Real-time forensic DNA analysis at a crime scene using a portable microchip analyzer

An integrated lab-on-a-chip system has been developed and successfully utilized for real-time forensic short tandem repeat (STR) analysis. The microdevice comprises a 160-nL polymerase chain reaction reactor with an on-chip heater and a temperature sensor for thermal cycling, microvalves for fluidic manipulation, a co-injector for sizing standard injection, and a 7-cm-long separation channel for capillary electrophoretic analysis. A 9-plex autosomal STR typing system consisting of amelogenin and eight combined DNA index system (CODIS) core STR loci has been constructed and optimized for this real-time human identification study. Reproducible STR profiles of control DNA samples are obtained in 2 h and 30 min with ≤0.8 bp allele typing accuracy. The minimal amount of DNA required for a complete DNA profile is 100 copies. To critically evaluate the capabilities of our portable microsystem as well as its compatibility with crime scene investigation processes, real-time STR analyses were carried out at a mock crime scene prepared by the Palm Beach County Sheriff's Office (PBSO). Blood stain sample collection, DNA extraction, and STR analyses on the portable microsystem were conducted in the field, and a successful “mock” CODIS hit was generated on the suspect's sample within 6 h. This demonstration of on-site STR analysis establishes the feasibility of real-time DNA typing to identify the contributor of probative biological evidence at a crime scene and for real-time human identification.     

Direct comparison of post-28-cycle PCR purification and modified capillary electrophoresis methods with the 34-cycle “low copy number” (LCN) method for analysis of trace forensic DNA samples

The investigation of samples with low amounts of template DNA remains at the forefront of forensic DNA research and technology as it becomes increasingly important to gain DNA profile information from exceedingly trace levels of DNA. Previous studies have demonstrated that it is possible to obtain short tandem repeat (STR) profiles from <100 pg of template DNA by increasing the number of amplification cycles from 28 to 34, a modification often referred to as “low copy number” or LCN analysis. In this study, we have optimised post-PCR purification techniques applied after only 28 cycles of PCR, as well as using modified capillary electrophoresis injection conditions and have investigated the progressive application of these enhanced approaches. This paper reviews the characteristics of the profiles obtained by these methods compared with those obtained on the same samples after 34-cycle PCR. We observed comparable sensitivity to 34-cycle PCR in terms of the number of profiles with evidence of DNA and the number of allelic peaks per profile and we noted improved peak height and area magnitude with some sample types. Certain parameters reported to be adversely affected in 34-cycle LCN investigations, such as non-donor allele peaks and increased stutter peak ratio, were reduced by this approach. There are a number of advantages for trace samples in progressing from the standard 28-cycle process to the post-PCR processing method as compared to 34-cycle PCR method, including reduced sample consumption, reduced number of PCR amplifications required, and a staged approach to sample processing and profile interpretation.     

Investigations into improving the standard DNA testing of trace samples at ESR

ABSTRACT

Since 2007, the Institute of Environmental and Science Research (ESR) has been using the AmpF/STR Identifiler profiling kit as the standard DNA test. Whilst this approach works well for most samples with a DNA input range of 400 pg to 2 ng, samples containing less DNA often have limited to no profiling success. If required, such samples can undergo testing using a more sensitive technique, such as mini-STR analysis or Low Copy Number (LCN) DNA analysis. The introduction of a more sensitive standard DNA test into the laboratory would likely prove to be greatly beneficial. Profiling success should increase, particularly for samples containing trace DNA concentrations, and the number of samples requiring rework and further analysis using an ultra-sensitive technique would potentially reduce. A number of new generation multiplex kits with increased sensitivity are now commercially available. One such kit is the AmpF/STR Identifiler Plus profiling kit, which has enhanced buffer formulation and an optimized PCR cycling protocol. This study investigates the profiling results from trace DNA samples using Identifiler at 28 cycles and Identifiler Plus, at 28 and 29 cycles, analysed using the 3500xL Applied BioSystems Genetic Analyzer. Any further benefits from including a post-PCR clean-up step and enhanced capillary electrophoresis conditions are investigated and discussed.     

Developmental validation of a fully integrated sample-to-profile rapid human identification system for processing single-source reference buccal samples

Short tandem repeat (STR) DNA typing is a global standard for human identification. Current practice involves highly trained forensic analysts, operating in a laboratory setting, using multiple instruments to process samples and analyze the data. Here, we report the developmental validation of a fully integrated and automated DNA profiling system, the RapidHIT^® System, capable of producing up to five high quality STR profiles with full controls in approximately 90 min using PowerPlex^®16 HS RapidHIT chemistry. The system integrates all sample handling steps: starting from lysis of cells on buccal swabs or other buccal sample types through DNA extraction, normalization, amplification,capillary array electrophoresis, detection, and integrated software analysis.The results describe the developmental validation of the RapidHIT™ System for buccal samples processed with the DNA IQ™ extraction chemistry using a guandinium chaotropic agent and paramagnetic beads followed by amplification using a modified version of PowerPlex 16 HS chemistry (PowerPlex 16 HS RapidHIT chemistry), and capillary electrophoresis with manual review of genotyping data following interpretation guidelines. All processing from the buccal swab to generation and processing of the profile occurs on the RapidHIT platform.Resultare concordant with traditional methods, with 88% first pass success rates for both the CODIS and PowerPlex 16 loci. Average peak height ratios were 0.89 for buccal swabs. The system produces full profiles from swabs with at least 176 ng of saliva DNA. Rapid DNA identification systems will significantly enhance capabilities for forensic labs, intelligence, defense, law enforcement, refugee and immigration applications, and kinship analysis.     

Improved analysis of long STR amplicons from degraded single source and mixed DNA

DNA profiles from degraded samples often suffer from information loss at the longer short tandem repeat (STR) loci. Sensitising the reactions, either by performing additional PCR cycles or increasing the capillary electrophoresis injection settings, carries the risk of over-amplifying or overloading the shorter fragments. We explored whether profiling of degraded DNA can be improved by preferential capturing of the longer amplified fragments. To this aim, a post-PCR purification protocol was developed that is based on AMPure XP beads that have size-selective properties. A comparison was made with an unselective post-PCR purification system (DTR gel filtration) and no purification of the PCR products. Besides a set of differently and serially degraded single source samples, unequal mixtures of degraded DNAs were analysed, in order to extract more genotyping information for the minor contributor without overloading the major component at the shorter amplicons. Purification by the AMPure protocol resulted in higher peak heights especially for the longer amplicons, while DTR gel filtration gave higher peaks for all amplicon sizes. Both purification methods presented more detected alleles, with the AMPure protocol performing slightly better, on average. In conclusion, the in-house developed AMPure protocol can be employed to improve STR profile analysis of degraded single source and (unequally) mixed DNA samples.     

Characterizing the amplification of STR markers in multiplex polymerase chain displacement reaction using massively parallel sequencing

Polymerase chain displacement reaction (PCDR) showed advantages in forensic low-template DNA analysis with improved amplification efficiency, higher allele detection capacity, and lower stutter artifact than PCR. However, characteristics of STR markers after PCDR amplification remain unclarified for the limited resolving power of capillary electrophoresis (CE). This issue can be addressed by massively parallel sequencing (MPS) technology with higher throughput and discriminability. Here, we developed a multiplex PCDR system including 24 STRs and amelogenin. In addition, a PCR reference was established for comparison. After amplification, products were subjected to PCR-free library construction and sequenced on the Illumina NovaSeq system. We implemented a sequence-matching pipeline to separate different amplicon types of PCDR products from the combination of primers. In the sensitivity test, the PCDR multiplex obtained full STR profiles with as low as 125 pg 2800M control DNA. Based on that, single-source DNA samples were tested. First, highly concordant genotypes were observed among the PCDR multiplex, the PCR reference, and CE-based STR kits. Next, read counts of different PCDR amplicon types were investigated, showing a relative abundance of 78:12:12:1 for the shortest amplicon S, the two medium amplicons M1 and M2, and the longest amplicon L. We also analyzed the stutter artifacts for distinct amplicon types, and the results revealed the reduction of N − 1 and N − 2 contraction stutters, and the increase of N + 1 and N + 2 elongation stutters in PCDR samples. Moreover, we confirmed the feasibility of PCDR for amplifying degraded DNA samples and unbalanced DNA mixtures. Compared to the previous proof of principle study, our work took a further step to characterize the complete profile of STR markers in the PCDR context. Our results suggested that the PCDR-MPS workflow is an effective approach for forensic STR analysis. Corresponding findings in this study may help the development of PCDR-based assays and probabilistic methods in future studies.     

Performance of a next generation sequencing SNP assay on degraded DNA

Forensic DNA casework samples are often of insufficient quantity or quality to generate full profiles by conventional DNA typing methods. Polymerase chain reaction (PCR) amplification of short tandem repeat (STR) loci is inherently limited in samples containing degraded DNA, as the cumulative size of repeat regions, primer binding regions, and flanking sequence is necessarily larger than the PCR template. Additionally, traditional capillary electrophoresis (CE) assay design further inherently limits shortening amplicons because the markers must be separated by size. Non-traditional markers, such as single nucleotide polymorphisms (SNPs) and insertion deletion polymorphisms (InDels), may yield more information from challenging samples due to their smaller amplicon size. In this study, the performance of a next generation sequencing (NGS) SNP assay and CE-based STR, mini-STR, and InDel assays was evaluated with a series of fragmented, size-selected samples. Information obtained from the NGS SNP assay exhibited higher overall inverse random match probability (1/RMP) values compared to the CE-based typing assays, with particular benefit for fragment sizes ≤150 base pairs (bp). The InDel, mini-STR, and NGS SNP assays all had similar percentages of loci with reportable alleles at this level of degradation; however, the relatively fewer number of loci in the InDel and mini-STR assays results in the NGS SNP assay having at least nine orders of magnitude higher 1/RMP values. In addition, the NGS SNP assay and three CE-based assays (two STR and one InDel assay) were tested using a dilution series consisting of 0.5 ng, 0.1 ng, and 0.05 ng non-degraded DNA. All tested assays showed similar percentages of loci with reportable alleles at these levels of input DNA; however, due to the larger number of loci, the NGS SNP assay and the larger of the two tested CE-based STR assays both resulted in considerably higher 1/RMP values than the other assays. These results indicate the potential advantage of NGS SNP assays for forensic analysis of degraded DNA samples.     

Probabilistic genotyping software: An overview

The interpretation of mixed profiles from DNA evidentiary material is one of the more challenging duties of the forensic scientist. Traditionally, analysts have used a “binary” approach to interpretation where inferred genotypes are either included or excluded from the mixture using a stochastic threshold and other biological parameters such as heterozygote balance, mixture ratio, and stutter ratios. As the sensitivity of STR multiplexes and capillary electrophoresis instrumentation improved over the past 25 years, coupled with the change in the type of evidence being submitted for analysis (from high quality and quantity (often single-source) stains to low quality and quantity (often mixed) “touch” samples), the complexity of DNA profile interpretation has equally increased. This review provides a historical perspective on the movement from binary methods of interpretation to probabilistic methods of interpretation. We describe the two approaches to probabilistic genotyping (semi-continuous and fully continuous) and address issues such as validation and court acceptance. Areas of future needs for probabilistic software are discussed.     

Development of a multiplex assay for detection of autosomal and Y-chromosomal STRs,assessment of the degradation state of mitochondrial DNA and presence of mitochondrial length heteroplasmies

The current focus in most routine forensic casework is detection of autosomal or gonosomal Short Tandem Repeats (STRs). With increasing degradation, STR analysis tends to be less successful up to complete failure. For challenging samples such as telogen hair roots and shafts, touch DNA samples or skeletal remains, mitochondrial DNA (mtDNA) analysis provides a powerful tool. Determination of DNA quantity is an important part in the casework workflow. Several ready-to-use kits are commercially available for nuclear DNA targets. However, quantification of mtDNA targets requires the establishment of an in-house method. Some assays even contain assessment of degradation, which alleviates the choice of target enrichment for sequencing through medium or small amplicons. As Sanger-type Sequencing (STS) still remains the golden standard in many laboratories, identification of heteroplasmies in C-tract regions prior to the sequencing reaction is advantageous. Firstly, primer selection can be expanded with primers binding near the C-tract and secondly, determination of the dominant variant is straightforward. All those quantity (nuclear and mtDNA) and quality (degradation and length heteroplasmies) evaluations usually require at least two separate reactions. Therefore, the aim of this project was the combination of all these targets in one multiplex assay using capillary electrophoresis to spare valuable sample extract. Amplification of representative autosomal and Y-chromosomal STRs allows estimate of success of (Y-)STR analysis. Simultaneously, five length heteroplasmies in the mitochondrial control region are targeted as well as three conservative regions of differing fragment lengths for assessment of the mitochondrial degradation state. Based on the outcome of this assay, forensic examiners can decide if STR analysis may be suitable. In case of absent STR peaks, appropriate proceeding of mtDNA sequencing can be determined.     

High sensitivity multiplex short tandem repeat loci analyses with massively parallel sequencing

STR typing in forensic genetics has been performed traditionally using capillary electrophoresis (CE). However, CE-based method has some limitations: a small number of STR loci can be used; stutter products, dye artifacts and low level alleles. Massively parallel sequencing (MPS) has been considered a viable technology in recent years allowing high-throughput coverage at a relatively affordable price. Some of the CE-based limitations may be overcome with the application of MPS. In this study, a prototype multiplex STR System (Promega) was amplified and prepared using the TruSeq DNA LT Sample Preparation Kit (Illumina) in 24 samples. Results showed that the MinElute PCR Purification Kit (Qiagen) was a better size selection method compared with recommended diluted bead mixtures. The library input sensitivity study showed that a wide range of amplicon product (6–200 ng) could be used for library preparation without apparent differences in the STR profile. PCR sensitivity study indicated that 62 pg may be minimum input amount for generating complete profiles. Reliability study results on 24 different individuals showed that high depth of coverage (DoC) and balanced heterozygote allele coverage ratios (ACRs) could be obtained with 250 pg of input DNA, and 62 pg could generate complete or nearly complete profiles. These studies indicate that this STR multiplex system and the Illumina MiSeq can generate reliable STR profiles at a sensitivity level that competes with current widely used CE-based method.     

Evaluation of the RapidHIT™ 200, an automated human identification system for STR analysis of single source samples

The RapidHIT™ 200 Human Identification System was evaluated to determine its suitability for STR analysis of single source buccal swabs. Overall, the RapidHIT™ 200 performed as well as our traditional capillary electrophoresis based method in producing useable profile information on a first-pass basis. General observations included 100% concordance with known profile information, consistent instrument performance after two weeks of buccal swab storage, and an absence of contamination in negative controls. When data analysis was performed by the instrument software, 95.3% of the 85 samples in the reproducibility study gave full profiles. Including the 81 full profiles, a total of 2682 alleles were correctly called by the instrument software, or 98.6% of 2720 possible alleles tested. Profile information was generated from as little as 10,000 nucleated cells, with swab collection technique being a major contributing factor to profile quality. The average peak-height-ratio for heterozygote profiles (81%) was comparable to conventional STR analysis, and while a high analytical threshold was required when offline profile analysis was performed (800 RFU), it was proportionally consistent with traditional methods. Stochastic sampling effects were evaluated, and a manageable approach to address limits of detection for homozygote profiles is provided. These results support consideration of the RapidHIT™ 200 as an acceptable alternative to conventional, laboratory based STR analysis for the testing of single source buccal samples, with review of profile information as a requirement until an expert software system is incorporated, and when proper developmental and internal validation studies have been completed.     

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.     

Evaluation of three DNA extraction protocols for forensic STR typing after laser capture microdissection

In forensic sciences, short tandem repeat (STR) analysis is a valuable tool in identifying the donor(s) of biological stains. Laser capture microdissection (LCM) can be used as a cell separating technique to isolate specific cell types in mixed samples. An important challenge lies in the development of a DNA isolation method appropriate for laser microdissected cells, as these samples usually contain minute amounts of cells. In this study three different DNA isolation methods for LCM collected cells were compared. The PicoPure DNA extraction method outperformed both other methods (IQ? system and short alkaline method). Consequently, the minimal number of LCM collected cells necessary for STR typing was determined. Using the PicoPure DNA extraction method, full DNA profiles could be obtained from as little as 10 cells. Nevertheless, despite the occurrence of allelic drop out in some of the samples, lower amounts of cells gave rise to useful DNA profiles.     

Low copy number DNA profiling from isolated sperm using the aureka®-micromanipulation system

A new cell isolation technique linked to the aureka? micromanipulation system (aureka?) was used to pick sperm from mixed samples containing sperm and epithelial cells. Both cell types were stained using the HY-LITER? high-resolution, fluorescent staining kit. To isolate a single sperm of interest under a fluorescent microscope, a specific microsphere picking technique was used. This sensitive and reliable cell identification and isolation technique enables low-copy-number (LCN) DNA profiling, as few as 20 sperm are sufficient for obtaining a full short tandem repeat (STR) profile without any allelic drop out. The presented protocol covers the whole workflow, from sample staining and cell pick up to STR analysis.     

Massively parallel sequencing of 17 commonly used forensic autosomal STRs and amelogenin with small amplicons

The next-generation sequencing (NGS) method has been utilized to analyze short tandem repeat (STR) markers, which are routinely used for human identification purposes in the forensic field. Some researchers have demonstrated the successful application of the NGS system to STR typing, suggesting that NGS technology may be an alternative or additional method to overcome limitations of capillary electrophoresis (CE)-based STR profiling. However, there has been no available multiplex PCR system that is optimized for NGS analysis of forensic STR markers. Thus, we constructed a multiplex PCR system for the NGS analysis of 18 markers (13CODIS STRs, D2S1338, D19S433, Penta D, Penta E and amelogenin) by designing amplicons in the size range of 77–210 base pairs. Then, PCR products were generated from two single-sources, mixed samples and artificially degraded DNA samples using a multiplex PCR system, and were prepared for sequencing on the MiSeq system through construction of a subsequent barcoded library. By performing NGS and analyzing the data, we confirmed that the resultant STR genotypes were consistent with those of CE-based typing. Moreover, sequence variations were detected in targeted STR regions. Through the use of small-sized amplicons, the developed multiplex PCR system enables researchers to obtain successful STR profiles even from artificially degraded DNA as well as STR loci which are analyzed with large-sized amplicons in the CE-based commercial kits. In addition, successful profiles can be obtained from mixtures up to a 1:19 ratio. Consequently, the developed multiplex PCR system, which produces small size amplicons, can be successfully applied to STR NGS analysis of forensic casework samples such as mixtures and degraded DNA samples.     

Assessment of application value of 19 autosomal short tandem repeat loci of GoldenEyeTM 20A kit in forensic paternity testing

This study was carried out to assess the application value of 19 autosomal short tandem repeat (STR) loci of GoldenEye^TM 20A kit, in which 13 combined DNA index system core STR loci and PentaE, PentaD, D2S1338, D19S433, D12S391, and D6S1043 of six STR loci could be used in forensic paternity testing in Chinese population. We amplified the genomic DNA from blood samples on FTA paper of 289 paternity testing cases by using the GoldenEye^TM 20A kit. The amplified products were detected by capillary electrophoresis, and then the genotypes of 20 genetic markers including 19 STR loci as well as Amelogenin for sex determination were analyzed by GeneMapper v3.2 and GeneMarker HID Software. The results of genotypes were compared to the three commonly used commercial kits including AmpF?STR Identifiler^TM, PowerPlex^TM16, and AmpF?STR Sinofiler^TM kits. Compared to the three other common commercial kits, the GoldenEye^TM 20A kit had higher value of combined paternity index in certainty of paternity or non-exclusion paternity cases, and more numbers of STR loci were excluded in exclusionary paternity cases. Our data in this study showed that the GoldenEye^TM 20A kit has a higher application value in forensic paternity testing and will be of help for kinship analysis.     

SEQ Mapper: A DNA sequence searching tool for massively parallel sequencing data

The development of massively parallel sequencing (MPS) has increased greatly the scale of DNA sequencing. The analysis of massive data-files from single MPS analysis can be a major challenge if examining the data for potential polymorphic loci. To aid in the analysis of both short tandem repeat (STR) and single nucleotide polymorphisms (SNP), we have designed a new program called SEQ Mapper to search for genetic polymorphisms within a large number of reads generated by MPS. This new program has been designed to perform sequence mapping between reference data and generated reads. As a proof-of-concept, sequences derived from the allelic ladders of five STR loci and data from the amelogenin locus were used as reference data sets. Detecting and recording the polymorphic nature of each STR loci was performed using four levels of search criteria: the entire STR locus spanning the two primers; the STR region plus the two primer sequences; the STR region only; and the two primers only. All the genotypes of 5 STR loci and the amelogenin gene were identified correctly using SEQ Mapper when compared to results obtained from capillary electrophoresis based on 10 test samples in this study. SEQ Mapper is a useful tool to detect STR or SNP alleles generated by MPS in both clinical medicine and forensic genetics.     

Reliable genotyping of short tandem repeat loci without an allelic ladder using time-of-flight mass spectrometry

DNA separations which traditionally have been performed by slab gel or capillary electrophoresis, may now be conducted via time-of-flight mass spectrometry (TOF-MS). The advantages of using a mass spectrometry approach for short tandem repeat (STR) characterization include a dramatic increase in both the speed of analysis and the accuracy of mass measurements. We report here typing of the STR loci TH01, TPOX, and CSF1PO as well as the sex-typing marker amelogenin using TOF-MS. Allelic ladders, which are typically used with electrophoretic separation systems to correct for mobility differences of DNA fragments under various conditions, are not needed for accurate genotyping with TOF-MS. A mass precision of 0.1% RSD, which corresponds to approximately 0.1 nucleotide, was routinely observed. Mass accuracies were better than a fraction of a single nucleotide when a daily mass calibration was used. STR microvariants, such as the TH01 allele 9.3, could be detected and resolved from alleles which differ by as little as a single base. In addition, the smaller PCR product sizes (55– 125 bp) examined in this study have the potential advantage of being more successful when amplifying forensic samples with degraded DNA. Received: 16 January 1998 / Received in revised form: 17 March 1998     

Improvement of short tandem repeat analysis of samples highly contaminated by humic acid

We investigated several methods for obtaining successful short tandem repeat (STR) results from high-humic acid (HA)-content samples. DNA purification efficiency was tested for QIAquick^® PCR Purification, QIAamp^® DNA Investigator and Prepfiler? Forensic DNA Extraction kits. HA-removal capacity of Inhibitor Remover and InhibitEX^® Tablet was tested. Experiments on overcoming HA effects on STR amplification were conducted using an AmpliTaq Gold^® DNA Polymerase and a TaKaRa Ex Taq? Hot Start Version (Ex Taq HS) with BSA addition. QIAquick kit was most efficient in HA removal and Ex Taq HS showed high resistance to HA. Increasing the amounts of Taq polymerases and BSA addition were shown to be efficient in overcoming PCR inhibition, but BSA addition was superior to the former method. Inhibitor Remover and InhibitEX^® Tablet did not positively affect the STR results. This study will help achieve better STR results with high-HA-content samples.