基于等位基因特异性PCR原理建立的SNP分型新方法

目的建立一种新方法,对多个单核苷酸多态性(singlenucleotidepolymorphism,SNP)位点进行分型。方法基于等位基因特异性PCR原理,采用荧光标记复合扩增和毛细管电泳技术,根据PCR片段长度差异进行分型。选择SNP位点共11个,每个SNP位点设计两条长度不同、3’末端分别与SNP两个等位基因碱基配对的上游引物,同时为了增加特异性,在两条等位基因上游引物的3’末端第3或第4位碱基人为引入错配。在距离上游引物100～300bp范围内的合适位置,设计下游共用引物,并进行荧光标记。所有位点经过复合扩增后,PCR产物经ABIPrismTM310型遗传分析仪电泳分离,确定每个SNP的基因型。结果每个SNP位点纯合子为单一产物峰,杂合子则为长度不同的两个产物峰。不同的SNP位点扩增产物长度不同,根据产物长度和产物峰的数量进行SNP分型,一次完成11个SNP位点分型,其结果与直接测序完全一致。结论荧光标记复合扩增片段长度差异等位基因特异性PCR法是一种简单快速而有效的SNP分型新方法。     

基于通用报告引物的5个Y-SNP复合扩增及其单倍型

目的建立一种简便、经济、高效的SNP复合扩增体系,为法医学应用打下方法学基础。方法选择5个Y-SNP位点——IMS-JST164520、IMS-JST021354、IMS-JST003305、M119和M134,针对每一位点设计5′端带有通用报告引物(universal reporter primer,URP)的等位基因特异性引物,先利用等位基因特异性PCR技术扩增不同位点的等位基因片段,再利用荧光标记的URP扩增检测所有位点的等位基因。结果成功构建了5个Y-SNP荧光复合扩增体系,分型结果显示:同一SNP位点的两个不同等位基因表现为不同颜色的产物峰,不同SNP位点间等位基因片段长度不同。5个Y-SNP在武汉汉族群体中的单倍型多样性为0.8655。结论基于URP的SNP复合扩增体系具有简便、经济、高效的特点,具有较高的法医学应用价值。     

荧光标记复合扩增毛细管电泳法在SNP分型中的应用

目的采用荧光标记复合扩增毛细管电泳法，对辽南地区汉族人群13个SNP进行等位基因频率调查，并评价其法医学应用价值。方法选择13个双等位基因SNP，应用荧光标记片段长度差异等位基因特异性复合扩增SNP分型方法，对辽南地区汉族人群进行群体调查。结果每个SNP纯合子为单一产物峰，杂合子则为长度不同的两个产物峰。不同位点扩增产物长度不同，根据产物长度和产物峰数量进行SNP分型，其结果与直接测序完全一致。同时获得辽南地区汉族人群13个SNP等位基因频率。结论采用荧光标记复合扩增毛细管电泳法进行SNP分型，方法简单实用，在法医学个人识别领域具有较高的应用。     

16个线粒体DNASNP复合检测体系的建立

目的建立一种复合检测线粒体DNA（mtDNA）单核苷酸多态性（SNP）分型的方法。方法通过设计等位基因特异性引物并结合毛细管电泳分型技术平台,建立包含16个mtDNASNP位点的复合扩增检测体系。对50名汉族无关个体血样进行mtDNASNP检测,并通过直接测序法对其分型结果进行验证。结果50个样本经本检测体系复合扩增后,均得到清晰的SNP分型结果,当模板量在0．5～10pg时能得到较理想的分型图谱。样本的复合检测结果与直接测序法结果完全一致。结论建立的复合检测体系检测mtDNASNP方法灵敏度高、操作简便、分型准确,为针对mtDNA进行简便、有效的中高通量多态性分型提供了一种新方法。     

以CE-PCR产物为模板的STR序列多态分型方法

目的实现以荧光标记复合扩增产物为扩增模板的STR序列多态分型。方法筛选常用STR分型试剂盒基因座并设计引物,构建常染色体STR复合扩增体系。分别以毛细管电泳(CE)试剂盒GlobalFiler~(TM)、PowerPlex~?21和Identifiler~(TM) Plus的扩增产物为模板,扩增、建库测序及数据分析,评估体系分型准确性及对CE扩增产物的通用性,并与Precision ID GlobalFiler~(TM) NGS STR Panel体系进行比较。结果该复合扩增体系能够从3款CE试剂盒的扩增产物中获得所有基因座的正确分型和序列多态信息,其体系均衡性和杂合子均衡性亦良好,且均优于Precision ID体系。结论该复合扩增体系建立了CE技术与二代测序技术之间的桥梁,实现了检材的零利用,能够进一步挖掘荧光标记扩增产物的STR序列多态信息,是对现有技术的提升和有效补充。     

AS-PCR技术检测20个mtDNA SNP位点及单倍型频率

目的基于等位基因特异性PCR(allele-specific PCR,AS-PCR)技术,建立一种三色荧光标记复合扩增检测线粒体DNA(mtDNA)SNP的方法。方法基于AS-PCR原理,选择20个mtDNA编码区SNP位点,分为两组,分别标记FAM和HEX荧光,每个位点设计具有长度差异的两条上游(下游)等位基因特异性引物以及一条下游(上游)通用引物。结合AS-PCR技术和毛细管电泳,检测200份无关个体血样。各位点随机选取至少3个样本进行直接测序验证,并进行单倍型频率调查。结果 200份血样均得到清晰分型,各位点的检测结果与直接测序结果完全一致。10μL体系下,DNA最低检测浓度为0.2pg,当模板量为0.5~5 pg时能得到较为理想的分型图谱。在200名无关个体中,共分出15种单倍型,单倍型多样性为0.906 0。结论 AS-PCR技术是一种简单、快速且有效的mtDNA SNP分型方法,适用于法庭科学检验的需求。     

47个SNPs复合检测方法的建立及其法医学应用

目的建立47-plexSNPs复合检测方法，评价其在法医学中的应用价值。方法筛选46个常染色体SNPs和1个Y—SNPs，使用2个检测体系分别对47个SNPs进行单管内复合PCR扩增，采用荧光标记单碱基延伸法和毛细管电泳检测技术进行分型检测；并用建立的方法对260份广东地区无关个体血样进行47个SNPs分型。结果建立的47-plex SNPs的复合检测体系灵敏度高，种属特异性好；260名个体所有SNPs均能准确分型，群体内基因型频率分布均符合Hardy—Weinberg平衡，累积个人识别率大于0．9999，累积非父排除率为0．99982，累积偶合率为6．24×10一。结论本文47-plex SNPs复合检测方法能同时对47个SNPs进行快速、准确的检测，在法医学个体识别鉴定中具有良好的应用前景。     

TaqMan探针技术用于X-SNP位点的分型

目的建立一种基于TaqMan探针技术的快速、准确且经济的实时荧光PCR方法,用于检测X染色体上的单核苷酸多态性(single nucleotide polymorphism,SNP)。方法选择X染色体上的13个SNP位点(X-SNP),针对每个位点分别设计1对PCR引物和TaqMan探针,进行实时荧光PCR扩增,对X-SNP位点进行分型。结果13个位点均符合Hardy-Weinberg平衡;多态信息含量分布为0.3497～0.3750,杂合度为0.4537～0.5021。建立的方法能够用于X-SNP位点的基因分型,检测结果与DNA测序结果完全一致。结论基于TaqMan探针技术的等位基因特异的实时荧光PCR方法灵敏、简单、快速,可实现对X-SNP位点的分型检测;所选择的13个X-SNP位点具有高信息量,在法医遗传学中具有潜在的应用价值。     

19个常染色体与4个Y染色体STR复合扩增体系的建立

目的建立19个常染色体STR及Amelogenin和4个Y染色体STR基因座复合扩增体系,并对其效能进行评估。方法用五色荧光标记20＋4Y—STR基因座,建立同步扩增检测体系,用ABI3130XL遗传分析仪对扩增产物进行电泳,GeneMapperID3．2软件进行基因分型;检测体系的灵敏度、均衡性、稳定性、特异性、同一性和稳定性,并观察混合、降解及微量检材的分型情况。结果采用本文体系,DNA模板量在0．05～1．00ng时,分型准确,均衡性、特异性好;混合、降解及微量检材分型正确。该19个常染色体STR基因座的累计个人识别率大于0．999999999,三联体累计非父排除率达0．999999985,Y—STR单倍型多态性为0．592。结论本文建立的复合扩增体系分型准确,稳定,在法医学案件检验及数据库建设等方面有良好的应用前景。     

19个常染色体与4个Y染色体STR复合扩增体系的建立

目的建立19个常染色体STR及Amelogenin和4个Y染色体STR基因座复合扩增体系,并对其效能进行评估。方法用五色荧光标记20+4Y-STR基因座,建立同步扩增检测体系,用ABI 3130XL遗传分析仪对扩增产物进行电泳,GeneMapperID 3.2软件进行基因分型;检测体系的灵敏度、均衡性、稳定性、特异性、同一性和稳定性,并观察混合、降解及微量检材的分型情况。结果采用本文体系,DNA模板量在0.05~1.00ng时,分型准确,均衡性、特异性好;混合、降解及微量检材分型正确。该19个常染色体STR基因座的累计个人识别率大于0.999 999 999,三联体累计非父排除率达0.999 999 985,Y-STR单倍型多态性为0.592。结论本文建立的复合扩增体系分型准确,稳定,在法医学案件检验及数据库建设等方面有良好的应用前景。     

SNPs and MALDI-TOF MS: tools for DNA typing in forensic paternity testing and anthropology

DNA markers used for individual identification in forensic sciences are based on repeat sequences in nuclear DNA and the mitochondrial DNA hypervariable regions 1 and 2. An alternative to these markers is the use of single nucleotide polymorphisms (SNPs). These have a particular advantage in the analysis of degraded or poor samples, which are often all that is available in forensics or anthropology. In order to study the potential of SNP analysis in these fields, 41 SNPs were selected on the basis of following criteria: conservation, lack of phenotypic expression, and frequency of occurrence in populations. Thirty-six autosomal SNPs were used for genotyping 21 inclusionary and 3 exclusionary paternity cases. The behavior of 5 X-chromosome SNPs was analyzed in a French representative population. Our approach to SNP typing is a multiplex PCR based amplification followed by simultaneous detection by primer extension (PEX) analyzed by Matrix Assisted Laser Desorption Ionization Time-of-Flight Mass Spectrometry (MALDI-TOF MS). The selected autosomal SNPs showed independent inheritance and gave clear results in paternity investigation. All X-SNPs were useful as both paternity and identification markers. PEX and MALDI-TOF MS, with their high sensitivity, precision and speed, gave a powerful method for forensic and anthropological exploitation of biallelic markers.     

A 21‐Locus Autosomal SNP Multiplex and its Application in Forensic Science

To develop a cost‐effective technique for single‐nucleotide polymorphism (SNP) genotyping and improve the efficiency to analyze degraded DNA, we have established a novel multiplex system including 21‐locus autosomal SNPs and amelogenin locus, which was based on allele‐specific amplification (ASA) and universal reporter primers (URP). The target amplicons for each of the 21 SNPs arranged from 63 base pair (bp) to 192 bp. The system was tested in 539 samples from three ethnic groups (Han, Mongolian, and Zhuang population) in China, and the total power of discrimination (TPD) and cumulative probability of exclusion (CPE) were more than 0.99999999 and 0.98, respectively. The system was further validated with forensic samples and full profiles could be achieved from degraded DNA and 63 case‐type samples. In summary, the multiplex system offers an effective technique for individual identification of forensic samples and is much more efficient in the analysis of degraded DNA compared with standard STR typing.     

Forensic typing of autosomal SNPs with a 29 SNP-multiplex—Results of a collaborative EDNAP exercise

We report the results of an inter-laboratory exercise on typing of autosomal single nucleotide polymorphisms (SNP) for forensic genetic investigations in crime cases. The European DNA Profiling Group (EDNAP), a working group under the International Society for Forensic Genetics (ISFG), organised the exercise. A total of 11 European and one US forensic genetic laboratories tested a subset of a 52 SNP-multiplex PCR kit developed by the SNPforID consortium. The 52 SNP-multiplex kit amplifies 52 DNA fragments with 52 autosomal SNP loci in one multiplex PCR. The 52 SNPs are detected in two separate single base extension (SBE) multiplex reactions with 29 and 23 SNPs, respectively, using SNaPshot kit, capillary electrophoresis and multicolour fluorescence detection. For practical reasons, only the 29 SBE multiplex reaction was carried out by the participating laboratories. A total of 11 bloodstains on FTA cards including a sample of poor quality and a negative control were sent to the laboratories together with the essential reagents for the initial multiplex PCR and the multiplex SBE reaction. The total SNP locus dropout rate was 2.8% and more than 50% of the dropouts were observed with the poor quality sample. The overall rate of discrepant SNP allele assignments was 2.0%. Two laboratories reported 60% of all the discrepancies. Two laboratories reported all 29 SNP alleles in all 10 positive samples correctly. The results of the collaborative exercise were surprisingly good and demonstrate that SNP typing with SBE, capillary electrophoresis and multicolour detection methods can be developed for forensic genetics.     

Internal validation of 29 autosomal SNP multiplex using a ABI 310 genetic analyser

In the last few years genetic identification and paternity testing have begun to make increasing use of autosomal SNP (Single Nucleotide Polymorphism) typing as a supplement or alternative to STR analysis. With the improvement in detection technology SNP analysis is likely to be easier and more sensitive, with the generation of new methods and multiplex systems for a growing array of SNP markers. SNPforID consortium developed 52 SNP PCR multiplex for human identification purposes detected with 23 plex and 29 plex single base extension reactions (Auto1 and 2 respectively). In this study, internal validation for the 29 SNPs of Auto2 was carried out by performing a 29 plex PCR and single base extension reaction on control samples and previously analyzed forensic casework and subsequent detection with an AB 310 Genetic Analyzer. We tested the accuracy, precision, sensitivity and reproducibility of the Auto2 multiplex with this instrument in our laboratory. We used 9947A control DNA samples of the AmpF?STR Identifiler™ kit to test the validation parameters together with non-probative DNA samples from whole blood and buccal swab samples of 29 healthy donors from different parts of Istanbul. Good results were obtained but interpretation of the peak patterns obtained on the AB 310 requires care and thorough optimization before they can be readily compard to those obtained from multiple capillary AB 31xx Analyzers. We succesfully optimized and validated the SNPforID Auto2 multiplex system for identification analyses in our laboratory.     

A DNA microarray system for forensic SNP analysis

Forensic DNA analysis is routinely performed using polymorphic short tandem repeat (STR) markers. However, for degraded or minute DNA samples, analysis of autosomal single nucleotide polymorphisms (SNPs) in short fragments might be more successful. Furthermore, sequencing of mitochondrial DNA (mtDNA) is often performed on highly degraded or scarce samples due to the high copy number of mtDNA in each cell. Due to the increasing number of complete mtDNA genome sequences available, the limited discrimination power of an mtDNA analysis, may be increased by analysis of coding region polymorphisms in addition to the non-coding variation. Since sequence analysis of the coding region would require more material than generally present in forensic samples, an alternative SNP analysis approach is required. We have developed a one-colour microarray-based SNP detection system for limited forensic materials. The method is based on minisequencing in solution prior to hybridisation to universal tag-arrays. In a first outline of a forensic chip, a combination of 12 nuclear and 21 mitochondrial SNP markers are analysed simultaneously. The mitochondrial markers on the chip are polymorphisms within the hypervariable region as well as in the coding region. Even though the number of markers in the current system is limited, it can easily be extended to yield a greater power of discrimination. When fully developed, microarray analysis provides a promising system for efficient sensitive SNP analysis of forensic samples in the future.     

MtSNP typing before mtDNA sequencing: Why do it?

Analysis of control mitochondrial DNA (mtDNA) hypervariable regions is sometimes the only available method to study hair evidence in forensic casework although being a laborious technique. Nowadays there is a huge interest in new genetic markers such as single nucleotide polymorphisms (SNPs) to type degraded forensic samples. For that purpose, a 10-Plex mitochondrial SNP for haplogroup typing, chosen from several SNP studies and useful to study the most common populations in our laboratory was applied in forensic casework. Hair shafts from three forensic cases with different ethnic backgrounds were studied with mtDNA sequencing and compared with mitochondrial SNPs (mtSNPs) study. Coding mtSNP typing prior to sequencing can allow for a rapid screening in forensic casework, which is emphasized in the first two cases. Moreover, in cases in which mtDNA sequencing fails, mtSNPs can still be detected. This 10 SNP loci multiplex provides a less expensive and simpler method for mitochondrial typing compared to control region mtDNA sequencing, especially when used as a fast screening method.     

Validation of a 21-locus autosomal SNP multiplex for forensic identification purposes

A single nucleotide polymorphism (SNP) multiplex has been developed to analyse highly degraded and low copy number (LCN) DNA template, i.e. <100 pg, for scenarios including mass disaster identification. The multiplex consists of 20 autosomal non-coding loci plus Amelogenin for sex determination, amplified in a single tube PCR reaction and visualised on the Applied Biosystems 3100 capillary electrophoresis (CE) system. Allele-specific primers tailed with shared universal tag sequences were designed to speed multiplex design and balance the amplification efficiencies of all loci through the use of a single reverse and two differentially labelled allele denoting forward universal primers. As the multiplex is intended for use with samples too degraded for conventional profiling, a computer program was specifically developed to aid interpretation. Critical factors taken into account by the software include empirically determined extremes of heterozygous imbalance (Hb) and the drop-out threshold (Ht) defined as the maximum peak height of a surviving heterozygous allele, where its partner may have dropped out. The discrimination power of the system is estimated at 1 in 4.5 million, using a White Caucasian population database. Comparisons using artificially degraded samples profiled with both the SNP multiplex and AMPFISTR SGM plus (Applied Biosystems) demonstrated a greater likelihood of obtaining a profile using SNPs for certain sample types. Saliva stains degraded for 147 days generated an 81% complete SNP profile whilst short tandem repeats (STRs) were only 18% complete; similarly blood degraded for 243 days produced full SNP profiles but only 9% with STRs. Reproducibility studies showed concordance between SNP profiles for different sample types, such as blood, saliva, semen and hairs, for the same individual, both within and between different DNA extracts.     

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。     

A new 39-plex analysis method for SNPs including 15 blood group loci

A novel 39-plex typing system for single nucleotide polymorphisms (SNPs) has been developed. This multiplex approach has the advantage of being able to type 38 autosomal SNPs and one sex-discriminating base exchange site on the X and Y chromosomes rapidly and simultaneously. The SNP loci on the autosomes, which we examined, contain 15 loci distributed on blood type genes: three on RhCE, two each on Km and Gc, and one each on Duffy, AcP1, Tf, MN, GPT, EsD, PI, and Kidd genes. Thirty-seven genomic DNA fragments containing a total of 38 SNPs and one sex-discriminating site were amplified in one multiplex PCR reaction. Following the reaction, single nucleotide primer extension reaction was performed by dividing these SNP loci into five groups. The SNP type of each of the 39 loci was determined at one time by capillary electrophoresis using the newly designed multi-injection method. The combined PD (power of discrimination) of this typing system was (1-1.1) x 10(-14), and the MEC (mean exclusion chance) was 0.9990. We applied this system to forensic cases, including 16 paternity testing cases (13 non-exclusion and three exclusion cases) and one personal identification case. For the paternity testing cases, the highest Essen-M?ller's W-value was 0.9999995. The pM (matching probability) of the personal identification case was 2.22 x 10(-17). These data showed that this system was an excellent tool for use in forensic cases of paternity testing and personal identification.