基于Luminex悬浮芯片的鼠疫耶尔森菌SNP分型方法研究

目的利用Luminex悬浮芯片技术,基于单核苷酸多态性（single nucleotide polymorphism,SNP）建立我国鼠疫耶尔森菌东方型菌株（以下简称东方型鼠疫菌）的基因分型方法,为进一步研究东方型鼠疫菌多态性并分析其系统发育关系奠定基础。方法利用多重PCR,同时扩增东方型鼠疫菌中18个具有分型意义的SNP位点,扩增产物进行多重等位基因特异性引物延伸（allele specific primer extension,ASPE）反应以及Luminex悬浮芯片技术分析,随后利用MasterPlex GT V2.3软件计算平均荧光强度（median fluorescence intensity,MFI）比值,判断各SNP位点的碱基状态;并对SNP分型方法的重现性进行评价。结果 Luminex多重SNP技术能够快速、高通量地检测出各SNP位点的MFI值,从而在8 h内一次性成功确定东方型鼠疫菌中18个SNP的碱基状态;36株东方型鼠疫菌基于18个SNP可以分为7个基因型。结论本文建立的Luminex多重SNP检测方法作为一种高通量检测SNP的技术平台,为后期的东方型鼠疫菌SNP分型及系统发育分析奠定了基础。     

Genetic variability of the SNPforID 52-plex identification-SNP panel in Central West Colombia

A set of autosomal single nucleotide polymorphism (SNP) loci was analyzed using the 52-plex assay previously described by Sanchez et al. [J.J. Sanchez, C. Phillips, C. Borsting, K. Balogh, M. Bogus, M. Fondevila, C.D. Harrison, E. Musgrave-Brown, A. Salas, D. Syndercombe-Court, P.M. Schneider, A. Carracedo, N. Morling, A multiplex assay with 52 single nucleotide polymorphisms for human identification, Electrophoresis 27 (2006) 1713–1724] in 140 samples of unrelated individuals born in the Colombian regions of, Risaralda, Caldas, Quindio, Antioquia, Tolima and Valle, and 164 samples of unrelated individuals with declared Native American ancestry from Colombia. Allele frequencies and statistical parameters of forensic interest are presented for the 52 SNPs. All loci were in agreement with Hardy–Weinberg equilibrium while comparisons with population samples of Argentina, Portugal, Spain, Mozambique, and Taiwan revealed significant differences in allele frequency distributions.     

Y-SNP miniplexes for East Asian Y-chromosomal haplogroup determination in degraded DNA

Four multiplex PCR systems followed by single base extension reactions were developed to score 22 single nucleotide polymorphisms (SNPs) and identify the most frequent East Asian Y chromosome haplogroups. Select Y chromosome SNPs allowed hierarchical testing for almost all of the major East Asian haplogroups along the revised Y chromosome tree. The first multiplex consists of six SNPs defining world-wide major haplogroups (M145, RPS4Y₇₁₁, M89, M9, M214, and M175). The second multiplex includes six SNPs of subhaplogroup O (M119, P31, M95, SRY₄₆₅, 47z, and M122). The third multiplex contains six SNPs that subdivide the subhaplogroup O3 (M324, P201, M159, M7, M134, and M133). The fourth multiplex comprises four SNPs of subhaplogroup C (M217, M48, M407, and P53.1). The sizes of the PCR amplicons ranged from 70 to 100 bp to facilitate their application to degraded forensic and ancient samples. Validation experiments demonstrated that the multiplexes were optimized for analysis of low template DNA and highly degraded DNA. In a test using DNA samples from 300 Korean males, 16 different Y chromosome haplogroups were identified; haplogroup O2b* was the most frequently observed (29.3%), followed by haplogroups C3 (xC3c, C3d, C3e) (16.0%) and O3a3c1 (11.0%). These multiplex sets will be useful tools for Y-chromosomal haplogroup determination in anthropological and forensic studies of East Asian populations.     

Evaluation of the 124-plex SNP typing microarray for forensic testing

Human identification systems such as criminal databases, forensic DNA testing and genetic genealogy require reliable and cost-effective genotyping of autosomal, mitochondrial and Y chromosome markers from different biological materials, including venous blood and saliva. Although many such assays are available, few systems are capable of simultaneously detecting all three targets in a single reaction. Employing the APEX-2 principle, we have characterized a novel 124-plex assay, using specific primer extension, universal primer amplification and single base extension on an oligonucleotide array. The assay has been designed for simultaneous genotyping of SNPs from the single copy loci (46 autosomal and 29 Y chromosomal markers) side by side with SNPs from the mitochondrial genome (49 markers) that appears in up to thousands of copies per cell in certain tissue types. All the autosomal SNPs (from the SNPforID Consortium) included in the multiplex assay are unlinked and are distributed widely across autosomes, enabling genetic fingerprints to be distinguished. Mitochondrial DNA and Y chromosome polymorphisms that define haplogroups common in European populations are included to allow for maternity and paternity testing and for the analysis of genetic genealogies. After assay optimization we estimated the accuracy (99.83%) and call rate (99.66%) of the protocol on 17 mother–father–child/children families and five internal control DNAs. In addition, 79 unrelated Estonian and Swedish DNA samples were genotyped and the accuracy of mtDNA and Y chromosome haplogroup inference by the multiplex method was assessed using conventional genotyping methods and direct sequencing.     

Forensic validation of the SNPforID 52-plex assay

The advantages of single nucleotide polymorphism (SNP) typing in forensic genetics are well known and include a wider choice of high-throughput typing platforms, lower mutation rates, and improved analysis of degraded samples. However, if SNPs are to become a realistic supplement to current short tandem repeat (STR) typing methods, they must be shown to successfully and reliably analyse the challenging samples commonly encountered in casework situations.The European SNPforID consortium, supported by the EU GROWTH programme, has developed a multiplex of 52 SNPs for forensic analysis, with the amplification of all 52 loci in a single reaction followed by two single base extension (SBE) reactions which are detected with capillary electrophoresis.In order to validate this assay, a variety of DNA extracts were chosen to represent problems such as low copy number and degradation that are commonly seen in forensic casework. A total of 40 extracts were used in the study, each of which was sent to two of the five participating laboratories for typing in duplicate or triplicate. Laboratories were instructed to carry out their analyses as if they were dealing with normal casework samples. Results were reported back to the coordinating laboratory and compared with those obtained from traditional STR typing of the same extracts using Powerplex^® 16 (Promega). These results indicate that, although the ability to successfully type good quality, low copy number extracts is lower, the 52-plex SNP assay performed better than STR typing on degraded samples, and also on samples that were both degraded and of limited quantity, suggesting that SNP analysis can provide advantages over STR analysis in forensically relevant circumstances. However, there were also additional problems arising from contamination and primer quality issues and these are discussed.     

A SNaPshot of next generation sequencing for forensic SNP analysis

Forensic phenotyping can provide useful intelligence regarding the biogeographical ancestry (BGA) and externally visible characteristics (EVCs) of the donor of an evidentiary sample. Currently, single nucleotide polymorphism (SNP) based inference of BGA and EVCs is performed most commonly using SNaPshot^®, a single base extension (SBE) assay. However, a single SNaPshot multiplex PCR is limited to 30–40 SNPs. Next generation sequencing (NGS) offers the potential to genotype hundreds to thousands of SNPs from multiple samples in a single experimental run. The PCR multiplexes from five SNaPshot assays (SNPforID 52plex, SNPforID 34plex, Eurasiaplex, IrisPlex and an unpublished BGA assay) were applied to three different DNA template amounts (0.1, 0.2 and 0.3 ng) in three samples (9947A and 007 control DNAs and a male donor). The pooled PCR amplicons containing 136 unique SNPs were sequenced using Life Technologies’ Ion Torrent™ PGM system. Approximately 72 Mb of sequence was generated from two 10 Mb Ion 314™ v1 chips. Accurate genotypes were readily obtained from all three template amounts. Of a total of 408 genotypes, 395 (97%) were fully concordant with SNaPshot across all three template amounts. Of those genotypes discordant with SNaPshot, six Ion Torrent sequences (1.5%) were fully concordant with Sanger sequencing across the three template amounts. Seven SNPs (1.7%) were either discordant between template amounts or discordant with Sanger sequencing. Sequence coverage observed in the negative control, and, allele coverage variation for heterozygous genotypes highlights the need to establish a threshold for background levels of sequence output and heterozygous balance. This preliminary study of the Ion Torrent PGM system has demonstrated considerable potential for use in forensic DNA analyses as a low to medium throughput NGS platform using established SNaPshot assays.     

Evaluation of the Precision ID Identity Panel for the Ion Torrent™ PGM™ sequencer

In cases where only a partial or incomplete STR profile is obtained from a sample, information contained in single nucleotide polymorphisms (SNPs) can prove informative for human identification. Thermo Fisher Scientific, which developed the high throughput Ion Torrent^™ PGM^™ sequencer, released the Precision ID Identity Panel, a multiplex SNP panel for human identity. We evaluated the reproducibility and sensitivity of this multiplex, which contains primers for the amplification of 90 autosomal SNPs and 34 Y-clade SNPs. The manufacturer’s protocol was tested using five commercially available pure native DNAs and six forensic type samples at a range of DNA input amounts (0.2–1.0 ng; n, 90). In addition to analyzing the data using the manufacturer’s software, HID SNP Genotyper (v4.3.1), we also used CLC Genomics Workbench (Qiagen). Although library yields and templating of ion sphere particles (ISPs) were low, downstream sequencing was still successful. Across all samples, only 1.5% of all possible quality control (QC) flags were raised by both the plugin QC filter and CLC; 85% of those flags were raised as the SNP had a major allele frequency outside the thresholds specified by the manufacturer. For the remaining SNPs, coverage of >1500 X and >780 X was obtained for autosomal and Y-clade SNPs respectively, and 100% congruence among genotype calls from both analysis programs was observed. Our results demonstrate that it is possible to obtain reliable and reproducible genotypes using the Precision ID Identity Panel, when using low quantities (≥0.2 ng) of either pure native DNA or forensic type DNA samples.     

A 21 marker insertion deletion polymorphism panel to study biogeographic ancestry

Insertion/deletion polymorphisms have recently received increased interest in the forensic genetics community. This class of markers combines the advantageous genetic properties of single nucleotide polymorphisms (i.e., low mutation rate, genetic stability, and short amplicon size) with the technical advantage of short tandem repeat markers (simple detection by fluorescence-labelled PCR and capillary electrophoresis). For a large number of indel markers significant differences in allele frequencies between the major populations have been reported, making this class of markers suitable for the analysis of biogeographic ancestry. We have developed a multiplex PCR assay designed to establish the biogeographic ancestry of forensic DNA samples based on insertion/deletion polymorphisms. A panel of 21 short indels with allele frequency differences between three major population groups (European, African and Asian) was selected to be incorporated into a single-tube multiplex PCR assay. The assay is highly sensitive, requiring less than 0.5 ng of genomic DNA for successful typing. Due to the short fragment lengths below 200 bp, the assay is ideally suited for the typing of challenging forensic genetic case work samples. A population genetic study has been performed proving the performance of the assay in inferring the ancestral population of individuals. The chosen 21 markers are sufficient to distinguish between three major global population groups. Furthermore, the assay design leaves room for an extension in order to cover additional population groups.     

Massively parallel sequencing analysis of nondegraded and degraded DNA mixtures using the ForenSeq™ system in combination with EuroForMix software

Massively parallel sequencing (MPS) technologies enable the simultaneous analysis of short tandem repeats (STRs) and single nucleotide polymorphisms (SNPs). MPS also enables the detection of alleles of the minor contributors in imbalanced DNA mixtures. In this study, 59 STRs (amelogenin, 27 autosomal STRs, 7 X-STRs, and 24 Y-STRs) and 94 identity-informative SNPs of 119 unrelated Taiwanese (50 men, 69 women) were sequenced using a commercial MPS kit. Forty-eight nondegraded and 44 highly degraded two-person artificial DNA mixtures with various minor to major ratios (1:9, 1:19, 1:29, 1:39, 1:79, and 1:99) were analyzed to examine the performance of this system for detecting the alleles of the minor contributors in DNA mixtures. Likelihood ratios based on continuous model were calculated using the EuroForMix for DNA mixture interpretation. The STR and SNP genotypes of these 119 Taiwanese were obtained. Several sequence variants of STRs were observed. Using EuroForMix software based on the sequence data of autosomal STRs and autosomal SNPs, 97.9% (47/48) and 97.7% (42/43) of minor donors were accurately inferred among the successfully analyzed nondegraded and degraded DNA mixtures, respectively. In conclusion, combined with EuroForMix software, this commercial kit is effective for assignment of the minor contributors in nondegraded and degraded DNA mixtures.

     

Independent validation of body fluid-specific CpG markers and construction of a robust multiplex assay

Potential forensic use of tissue-specific DNA methylation markers has recently been discussed for the identification of the biological source of a stain. In this study 13 promising markers were evaluated to identify suitable candidate markers for the development of a robust and reliable multiplex assay. The results of this study suggest that a combination of only four highly informative markers will be enough for clear body fluid identification. A multiplex assay was developed for the identification of menstrual blood, saliva, semen, and venous blood. This assay was successfully applied to the identification of these body fluids in mixtures and crime scene stains. The multiplex assay aids in the identification of not only single source body fluids but also of body fluid mixtures. The main advantage of using DNA methylation assays over alternative tests is that it can be applied at a later time point in the investigative process since testing is possible even after DNA analysis.     

Comparison of the genetic background of different Colombian populations using the SNPforID 52plex identification panel

Various strategies for analysing SNP markers and genotyping have been published with the goal of obtaining informative profiles from biological samples that contain only small amounts of template and/or degraded DNA. In this study, a multiplex assay of 52 autosomal single-nucleotide polymorphisms (SNPs) was used to analyse 438 individuals from urban populations from different regions of Colombia, as well as a sample of 50 Native American individuals of the Pastos ethnic group from Nariño. To determine if significant differences in these 52 SNPs exist between the distinct regions of Colombia, genetic distance and admixture analyses were performed based on the available data for 17 different Colombian population groups and for population groups from Africa, Europe and America. The results demonstrate significant differences between the populations from the Southwest Andean, Central-West Andean, Central-East Andean, Orinoquian and northern Colombian Pacific Coast regions. Most of the regions exhibited a European and Native American admixture. One exception is the population from the region of Chocó (on the northern Pacific Coast), which exhibits a high proportion of African admixture (54 %). From the observed genetic backgrounds, it is possible to conclude that a single reference database for the entire country would not be suitable for forensic purposes. The allele frequencies and the forensically relevant parameters were calculated for all of the markers in each Colombian region with significant values for the combined matching probability (power of discrimination ≥0.99999999999999990) and the combined probability of exclusion (≥0.9990) in trios that were obtained from all of the population groups.     

Tetra-allelic SNPs: Informative forensic markers compiled from public whole-genome sequence data

Multiple-allele single nucleotide polymorphisms (SNPs) are potentially useful for forensic DNA analysis as they can provide more discrimination power than normal binary SNPs. In addition, the presence in a profile of more than two alleles per marker provides a clearer indication of mixed DNA than assessments of imbalanced signals in the peak pairs of binary SNPs. Using the 1000 Genomes Phase III human variant data release of 2014 as the starting point, this study collated 961 tetra-allelic SNPs that pass minimum sequence quality thresholds and where four separate nucleotide substitution alleles were detected. Although most of these loci had three of the four alleles in combined frequencies of 2% or less, 160 had high heterozygosities with 50 exceeding those of ‘ideal’ 0.5:0.5 binary SNPs. From this set of most polymorphic tetra-allelic SNPs, we identified markers most informative for forensic purposes and explored these loci in detail. Subsets of the most polymorphic tetra-allelic SNPs will make useful additions to current panels of forensic identification SNPs and ancestry-informative SNPs. The 24 most discriminatory tetra-allelic SNPs were estimated to detect more than two alleles in at least one marker per profile in 99.9% of mixtures of African contributors. In European contributor mixtures 99.4% of profiles would show multiple allele patterns, but this drops to 92.6% of East Asian contributor mixtures due to reduced levels of polymorphism for the 24 SNPs in this population group.     

Techniques for estimating genetically variable peptides and semi-continuous likelihoods from massively parallel sequencing data

Forensic genetic investigations typically rely on analysis of DNA for attribution purposes. There are times, however, when the amount and/or the quality of the DNA is limited, and thus little or no information can be obtained regarding the source of the sample. An alternative biochemical target that also contains genetic signatures is protein. One class of genetic signatures is protein polymorphisms that are a direct consequence of simple/single/short nucleotide polymorphisms (SNPs) in DNA. However, to interpret protein polymorphisms in a forensic context, certain complexities must be understood and addressed. These complexities include: 1) SNPs can generate 0, 1, or arbitrarily many polymorphisms in a polypeptide; and 2) as an object of expression that is modulated by alleles, genes and interactions with the environment, proteins may be present or absent in a given sample. To address these issues, a novel approach was taken to generate the expected protein alleles in a reference sample based on whole genome (or exome) sequence data and assess the significance of the evidence using a haplotype-based semi-continuous likelihood algorithm that leverages whole proteome data. Converting the genomic information into the proteomic information allows for the zero-to-many relationship between SNPs and GVPs to be abstracted away. When viewed as a haplotype, many GVPs that correspond to the same SNP is equivalent to many SNPs in perfect linkage disequilibrium (LD). As long as the likelihood formulation correctly accounts for LD, the correspondence between the SNP and the proteome can be safely neglected. Tests were performed on simulated samples, including single-source and two-person mixtures, and the power of using a classical semi-continuous likelihood versus one that has been adapted to neglect drop-out was compared. Additionally, summary statistics and a rudimentary set of decision guidelines were introduced to help identify mixtures from protein data.     

Evaluation of the Genplex SNP typing system and a 49plex forensic marker panel

Using a 52 SNP marker set previously developed for forensic analysis, a novel 49plex assay has been developed based on the Genplex typing system, a modification of SNPlex™ chemistry (both Applied Biosystems) using oligo-ligation of pre-amplified DNA and dye-labeled, mobility modified detection probes. This gives highly predictable electrophoretic mobility of the allelic products generated from the assay to allow detection with standard capillary electrophoresis analyzers. The loci chosen comprise the 48 most informative autosomal SNPs from the SNPforID core discrimination set supplemented with the amelogenin gender marker. These SNPs are evenly distributed across all 22 autosomes, exhibit balanced polymorphisms in three major population groups and have been previously shown to be effective markers for forensic analysis. We tested the accuracy and reproducibility of the Genplex system in three SNPforID laboratories, each using a different Applied Biosystems Genetic Analyzer. Genotyping concordance was measured using replicates of 44 standardized DNA controls and by comparing genotypes for the same samples generated by the TaqMan^®, SNaPshot^® and Sequenom iPLEX^® SNP typing systems. The degree of informativeness of the 48 SNPs for forensic analysis was measured using previously estimated allele frequencies to derive the cumulative match probability and in paternity analysis using 24 trios previously typed with 18 STRs together with three CEPH families with extensive sibships typed with the 15 STRs in the Identifiler^® kit.     

Autosomal SNPs study of a population sample from North of Portugal and a sample of immigrants from the Eastern Europe living in Portugal

The use of autosomal single nucleotide polymorphisms (SNPs) for forensic research has been widely discussed in recent years, mainly because SNPs have important advantages compared to short tandem repeats (STRs).In this study a total of 131 non related individuals from the North of Portugal and 85 immigrant individuals from the Eastern Europe, mainly Ukrainians, equally non related and residing in Portugal, were typed for 52 loci included in the in the SNP for ID 52plex with the SNaPshot™ assay.     

The development and validation of a single SNaPshot multiplex for tiger species and subspecies identification--implications for forensic purposes

The tiger (Panthera tigris) is currently listed on Appendix I of the Convention on the International Trade in Endangered Species of Wild Fauna and Flora; this affords it the highest level of international protection. To aid in the investigation of alleged illegal trade in tiger body parts and derivatives, molecular approaches have been developed to identify biological material as being of tiger in origin. Some countries also require knowledge of the exact tiger subspecies present in order to prosecute anyone alleged to be trading in tiger products. In this study we aimed to develop and validate a reliable single assay to identify tiger species and subspecies simultaneously; this test is based on identification of single nucleotide polymorphisms (SNPs) within the tiger mitochondrial genome. The mitochondrial DNA sequence from four of the five extant putative tiger subspecies that currently exist in the wild were obtained and combined with DNA sequence data from 492 tiger and 349 other mammalian species available on GenBank. From the sequence data a total of 11 SNP loci were identified as suitable for further analyses. Five SNPs were species-specific for tiger and six amplify one of the tiger subspecies-specific SNPs, three of which were specific to P. t. sumatrae and the other three were specific to P. t. tigris. The multiplex assay was able to reliably identify 15 voucher tiger samples. The sensitivity of the test was 15,000 mitochondrial DNA copies (approximately 0.26 pg), indicating that it will work on trace amounts of tissue, bone or hair samples. This simple test will add to the DNA-based methods currently being used to identify the presence of tiger within mixed samples.     

Mini-SNaPshot multiplex assays authenticate elephant ivory and simultaneously identify the species origin

Illegal trading of ivory is mainly responsible for the dramatic decline in elephant populations. Thailand is one of the largest laundering hotspots for African ivory, as the domestic Asian elephant ivory can be legally traded. So, to help combat ivory poaching and smuggling, an efficient method is needed to identify the elephant species from its ivory and ivory products. In this study, a mini-SNaPshot^® multiplex assay was developed and fully validated for the identification of confiscated ivory and low DNA template ivory products. Elephantid- and elephant species-specific mitochondrial single nucleotide polymorphisms (SNPs) were identified from 207 mammalian and 1705 elephant/mammoth cytochrome b sequence alignments. Seven informative SNPs were used for assay development. The assay unambiguously and accurately identified authentic elephant ivory and its species of origin on the basis of peak size and color observed in the haplotype profile. The assay was highly efficient for analysis of confiscated ivory and low-template ivory products with a 99.29% success rate (N = 140). It was highly reproducible, exhibited no cross-reaction with eight other mammalian DNA; and had 100% identification accuracy. In addition, nested and direct PCR amplification were also compatible with the developed assay. This efficient assay should benefit wildlife forensic laboratories and aid in the prosecution of elephant-related crimes.     

Quantification of mtDNA mixtures in forensic evidence material using pyrosequencing

Analysis of mtDNA variation using Sanger sequencing does not allow accurate quantification of the components of mtDNA mixtures. An alternative method to determine the specific mixture ratios in samples displaying heteroplasmy, consisting of DNA contributions from several individuals, or containing contamination would therefore be valuable. A novel quantification system for mtDNA mixture analysis has been developed based on pyrosequencing technology, in which the linear relationship between incorporated nucleotides and released light allows quantification of the components of a sample. Within five polymerase chain reaction fragments, seven variable positions in the mtDNA control and coding region were evaluated using this quantification analysis. For all single nucleotide polymorphisms quantified in this study, a linear relationship was observed between the measured and expected mixture ratios. This mtDNA quantification assay is an easy to use, fast and accurate quantification system, with the ability to resolve and interpret major and minor mtDNA components in forensic mixture samples.H. Andréasson and M. Nilsson have contributed equally to the work.     

Analysis of nondegraded and degraded DNA mixtures of close relatives using massively parallel sequencing

Identification of the minor contributor in DNA mixture of close relatives remains a dilemma in forensic genetics. Massively parallel sequencing (MPS) can analyze multiple short tandem repeats (STRs) and single nucleotide polymorphism (SNPs) concurrently and detect non-overlapping alleles of the minor contributors in DNA mixtures. A commercial kit for MPS of 59 identity informative STRs (iiSTRs) and 94 autosomal identity-informative SNPs (iiSNPs) was used to analyzed 34 nondegraded and 33 highly degraded two-person artificial DNA mixtures of close relatives with various minor to major ratios (1:9, 1:19, 1:29, 1:39, 1:79, 1:99). EuroForMix software was used to determine the minor contributors in the mixtures based on the likelihood ratios calculated from the MPS data, and relMix software was used to perform kinship analysis of the contributors. The STRs and SNPs of the 34 nondegraded and 33 degraded DNA mixtures were genotyped using MPS. Using EuroForMix based on the genotypes of autosomal iiSTRs and autosomal iiSNPs, 82.4% (28/34) and 54.5% (18/33) of minor donors could be accurately assigned for the nondegraded and degraded DNA mixtures, respectively. The relMix software correctly inferred the relationship between contributors in 97.1% (33/34) of nondegraded mixtures and in 97.0% (32/33) of degraded mixtures. In conclusion, combined EuroForMix and MPS data of STRs and SNPs can assist in the assignment of minor donors in nondegraded DNA mixtures of close relatives, and relMix can be used to infer relationship among contributors.