ABO基因分型及其在法医学中的应用

为建立一种ABO血型系统基因分型方法，采用PCR-RFLP技术，成功地将ABO系统区分为AA，AO，AB，OO，BB，BO六种基因型。对240名中国汉族无关个体血样的ABO（基因型频率调查结果表明，6种基因型的频率分布为0．0125～0．3834，符合Hardy－Weinbeng遗传平衡法则（P＞0．1），其DP值为0．8161。家系分析表明，亲代a、b、o基因传递遵守孟德尔遗传规律。对法医学中常见的血痕、混合斑、骨组织及毛发根部等生物样品进行检测，均能准确判定ABO基因型，并可在实际案件鉴定中应用。     

运用二重PCR和DNA芯片技术检测ABO基因型

目的以玻片为载体,用寡核苷酸探针杂交技术检测ABO基因型。方法根据ABO基因座外显子6和外显子7的3个SNP点的序列分布特征设计4条寡核苷酸探针,制成分型芯片。将待测样品DNA用末端标记了Cy5的引物进行二重PCR扩增,产物与芯片上的探针进行杂交,根据杂交产生的荧光信号确定样品的ABO基因型。结果利用ABO芯片,可对血斑、毛发等微量检材进行ABO基因型检测。对115名汉族无关个体的调查表明,ABO基因型的分布符合Hardy-Weinberg平衡,等位基因杂合度观察值和期望值分别为0.591、0.616,多态信息含量为0.544,二联体和三联体非父排除率分别为0.188、0.334,个体识别能力为0.777。结论通过DNA芯片检测ABO基因型的技术适用于法医学样本,可满足高通量的检测需求。     

PCR-RFLP技术鉴定ABO基因型的法医学应用研究

目的 建立 PCR－ RFLP、非变性 PAG胶垂直电泳和银染技术进行 ABO基因分型的方法体系,并对 200名广东汉族人群 ABO基因型频率进行了调查。方法 用 Chelex－ 100和酚、氯仿抽提法处理样本, PCR扩增后用非变性聚丙烯酰胺凝胶垂直电泳和银染技术检测分型。结果 ABO位点特异性扩增片段长度为 175bp～ 210bp, 6种基因型频率分布为 0.025 0～ 0.430 0,杂合度 H值为 0.516 2,个体识别力 DP值为 0.711 1。结论 该方法可成功运用于血液、血痕、精斑、毛发、骨组织和混合斑等检材的个体识别及亲权鉴定的检验。     

PCR－RFLP技术鉴定ABO基因型的法医学应用研究

目的建立PCR－RFLP、非变性PAG胶垂直电泳和银染技术进行ABO基因分型的方法体系,并对200名广东汉族人群ABO基因型频率进行了调查。方法用Chelex－100和酚、氯仿抽提法处理样本,PCR扩增后用非变性聚丙烯酰胺凝胶垂直电泳和银染技术检测分型。结果ABO位点特异性扩增片段长度为175bp～210bp,6种基因型频率分布为0.0250～0.4300,杂合度H值为0.5162,个体识别力DP值为0.7111。结论该方法可成功运用于血液、血痕、精斑、毛发、骨组织和混合斑等检材的个体识别及亲权鉴定的检验。     

中国北方汉族和南方黎族RHCE基因分型

目的建立应用PCR技术进行RHCE基因分型的方法。方法应用序列特异性引物PCR技术(PCR-SSP)检测200例中国北方汉族、南方黎族个体的RHCE基因型,同时对5例亲子鉴定样品进行检测。结果2个民族个体RHCE基因分型结果与血清学分型结果完全一致;其中中国北方汉族RH基因型频率分布为RHCCEE1例,RHCCEe3例,RHCCee88例,RHCcEE4例,RHCcEe20例,RHCcee54例,RHccEE1例,RHccEe22例,RHccee7例;中国南方黎族RH基因型频率分布为RHCCEE2例,RHCCEe2例,RHCCee106例,RHCcEE7例,RHCcEe62例,RHCcee10例,RHccEE3例,RHccEe8例。亲子鉴定样品RHCE基因型检测结果与13个STR位点联合鉴定结论一致。结论PCR-SSP技术能准确判断中国北方汉族和南方黎族个体的RHCE基因型。     

法医SNP复合检测体系的构建及应用

目的构建48-SNP位点复合检测体系,用于个体识别、性别鉴定、ABO基因分型。方法采集225份无关个体样本(血斑及口腔拭子),18份案例样本(不同组织及体液斑),选择43个常染色体位点、4个ABO基因位点和1个性别鉴定位点,根据单碱基延伸技术通过GenomeLabTMSNPstream基因分型系统进行SNP分型;并检测体系灵敏度、同一个体不同组织同一性及模拟腐败检材。结果 48-SNP体系分型结果与测序结果的一致性为100%,最小DNA检出量为0.25ng,不同组织来源样本检测同一性很好;利用该体系检测225名无关汉族个体,所有位点均符合Hardy-Weinberg平衡,整个系统的随机匹配概率为9.4×10-18,累积非父排除率(CEP)为0.999 788,累积个体识别率大于0.999 999 999 999 999 99。结论本文48-SNP体系能同时进行个体识别、ABO基因分型和性别鉴定,可以作为现有STR检验体系的补充。     

Gc亚型检测的复合MS-PCR法及其应用

目的探讨建立Gc亚型检测的复合MS-PCR法及其应用价值。方法根据Gc基因中的2处点突变,设计2对片段相差5bp的等位基因特异性引物和1条公共引物进行复合MS-PCR,分析Gc多态性,并调查武汉地区218例汉族无关个体Gc多态性和鉴定10例亲子关系。结果复合MS-PCR检测的Gc基因型,与AmpliTypePM试剂盒的分型结果一致;武汉地区汉族人群Gc基因的3个常见等位基因Gc1F、Gc1S、Gc2的基因频率分别为0.4816、0.2592、0.2592,观察杂合度(Hobs)、期望杂合度(Hexp)、多态性信息含量(PIC)、个人识别能力(DP)、非父排除率(PE)分别为0.6193、0.6359、0.6253、0.7974、0.3480,基因型分布符合Hardy-Weinberg平衡;真三联体和非真三联体亲子鉴定各5例,前者不排除父子关系,与常规STR分型一致,后者经Gc-MS-PCR分型排除2例。结论建立复合MS-PCR法检测Gc亚型在法医物证鉴定中有实用价值。     

ABO基因分型与多重STR联合检测在法医学中的应用

目的建立ABO基因型和Goldeneye16A试剂盒联合检测的方法,并评价其在法医学实践中的应用价值。方法将6种ABO基因型(A/A,A/O,B/B,B/O,A/B,O/O)的序列特异性引物(PCR-SSP)检测方法与Goldeneye16A试剂盒相整合进行同步分型。通过对460份男性个体血痕样本、9947A DNA及90份案件样本进行检测,考察方法的一致性、灵敏度及对法庭科学检材的适用性。结果应用本文方法可同时检出6种ABO基因型和15个常染色体STR基因座及性别决定基因座,检测灵敏度为125pg,其中ABO基因检测灵敏度达63pg。460份男性血痕和90份案件检材证实该联合分型方法用于各类检材结果准确、稳定。结论本文ABO基因分型与多重STR联合检测方法,适用于各类含有核细胞的生物检材,在法庭科学DNA鉴定中有较好的应用前景。     

单管实时PCR快速检验ABO基因型

目的建立快捷特异的ABO基因分型检测方法。方法根据ABO基因结构特点,设计特异性引物和四色双链探针,采用单管实时PCR方法检测ABO基因,结果与传统免疫学方法相对比。结果该方法可检出常见的3个等位基因,区分常见的6种基因型,全部检测过程可在100min内完成。110例中国人的随机个体定型结果与传统免疫学方法一致。结论实时PCR法进行ABO基因分型,简便快捷,灵敏度高,可以有效地为侦查破案服务。     

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。     

A New Method for Human ABO Genotyping Using a Universal Reporter Primer System

Abstract: We developed a new method for forensic ABO genotyping based on a universal reporter primer (URP) system. This allows for the simultaneous detection of six single nucleotide polymorphism (SNP) sites in the ABO gene (nucleotide positions 261, 297, 526, 703, 796, and 803). This URP system provides obvious peaks, ranging from 82 to 151 bp in length. ABO genotypes were classified and successfully genotyped by our method, including minor alleles that may cause a discrepancy between the genetic data and serological phenotypes. Full profiles were identified using as little as 0.1 ng (0.05 ng/reaction) of standard K562 and 9947A DNA. Moreover, the success rate of genotyping from a URP system was much higher than that from a conventional primer extension method in degraded DNA. This method enables simple and rapid detection of multiple SNP sites on human ABO genes and is highly specific and sensitive when using limited and degraded DNA.     

Alleles responsible for ABO phenotype-genotype discrepancy and alleles in individuals with a weak expression of A or B antigens

ABO types obtained from evidentiary samples have been used effectively to obtain the initial information leading to the apprehension of culprits in Japanese criminal investigations. A simple ABO genotyping method using multiplex sequence-specific PCR and capillary electrophoresis was developed as a supplement to serological ABO typing. Limitations in predicting a phenotype based on genotype were evaluated using 1134 randomly selected Japanese peripheral blood samples. A concordance rate of 99.82% (1132/1134 samples) was found between genotypes and phenotypes defined as Groups A, B, AB, and O. Sequencing analysis revealed that one discrepant sample contained an O allele having a previously unreported point mutation at the primer binding site in exon 6, and another discrepant sample contained an O allele lacking the guanine deletion at nt 261 (the O301 allele). Therefore, the existence of such alleles must be given some consideration when predicting phenotype based on genotype.     

改良AS-PCR引物对ABO基因分型的影响

目的通过改进AS-PCR引物,提高ABO基因型分型正确率。方法把引物P13′末端第5位碱基由G改为C,其分型图谱与改进前进行对比分析。结果改进AS-PCR引物后,OO型非特异产物减少,避免了将OO型误判为AO型。结论引物P13′末端第5位碱基由G改为C后,可有效防止OO型被误判为AO型。     

ABO genotyping by mutagenically separated polymerase chain reaction

ABO blood groups were determined by the mutagenically separated polymerase chain reaction (MS-PCR). The products from two sets of PCR reactions using the same program for the nucleotides at positions 261 and 703 from cDNA at the ABO locus were used to distinguish A, B and O alleles. Two forward mutagenic allele-specific primers of different lengths for the ABO polymorphic site were paired with the same reverse primer in each PCR reaction. The 216 bp fragment of the PCR products for the 261th nucleotide was A or B allele-specific and the 195 bp fragment was O allele-specific. The 126 bp fragment of the PCR products for the 703th nucleotide was B allele-specific and the 106 bp fragment was A or O allele-specific. The ABO genotypes were determined by the intersection of the predicted alleles from these two PCR reactions. The PCR products were obtained using 10 ng of DNA in 50 μL of PCR reaction mixture, and electrophoresed in 4% agarose gel. In this study, 265 ABO-phenotype known samples (A: 31, B: 48, AB: 6 and O: 180) in Chinese were used. The results of ABO genotypes were AA: 1, AO: 30, BB: 2, BO: 46, AB: 6 and OO: 180. These results were confirmed by the PCR-RFLP ABO genotyping method. This technique is a simple, rapid, and reliable method for ABO genotyping.     

Rapid direct PCR for ABO blood typing

Many different molecular typing methods have been reported to complement routine serological ABO blood typing in forensics. However, these ABO genotyping methods are often time-consuming and call for an initial DNA isolation step that requires the use of expensive kits or reagents. We report here a rapid direct ABO genotyping method that eliminates the need for DNA extraction from fresh blood, hair, and body fluid stains before PCR. Using a fast PCR instrument and an optimized polymerase, the genotyping method-which employs a multiplex allele-specific primer set for the simultaneous detection of three single-nucleotide polymorphism (SNP) sites (nucleotides 261, 526, and 803)-identifies A, B, O01/O02, O03, and cis-AB01 alleles in around 70 min from sample collection to electropherogram. Not only will this ABO genotyping method be efficiently used in forensic practice for rapid screening of samples before full-blown multilocus short tandem repeat profiling, but it will also demonstrate an example of rapid direct genotyping of SNPs that offers the advantages of time- and cost-efficiency, convenience, and reduced contamination during DNA analysis.     

Evaluation of ABO and Lewis genotypes using primer extension preamplification

There are some difficulties with blood typing from ABO variant bloodstains and Lewis negative samples using serologic methods. In these samples, DNA analysis should be employed simultaneously to avoid errors in typing. Primer extension preamplification (PEP) produces copies of template DNA. The minimum quantity to examine nucleotide substitutions of ABO and Lewis genotypes by PCR ranged from 1 to 3 ng DNA. The PCR products with or without PEP treatment showed identical ABO and Lewis genotyping results. Performing both serologic and PCR testing served to crosscheck the ABO and Lewis grouping of such specimens. Errors in ABO and Lewis typing can be avoided as discrepancies are investigated further. The application of the PEP method to limited amounts of DNA samples for ABO and Lewis blood groupings is useful.     

ABO genotyping by duplex amplification and oligonucleotide arrays assay

Objective

Research on the application feasibility of ABO genotyping for forensic identification by oligonucleotide arrays assay.

Methods

Oligonucleotide microarrays which detect three different SNPs in exon 6 and exon 7 for ABO genotyping were used. After hybridization wash, the arrays were scanned and fluorescence intensities were analyzed using microarray population studies on ABO was carried out in a sample of 115 unrelated Chinese Han individuals oligonucleotide arrays for genotype detection. The method was also applied to cases.

Results

Technique could identify six genotypes of ABO system and the results of GeneChip analyses confirmed by PCR–RFLP. According to the results of population studies, no significant deviations Hardy–Weinberg equilibrium could be found. The observed heterozygosity (H-obs) was 0.591. Expected heterozygosity (H-exp) was 0.616. The polymorphic information content (PIC) was the average exclusion probability in paternity testing for duos (PE (1)) was 0.188. The average exclusion probability in paternity testing for trios (PE(2)) was 0.344. The discrimination power 0.777.

Conclusion

The data and case application demonstrated that ABO typing by oligonucleotide probe arrays was a useful technique for paternity testing and individual identification.