Simultaneous Identification of Four “Legal High” Plant Species in a Multiplex PCR High‐Resolution Melt Assay,

The international prevalence of “legal high” drugs necessitates the development of a method for their detection and identification. Herein, we describe the development and validation of a tetraplex multiplex real‐time polymerase chain reaction (PCR) assay used to simultaneously identify morning glory, jimson weed, Hawaiian woodrose, and marijuana detected by high‐resolution melt using LCGreen Plus^®. The PCR assay was evaluated based on the following: (i) specificity and selectivity—primers were tested on DNA extracted from 30 species and simulated forensic samples, (ii) sensitivity—serial dilutions of the target DNA were prepared, and (iii) reproducibility and reliability—sample replicates were tested and remelted on different days. The assay is ideal for cases in which inexpensive assays are needed to quickly detect and identify trace biological material present on drug paraphernalia that is too compromised for botanical microscopic identification and for which analysts are unfamiliar with the morphology of the emerging “legal high” species.     

SNP Miniplexes for Individual Identification of Random‐Bred Domestic Cats

Phenotypic and genotypic characteristics of the cat can be obtained from single nucleotide polymorphisms (SNPs) analyses of fur. This study developed miniplexes using SNPs with high discriminating power for random‐bred domestic cats, focusing on individual and phenotypic identification. Seventy‐eight SNPs were investigated using a multiplex PCR followed by a fluorescently labeled single base extension (SBE) technique (SNaPshot^®). The SNP miniplexes were evaluated for reliability, reproducibility, sensitivity, species specificity, detection limitations, and assignment accuracy. Six SNPplexes were developed containing 39 intergenic SNPs and 26 phenotypic SNPs, including a sex identification marker, ZFXY. The combined random match probability (cRMP) was 6.58 × 10^?19 across all Western cat populations and the likelihood ratio was 1.52 × 10¹⁸. These SNPplexes can distinguish individual cats and their phenotypic traits, which could provide insight into crime reconstructions. A SNP database of 237 cats from 13 worldwide populations is now available for forensic applications.     

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.     

High‐Resolution Melting (HRM) of Hypervariable Mitochondrial DNA Regions for Forensic Science

Forensic strategies commonly are proceeding by analysis of short tandem repeats (STRs); however, new additional strategies have been proposed for forensic science. Thus, this article standardized the high‐resolution melting (HRM) of DNA for forensic analyzes. For HRM, mitochondrial DNA (mtDNA) from eight individuals were extracted from mucosa swabs by DNAzol reagent, samples were amplified by PCR and submitted to HRM analysis to identify differences in hypervariable (HV) regions I and II. To confirm HRM, all PCR products were DNA sequencing. The data suggest that is possible discriminate DNA from different samples by HRM curves. Also, uncommon dual‐dissociation was identified in a single PCR product, increasing HRM analyzes by evaluation of melting peaks. Thus, HRM is accurate and useful to screening small differences in HVI and HVII regions from mtDNA and increase the efficiency of laboratory routines based on forensic genetics.     

Effectiveness of Single‐Nucleotide Polymorphisms to Investigate Cattle Rustling

Short tandem repeats (STR)s have been the eligible markers for forensic animal genetics, despite single‐nucleotide polymorphisms (SNP)s became acceptable. The technology, the type, and amount of markers could limit the investigation in degraded forensic samples. The performance of a 32‐SNP panel genotyped through OpenArrays^TM (real‐time PCR based) was evaluated to resolve cattle‐specific forensic cases. DNA from different biological sources was used, including samples from an alleged instance of cattle rustling. SNPs and STRs performance and repeatability were compared. SNP call rate was variable among sample type (average = 80.18%), while forensic samples showed the lowest value (70.94%). The repeatability obtained (98.7%) supports the used technology. SNPs had better call rates than STRs in 12 of 20 casework samples, while forensic index values were similar for both panels. In conclusion, the 32‐SNPs used are as informative as the standard bovine STR battery and hence are suitable to resolve cattle rustling investigations.     

A molecular identification system for grasses: a novel technology for forensic botany

Our present inability to rapidly, accurately and cost-effectively identify trace botanical evidence remains the major impediment to the routine application of forensic botany. Grasses are amongst the most likely plant species encountered as forensic trace evidence and have the potential to provide links between crime scenes and individuals or other vital crime scene information. We are designing a molecular DNA-based identification system for grasses consisting of several PCR assays that, like a traditional morphological taxonomic key, provide criteria that progressively identify an unknown grass sample to a given taxonomic rank. In a prior study of DNA sequences across 20 phylogenetically representative grass species, we identified a series of potentially informative indels in the grass mitochondrial genome. In this study we designed and tested five PCR assays spanning these indels and assessed the feasibility of these assays to aid identification of unknown grass samples. We confirmed that for our control set of 20 samples, on which the design of the PCR assays was based, the five primer combinations produced the expected results. Using these PCR assays in a 'blind test', we were able to identify 25 unknown grass samples with some restrictions. Species belonging to genera represented in our control set were all correctly identified to genus with one exception. Similarly, genera belonging to tribes in the control set were correctly identified to the tribal level. Finally, for those samples for which neither the tribal or genus specific PCR assays were designed, we could confidently exclude these samples from belonging to certain tribes and genera. The results confirmed the utility of the PCR assays and the feasibility of developing a robust full-scale usable grass identification system for forensic purposes.     

Genome‐wide Screen for Individual Identification SNPs (IISNPs) and the Confirmation of Six of Them in Han Chinese with Pyrosequencing Technology*

Abstract: Single nucleotide polymorphisms (SNPs) offer promise to forensic DNA analysts, but it remains uncertain whether a panel of individual identification SNPs can be as informative as the Combined DNA Index System short tandem repeats. Based on the highly accurate and publicly available HapMap SNP database (r21a) and a minor allele frequency cutoff of ≥0.45, we completed a genome‐wide screen through 3,905,819 SNPs with internally modified computer programs and identified 1439 SNPs with high heterozygosity and low F_st values among four populations (Utah Caucasian, Han Chinese, Tokyo Japanese, and Nigerian Yoruba). Using pyrosequencing technology, we studied six loci in a relatively large group of samples to determine whether these loci were as informative as the HapMap data suggest. These SNPs performed as expected in the Han Chinese in terms of heterozygosity and F_st. The 1439 identified SNPs should provide a comprehensive and reliable set of loci for identity and relationship testing.     

A Novel Application of a Cryosectioning Technique to Aid Scat Hair Microanalysis

Scat hair presents a diverse profile of hairs for morphological assessment that may find versatile applications in wildlife forensic investigations. Successful morphological assessment of scat hair microstructure, however, depends on a robust sectioning methodology. We assessed the feasibility and efficacy of a cryosectioning technique compared to that of a gold standard hand‐sectioning technique. Scat hairs were embedded in paraffin wax and hand‐sectioned, while cryopreserved scat hairs were sectioned with a cryostat. The results showed that cryosectioning preserved the pristine morphology of the scat hair and provided cross sections more amenable to high‐resolution imaging of hair internal microstructure than hand‐sectioning. The cryosectioning technique may find novel applications as a more reliable and robust technique to aid (i) scat hair internal microstructure analysis for cross‐referencing with species identification keys in wildlife forensic studies and (ii) downstream toxicological analysis in wildlife forensic studies as hair biochemistry is not altered during cryopreservation.     

个体识别SNPs位点组合筛选与法医学应用价值初探

目的筛选用于包括中国主要民族在内的多个群体个体识别的SNPs位点组合体系。方法以Kidd实验室筛选的86个SNPs位点、欧洲SNPforID组织构建的52-plex SNPs复合检测体系为基础,收集和整理这些位点在HapMap数据库中11个人群的分型数据,计算各位点杂合度和Fst值,筛选杂合度〉0.4,Fst值〈0.06,并在研究人群中处于Hardy-Weinberg和连锁平衡的位点组合。针对这些位点,采用MassARRAY分子阵列技术对自行收集的8个人群（尼日利亚人、坦桑尼亚查加人、印度人、丹麦人、俄罗斯汉特人、中国汉族、藏族、维吾尔族）308份样本进行分型,统计群体遗传学参数。结果按本文标准共筛选出66个SNPs位点,均符合Hardy-Weinberg平衡,之间互不连锁,平均杂合度和Fst值分别为0.475、0.014。在本文收集的8个人群中的随机匹配概率在1.45E-24~4.72E-27之间,累积非父排除率为0.999 995 608~0.999 997 876之间。结论本文筛选的SNPs组合系统具有较强的个体识别能力,可用于本文调查的HapMap数据库中11个人群和本文收集的8个人群的个体识别鉴定。     

Inferring recent human phylogenies using forensic STR technology

STR loci are characterized by extremely high mutation rates and thus, high levels of length polymorphism both within and among populations. In addition, much of the observed variation is believed to be nearly selectively neutral. Because of these features, STRs are ideal markers for genetic mapping, intra-species phylogenetic reconstructions and forensic analysis. In the present study, we investigate the application of five STR loci (CS1PO, TH01, TPOX, FGA and vWA) routinely used in forensic analysis for delineating the phylogenetic relationships of 10 human populations representing the three major racial groups (African-Caribbean, Croatian from the island of Hvar, East Asian, Han Chinese, Italian, Japanese, Portuguese, UK Caucasian, US Caucasian and Zimbabwe). The resulting tree topology exhibited strong geographic and racial partitioning consistent with that obtained with mtDNA haplotypes, Y-chromosome markers, SNPs, PAIs (polymorphic Alu insertions) as well as classic genetic polymorphisms. These findings suggest that forensic STR loci may be particularly powerful tools and provide the necessary fine resolution for the reconstruction of recent human evolutionary history.     

Estimating Individual Contributions to Complex DNA SNP Mixtures.,

High‐throughput sequencing (HTS) of large panels of single nucleotide polymorphisms (SNPs) provides an alternative or complimentary approach to short tandem repeats (STRs) panels for the analysis of complex DNA mixture forensic samples. For STRs, methods to estimate individual contribution concentrations compare capillary electrophoresis peak heights, peak areas, or HTS allele read counts within a mixture. This article introduces three approaches (mean, median, and slope methods) for estimating individual DNA contributions to forensic mixtures for HTS/massively parallel sequencing (MPS) SNP panels. For SNPs, the major:minor allele ratios or counts, unique to each contributor, were compared to estimate contributor proportion within the mixture using the mean, median, and slope intercept for these alleles. The estimates for these three methods were typically within 5% of planned experimental contributions for defined mixtures.     

Testing the performance of mtSNP minisequencing in forensic samples

There is a growing interest among forensic geneticists in developing efficient protocols for genotyping coding region mitochondrial DNA (mtDNA) SNPs (mtSNPs). Minisequencing is becoming a popular method for SNP genotyping, but it is still used by few forensic laboratories. In part, this is due to the lack of studies testing its efficiency and reproducibility when applied to real and complex forensic samples. Here we tested a minisequencing design that consists of 71 mtSNPs (in three multiplexes) that are diagnostic of known branches of the R0 phylogeny, in real forensic samples, including degraded bones and teeth, hair shafts, and serial dilutions. The fact that amplicons are short coupled with the natural efficiency of the minisequencing technique allow these assays to perform well with all the samples tested either degraded and/or those containing low DNA amount. We did not observe phylogenetic inconsistencies in the 71 mtSNP haplotypes generated, indicating that the technique is robust against potential artefacts that could arise from unintended contamination and/or spurious amplification of nuclear mtDNA pseudogenes (NUMTs).     

Detection of microRNAs in DNA Extractions for Forensic Biological Source Identification

Molecular‐based approaches for biological source identification are of great interest in the forensic community because of a lack of sensitivity and specificity in current methods. MicroRNAs (miRNAs) have been considered due to their robust nature and tissue specificity; however, analysis requires a separate RNA extraction, requiring an additional step in the forensic analysis workflow. The purpose of this study was to evaluate miRNA detection in blood, semen, and saliva using DNA extraction methods commonly utilized for forensic casework. RT‐qPCR analysis revealed that the tested miRNAs were consistently detectable across most tested DNA extraction methods, but detection was significantly reduced compared to RNA extracts in some biological fluids. DNase treatment was not necessary to achieve miRNA‐specific results. A previously developed miRNA panel for forensic body fluid identification was evaluated using DNA extracts, and largely demonstrated concordance with results from samples deriving from RNA extracts of semen, blood, and saliva.     

Case report: Identification of skeletal remains using short-amplicon marker analysis of severely degraded DNA extracted from a decomposed and charred femur

Applying two extraction protocols to isolate DNA from a charred femur recovered after a major forest fire, a range of established and recently developed forensic marker sets that included mini-STRs and SNPs were used to type the sample and confirm identity by comparison to a claimed daughter of the deceased. Identification of the remains suggested that the individual had been dead for 10 years and the DNA was therefore likely to be severely degraded from the combined effects of decomposition and exposure to very high temperatures. We used new marker sets specifically developed to analyze degraded DNA comprising both reduced-length amplicon STR sets and autosomal SNP multiplexes, giving an opportunity to assess the ability of each approach to successfully type highly degraded material from a challenging case. The results also suggest a modified ancient DNA extraction procedure offers improved typing success from degraded skeletal material.     

A Grass Molecular Identification System for Forensic Botany: A Critical Evaluation of the Strengths and Limitations*

Abstract: Plant material is frequently encountered in criminal investigations but often overlooked as potential evidence. We designed a DNA‐based molecular identification system for 100 Australian grasses that consisted of a series of polymerase chain reaction assays that enabled the progressive identification of grasses to different taxonomic levels. The identification system was based on DNA sequence variation at four chloroplast and two mitochondrial loci. Seventeen informative indels and 68 single‐nucleotide polymorphisms were utilized as molecular markers for subfamily to species‐level identification. To identify an unknown sample to subfamily level required a minimum of four markers or nine markers for species identification. The accuracy of the system was confirmed by blind tests. We have demonstrated “proof of concept” of a molecular identification system for trace botanical samples. Our evaluation suggests that the adoption of a system that combines this approach with DNA sequencing could assist the morphological identification of grasses found as forensic evidence.