected in maternal plasma completely matched the alleged father haplotype in 16 out of the 20 cases. Four cases showed single mismatches and they did not configure exclusions; 1 case showed a mutation in the DYS 458 locus due to the loss of one repeat unit and 3 cases showed one DYS 385I/II locus dropout. All mismatches were confirmed after the delivery. Seventeen fetuses’ haplotypes were not found in YHRD and one of them had a mutation, which corresponded to the paternity probability of 99.9812% and 95.7028%, respectively. Three fetuses’ haplotypes occurred twice in YHRD, which corresponded to paternity probability of 99.9437%. In conclusion, high discriminatory fetal Y-STR haplotype could be determined from maternal plasma during pregnancy starting at 12 weeks of gestation. All male fetuses could be attributed to the alleged father male lineage early in pregnancy. The high probability of paternity associated with each case suggests that the relationship is not random and this strategy can be use as an alternative for male fetal kinship analysis.     

Forensic molecular biomarkers for mixture analysis

The deconvolution of DNA mixtures has gathered the attention of forensic DNA scientists for over two decades. To enhance mixture deconvolution capabilities, a new generation of sensitive DNA-typing approaches has been recently proposed. In this review, we describe novel, forensically relevant multi-SNP loci (i.e., microhaplotypes or microhaps), compound markers (i.e., DIP-STRs, SNP-STRs and DIP-SNPs) and lineage markers (i.e., rapidly mutating Y chromosome STRs) that improve the deconvolution of two and more than two-person mixtures typed using conventional STR, binary and non-binary loci. We explore the features and applications of these emerging molecular biomarkers with respect to their ability to forensically detect same-or-opposite sex donors. Finally, we discuss the impact of initial massively parallel sequencing (MPS) investigations of STR, microhaplotype and SNP/indel assays for DNA mixture profiling.     

Separate analysis of DYS385a and b versus conventional DYS385 typing: is there forensic relevance?

In order to determine to what extent the separate analysis of both copies of DYS385 improves Y-chromosomal short tandem repeat (Y-STR) haplotyping, we followed a recently published protocol for the separate amplification of DYS385a and DYS385b with modifications and compared the results with those obtained by conventional analysis in a population sample comprising 133 unrelated Caucasian males from Austria. Additionally, we typed all markers of the minimal haplotype (minHT) and a set of Y-chromosomal single nucleotide polymorphisms (Y-SNPs) in order to interpret the STR data depending on the Y-SNP haplogroup structure. The separate amplification of DYS385a and b improved the power of discrimination of this marker when compared to the results obtained with the conventional non-locus-discriminating amplification strategy. However, the degree of this improvement varied greatly between different haplogroups and was found to be highest in clade K. In the forensically relevant context of the minHT, the separate analysis of the DYS385 alleles had no effect on the differentiation of paternal lineages in our study. Furthermore, the amplicon lengths of 700–780 base pairs obtained in the course of the locus-discriminating approach restrict the applicability of this amplification strategy to high quality DNA samples.     

A case of double alleles at three Y-STR loci: forensic implications

In a genetic study of unrelated donors from Bahia (Brazil), one sample contained a 16 Y-STR haplotype with double peaks at three loci: DYS389 II, DYS437 and DYS439. The son of the subject had the same haplotype as found in the father. This profile was compared with a similar case found in a paternity case investigation in Madrid (Spain) and a match was found for the full 16 Y-STR haplotype. Because these three loci are located within the AZFa segment, these results are in accordance with duplication of the AZFa region that includes also other Y-STRs currently used in forensic investigation, for example DYS389I and DYS438. This case attracts our attention in the forensic interpretation of Y-haplotype profiles, because multiple alleles at various loci do not indicate forcibly that the sample under analysis is a mixture.     

High resolution mapping of Y haplogroup G in Tyrol (Austria)

The distribution of Y-chromosomal haplogroup G2a (G-P15) in present-day paternal lineages in Tyrol (Austria) was analyzed by applying a high-density regional sampling scheme that also covered remote mountain areas. There is evidence from ancient genetic data for a high frequency of Y-chromosomal haplogroup G in prehistoric populations of Central Europe, whilst nowadays levels well below 10% are routinely observed. A population sample comprising ∼3700 specimens was analyzed for Y-chromosomal variation by genotyping Y-SNPs and Y-STRs. The set of binary markers included nine SNPs specific for sub-lineages of haplogroup G. The frequency of haplogroup G in 2379 unrelated men born in Tyrol amounted to 11.3%. Nearly all of these Y chromosomes belonged to haplogroup G2a. The main sub-haplogroup within G2a was defined by the SNP L497 (G2a3b1c) and reached a population frequency of 8.6%. Although this average level is higher than reported for other countries the geographical distribution of haplogroup G-L497 showed a differentiated pattern with a clustered distribution within some alpine valleys, where maxima above 40% were found. Both, the estimation of coalescent times and a principle coordinates analysis based on R_ST values derived from Y-STR haplotypes from different sub-regions of Tyrol revealed evidence for an old settlement history associated with Y chromosomes belonging to haplogroup G in the Tyrolean Alps.     

Y chromosome STR typing in crime casework

Since the beginning of the nineties the field of forensic Y chromosome analysis has been successfully developed to become commonplace in laboratories working in crime casework all over the world. The ability to identify male-specific DNA renders highly variable Y-chromosomal polymorphisms, the STR sequences, an invaluable addition to the standard panel of autosomal loci used in forensic genetics. The male-specificity makes the Y chromosome especially useful in cases of male/female cell admixture, namely in sexual assault cases. On the other hand, the haploidy and patrilineal inheritance complicates the interpretation of a Y-STR match, because male relatives share for several generations an identical Y-STR profile. Since paternal relatives tend to live in the geographic and cultural territory of their ancestors, the Y chromosome analysis has a potential to make inferences on the population of origin of a given DNA profile. This review addresses the fields of application of Y chromosome haplotyping, the interpretation of results, databasing efforts and population genetics aspects.