亲子鉴定中STR位点数选择及其应用价值研究

目的对在亲子鉴定中STR位点数的选择及其鉴定应用价值进行研究。方法将CODIS13个STR位点分为四个观测组,观测对象包括排除亲权的母亲-孩子-假设父亲三人组合102例,以及肯定亲权的母亲-孩子-假设父亲三人组合100例,通过310遗传分析仪对荧光复合扩增产物进行分型检测。结果各STR观察组出现的最低排除指标数与各观察组累积非父排除概率(CPE)值成一定正相关性,CPE值超过99.99%的两个STR观察组其出现的最低排除指标数为三个,同时这两个STR观察组在肯定亲权的案例分析中,其亲子关系概率值(RCP)值都超过了99.99%。结论对于亲子鉴定中的STR位点检测系统,其非父排除指标应为三个以上,其累积非父排除概率(CPE)值达到99.99%时,就可以认为该STR位点检测系统具有了相关的鉴定应用价值。     

单亲案亲权鉴定结果判定策略

目的探讨用STR基因座进行单亲鉴定出现矛盾基因座时下结论的策略。方法根据基因频率和遗传规律,推导单亲案亲权鉴定时的非父排除率。根据平均单亲非父排除率和平均突变率,用二项分布公式分别计算出现不同数目矛盾基因座时真父和假父的概率和似然率(亲权指数)。结果对STR共显性基因座,其单亲非父排除率的计算公式为:PEM=∑i=n1pi2(1-pi)2 ∑i相似文献   

The potential contribution of MVR-PCR to paternity probabilities in a case lacking a mother.

Minisatellite variant repeat (MVR) mapping using the polymerase chain reaction (PCR) was applied to a paternity case lacking a mother to evaluate the paternity probability. After three flanking polymorphic sites at each of MS31A and MS32 loci were investigated from the child and alleged father, allele-specific MVR-PCR was performed using genomic DNA. It was confirmed that one allele in the child was identical to that in the alleged father at both loci. Mapped allele codes were compared with allele structures established from population surveys. No perfect matches were found although some motifs were shared with other Japanese alleles. The paternity index and probability of paternity exclusion at these two MVR loci were then estimated, establishing the power of MVR-PCR even in paternity cases lacking a mother.     

单亲案的亲权概率的计算及认定标准

确定单亲案的亲权概率计算方法和认定标准。用多基因座DNA分析方法和计算多基因座累积平均非父排除率计算公式。检测8个以上的DNA多态性基因座,在等位基因的遗传不违反孟德尔规律的前提下,父权概率都可达到或超过0.9990的标准;对不存在亲生关系的案例,在用本方法时,都有3个或更多的基因座的等位基因遗传违反孟德尔规律。对单亲案的亲权鉴定,检测的多态性基因座要在8个以上。在肯定亲生关系时,父权概率要达到或超过0.9990;在否定亲生关系时,必须有3个以上或更多的基因座违反孟德尔遗传规律。     

复合扩增9个STR位点在亲子鉴定中的应用评估

在法医学亲子鉴定中应用复合扩增及四色荧光自动分析技术检测 Profiler plusTM9个 STR位点,一次性获得的信息量大,累计非父排除率达 0.9999。应用于 268例亲子鉴定的结果表明, 9个具有高度多态性 STR基因座的联合检测,能使三联体亲子鉴定的排除结论明确无误。对不排除案例,其 RCP值均可达国际认定标准。对二联体亲子鉴定一般需增加 CofilerTM试剂盒 4个 STR位点检测。     

MiniFiler及Yfiler试剂盒无创产前亲子鉴定的可能性探究

目的采用Mini Filer~(TM)及YFiler~(TM)试剂盒对孕妇血浆进行STR分型,评估上述试剂盒进行无创产前亲子鉴定的可行性。方法采用Mini Filer~(TM)及YFiler~(TM)试剂盒,对2例成人男性的全血及血浆进行STR分型,评估血浆检材的分型准确率及适用性;对8组已知亲子关系的孕妇家系(4组非父,4组亲父,均为男胎样本)采用Mini Filer~(TM)及YFiler~(TM)试剂盒进行STR分型,对STR分型图谱直接观察,总结归纳孕妇血浆STR图谱的特征,探讨进行无创产前亲子鉴定的可行性。结果血浆检材的STR分型结果与全血STR分型结果 100%一致,且等位基因峰高接近,表明血浆是一类可以进行STR分型的检材;观察8组孕妇血浆检材的STR分型图谱,可获得2~5个可用(含胎儿STR信息)Mini-STR位点,1~8个可用Y-STR位点,且在位点充足的情况下(6个),肯定父权家系可计算累计父权指数达192 653,否定父权家系中有3~7个位点支持否定父权。结论采用Mini Filer~(TM)及Yfiler~(TM)试剂盒对孕妇血浆进行STR分型,存在进行无创产前亲子鉴定的可能性。     

联合应用常染色体STR和X-STR标记鉴定单亲疑难案例

目的通过对常染色体和X染色体遗传标记的检测,探讨单亲疑难案例的鉴定策略。方法提取3个单亲鉴定案例的6份血样,采用Goldeneye 20A试剂盒和AGCU21＋1试剂盒检测常染色体上39个STR基因座,采用自主研制的16重X-STR扩增系统检测X染色体上16个STR基因座。结果用Goldeneye 20A试剂盒检测后发现每个单亲案例均有一个基因座不符合遗传规律,当常染色体STR基因座增加到39个时,案例1累计出现3个矛盾基因座;案例2和案例3均没有出现新的矛盾基因座。X染色体STR分型结果显示案例1有8个矛盾基因座,案例2和案例3无矛盾基因座,与常染色体分型结论相符。结论对于出现单基因座不符合遗传规律的母女、母子、父女单亲案例鉴定,不仅可以增加新的常染色体STR检测,也可以增加X染色体STR的检测,这样在相互验证的同时也能获得更加可靠的鉴定意见。     

Intentional mixed buccal cell reference sample in a paternity case

We report a case where an alleged father (AF) attempted to substitute someone else's saliva sample for his reference sample in a paternity analysis. Buccal cells were collected from the AF and the child, and DNA analysis was performed using an autosomal STR loci (Identifiler). The profile from the AF showed extra peaks in some loci, as well as a much higher "X" allele peak relative to the "Y" allele peak at the amelogenin locus. After conducting reanalysis by another technician with another set of positive and negative controls, it was concluded that the only source of the mixed profile was by intentional introduction by the AF, at the time of sampling, of some foreign human biological material, most likely saliva from a woman. Owing to the inconclusive results, when the AF was called back to the lab and the peculiar results were explained to him, he admitted that he had introduced into his mouth saliva from another person in an attempt to be excluded as the father of the child. Although tampering with DNA reference samples is not common, some individuals may attempt to contaminate or otherwise adulterate specimens before DNA tests. Personnel responsible for sampling should be aware of this possibility and should try to establish procedures to avoid the problem.     

海南汉族人群19个STR基因座遗传多态性及其应用

目的建立海南地区汉族人群19个常染色体STR基因座的遗传多态性数据资料,并探讨此19-STR基因座系统在亲子鉴定中的应用。方法对海南汉族462例无血缘关系个体,采用Goldeneye~(TM) 20A系统复合扩增并检测,得到19个STR基因座的遗传数据信息;在283例亲子鉴定案例中,评价19-STR基因座系统的应用。结果 19个STR基因座的基因频率分布均符合Hardy-Weinberg平衡(P0.05),杂合度在0.603~0.914之间,累积个体识别率大于0.999 999 999 999 999,累积三联体非父排除率为0.999 999 994。283例亲子鉴定中,三联体170例,二联体113例;认定案例247例(87.3%),排除案例36例(12.7%);发生等位基因突变案例14例(4.9%),均为一步突变。结论 19个STR基因座中的14个基因座具有高度遗传多态性,19-STR基因座复合扩增分型系统具有较高的非父排除效能,可满足海南地区亲子鉴定的需要,同时应注意亲子鉴定中的基因突变现象。     

亲权指数计算的新方法

目的介绍一种亲权指数（paternity index,PI）计算的新方法。方法假定亲代的等位基因都要经过一个转变的过程才发生分离并遗传给子代。每个亲代的等位基因与子代相同时,其转变概率为1;当不相同时,其转变概率为0。且每个亲代的等位基因都有1/2的机会遗传给子代。据此,可以计算出孩子从争议父或母亲获得等位基因的概率。而随机男子提供等位基因给孩子的概率为等位基因频率。相应地算出PI值公式中的分子（X）和分母（Y）值。结果推导得到了一个能够计算三联体、二联体和失踪孩子案PI值的通用计算公式。结论本PI计算公式在亲子鉴定PI值计算上具有实用价值。     

15个STR在单亲亲子鉴定中的排除分析

目的评估15个短串联重复(DODIS)基因座和Penta D、Penta E)在单亲亲子鉴定中的亲权排除率。方法 以644个随机个体构成207046个假想的家系,然后统计不排除或只有一个基因座排除亲权关系的例数。结果有27个假想家系15个STR均不排除亲权关系,排除率为0.999869。有384个假想家系只有一个基因座排除,占0.185％。结论用15个STR认定单亲案的亲权关系时要谨慎。出现单个基因座排除时要检测更多的遗传标记,以区分是否系突变。     

Possible pitfalls in motherless paternity analysis with related putative fathers

Nowadays, more and more paternity cases are carried out investigating only child and putative father, mostly for economical or private reasons. Usually, reliable results can be obtained and the putative father can be included or ruled out with a high certainty. Considerable problems might arise when a relative of the biological father is investigated as being the putative father. In this study, we investigated 164 persons from 27 families creating artificial deficiency cases using the AmpFlSTRIdentifiler kit, which amplifies 15 STRs simultaneously. We analyzed 93 child/biological father pairs and the corresponding uncles, respectively the brothers of the biological fathers. The average paternity probability for the biological father was 99.9699% (paternity index (PI): 3321.26); only in three cases the results were under 99.9%. In five out of 125 child/uncle pairs no STR mismatches were found and paternity probabilities between 99.9726% (PI 3652) and 99.9970% (PI 33,545) were calculated. The average number of excluding loci was 3.4, but in 31.2% of the cases only zero, one or two mismatches were found. When both putative fathers were genetically typed, the biological father usually had a statistically higher paternity probability. Nevertheless, the differences between probabilities for father and uncle were only small. These results show that a reliable investigation of deficiency cases (i.e. child and putative father) seems to be more difficult than generally assumed. Especially in cases with an unknown familiar background and/or when investigating foreigners for immigration purposes, the laboratory expert should include the mother, increase the number of investigated loci or include a second method such as RFLP-analysis, some serological systems or typing of X-chromosome specific STRs to further ascertain the results.     

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.     

PowerPlex21 系统在亲子鉴定中的应用评估

目的评估PowerPlex21系统20个STR基因座在亲子鉴定中的检验能力。方法用PowerPlex21系统检测1 704例亲子鉴定,评估该系统在亲子鉴定中的排除能力和突变率。结果采用PowerPlex21系统,累积非父排除率和累积个体识别力均大于0.999 999 999 999 999 999 999 999 999 999。1704例亲子鉴定中有265例排除亲子关系,最常见为8~10个基因座排除;44例表现为1个STR基因座突变。结论 PowerPlex21系统用于亲子鉴定是高效的。     

A single mutation in the FGA locus responsible for false homozygosities and discrepancies between commercial kits in an unusual paternity test case

We report an unusual paternity test case showing multiple peculiarities. Using AmpFlSTR Profiler Plus and AmpFlSTR Identifiler PCR Amplification kits, the alleged father and the two children were apparently homozygous at the FGA locus, but using the PowerPlex 16 kit the three individuals were found to be heterozygous. Drop-out was caused by a single mutation event in the presumptive binding site of the reverse primer. In addition, three inconsistencies were detected between the daughter and the alleged father among 18 STR markers. The occurrence of the rare null allele at the FGA locus and case history suggested that the true father was the brother of the alleged father. Furthermore, a single-step repeat maternal mutation was also detected at D16S539. This puzzling case was solved by using multiple analytical approaches, including the use of different primer pairs, the use of a high number of STR markers, and the characterization of the mutation causing the "null allele."     

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。     

Parentage of Hydatidiform Moles

We were presented with the STR (short tandem repeat) profiles from two separate paternity trios. Each trio consisted of a mother, an alleged father, and products of conception (POC) that contained a hydatidiform mole but no visible fetus. In both cases , antecedent pregnancies had followed alleged sexual assaults. Mole classification and pathogenesis are described in order to explain the analyses and statistical reasoning used in each case. One mole exhibited several loci with two different paternal alleles, indicating it was a dispermic (heterozygous) mole. Maternal decidua contaminated the POC, preventing the identification of paternal obligate alleles (POAs) at some loci. The other mole exhibited only one paternal allele/locus at all loci and no maternal alleles, indicating it was a diandric and diploid (homozygous) mole. In each case, traditional calculations were used to determine paternity indices (PIs) at loci that exhibited one paternal allele/locus. PIs at mole loci with two different paternal alleles/locus were calculated from formulas first used for child chimeras that are always dispermic. Combined paternity indices in both mole cases strongly supported the paternity of each suspect.     

VNTR D17530位点多态性在亲子鉴定中的应用

运用微量热启动PCR技术,对20例正常家系的遗传学分析,证实D17530位点的遗传符合孟德尔遗传规律,表现为简单的共显性遗传。同时,对100例亲子鉴定案例进行回顾性分析研究,证明D17S30位．在多态性可应用于我国法医学亲子鉴定。根据D17S30位点基因频率估算的排除概率（74．04％）与其实际排除能力（80．00％）无显著差异。在15倒排除亲子关系的案例中,有2例由D17S30位点单独取得排除证据。D17S30位点是法医学上有重要意义的遗传学标记,可用于亲子鉴定。     

D6S1043和D12S391基因座在亲权鉴定中的应用

目的研究D6S1043和D12S391基因座在亲权关系鉴定案件中的应用价值。方法应用荧光标记复合扩增系统对日常检案中所收集的192名汉族无关个体血样DNA进行PCR扩增,用ABI3100-Avant遗传分析仪对扩增产物进行毛细管电泳,用GeneMapperv3.2软件进行基因分型,统计分析D6S1043和D12S391基因座的多态信息。结果在D6S1043和D12S391基因座分别发现12个等位基因,它们在中国汉族人群中的个体识别能力分别为0.9656和0.9510,二联体非父排除率分别为0.573和0.510,三联体非父排除率分别为0.731和0.679。结论D6S1043和D12S391基因座具有高度多态性,在亲权鉴定中具有重要应用价值。     

二联体亲权鉴定风险分析

目的探讨二联体亲权鉴定时存在的风险。方法选取22组经Goldeneye~(TM) 20A试剂盒检测后只有一个或没有不符合基因座的无关个体对构建假想家系。对其增加检测STRtyper-10G和/或AGCU 21+1 STR系统直至所有组不符合基因座个数大于3个,累积父权指数(CPI)不大于0.000 1。以三种规则:(1)不符合基因座数大于3个;(2)CPI值小于0.000 1;(3)同时满足(1)和(2),作为排除依据,使用不同数量的基因座(19个、26个、39个和46个)进行检测,讨论无关个体对的排除情况是否存在差异。结果 22组无关个体对,使用19个基因座和39个基因座以上的检测系统达到排除结果的分别为0组和22组。结论二联体亲子鉴定,使用19个基因座进行检测仍存在结果错判,39个基因座以上的检测系统能更有效的避免二联体的鉴定风险。