D5S818 Typing Discrepancy Between PowerPlex® Fusion and Other STR Kits Including GlobalFiler® Caused by a One‐base Deletion in 31 Nucleotides Upstream of the Repeat Region

Short tandem repeat (STR) typing is widely used in forensic investigation. When the same DNA sample is analyzed with different STR typing kits, a typing discrepancy is occasionally observed. In this study, we examined the cause of a typing discrepancy in a sample at D5S818 locus. This sample was designated as 10, 12 using Identifiler^®, Identifiler^® Plus, GlobalFiler^®, PowerPlex^® 16HS, and PowerPlex^® 18D, but as 9.3, 12 using PowerPlex^® Fusion. Sequencing results indicated that the shorter allele in the sample had a deletion (U31Tdel) at 31 nucleotides upstream of the repeat region (AGAT)₁₀. This deletion was located in the binding site of the published D5S818 forward primer in PowerPlex^® 16 and was only 9 and 11 nucleotides downstream of our estimated 5′ end position of D5S818 forward primer in GlobalFiler^® and PowerPlex^® 18D, respectively. We also examined the effect of primer length on the heterozygous peak balance in this sample.     

The Effects of Different Maceration Techniques on Nuclear DNA Amplification Using Human Bone

Abstract: Forensic anthropologists routinely macerate human bone for the purposes of identity and trauma analysis, but the heat and chemical treatments used can destroy genetic evidence. As a follow‐up to a previous study on nuclear DNA recovery that used pig ribs, this study utilizes human skeletal remains treated with various bone maceration techniques for nuclear DNA amplification using the standard Combined DNA Index System (CODIS) markers. DNA was extracted from 18 samples of human lower leg bones subjected to nine chemical and heat maceration techniques. Genotyping was carried out using the AmpF?STR^® COfiler^® and AmpF?STR^® Profiler Plus^® ID kits. Results showed that heat treatments via microwave or Biz/Na₂CO₃ in sub‐boiling water efficiently macerate bone and produce amplifiable nuclear DNA for genetic analysis. Long‐term use of chemicals such as hydrogen peroxide is discouraged as it results in poor bone quality and has deleterious effects on DNA amplification.     

PowerPlex 16 HS: Internal validation of a new tool for genetic analysis of forensic and parentage testing

Forensic human identification requires powerful and efficient tools to obtain useful results in a minimum timeframe. In this study several forensic and parentage samples that could not be analyzed with others kits were studied using the recently available PowerPlex^® 16 HS kit (Promega). DNA was extracted using four different methods, depending upon the particular sample, and the PCR products were run on an ABI 3130XL Sequencer. The resultant DNA profiles were analyzed using Gene Mapper ID v 3.2 Analysis Software (ABI). Of 30 samples processed with the PowerPlex^® 16 HS system, genetic analysis was successful in 18 (60%). The results obtained show that the PowerPlex^® 16 HS is a valuable tool for forensic identification and parentage testing that is particularly useful for difficult samples that have not yielded adequate results with other methods.     

Evaluation of the PowerPlex Fusion System in a sample from East Timor

East Timor is a country located in Southeast Asia. In this study, we determined allele frequencies and forensic parameters for 24 STR autosomal loci included in the PowerPlex^® Fusion System. Autosomal STR data was collected from saliva samples of 100 individuals from East Timor. The amplification of the 24 autosomal STRs was performed using PowerPlex^® Fusion System (Promega Corporation) and the amplified products were analysed on 3500 Genetic Analyser using GeneMapper^® ID-X 1.2 Software (Applied Biosystems). All the analysed loci meet Hardy–Weinberg equilibrium after Bonferroni correction. In our samples, we found “off-ladder” alleles (D2S441, Penta E and FGA locus) confirmed by reamplification, amplification with others kits and sequenced when justified.     

A comparative study of two extraction methods routinely used for DNA recovery from simulated post coital samples

In sexual assault cases DNA profiling of spermatozoa can be of critical importance. Most methods use differential extraction of the spermatozoa to separate it from the female component. Here we have compared two commercially available differential extraction methods, the QIAamp^® DNA mini kit (Qiagen) and Differex™ with the DNA IQ^® System (Promega). Simulated postcoital samples were prepared using buccal cells from a female donor and spermatozoa from three male donors. A dilution series ranging from neat semen to a 1:1500 dilution (semen:dH₂O) was prepared and mixed with an equal volume of saliva from a female donor. Extraction efficiency was assessed using DNA concentration measured with NanoDrop 2000 and Quantifiler^® Human DNA Quantification Kit and the profile count of full, partial and mixed DNA profiles generated using SGM Plus and PowerPlex^® ESI 17. Statistical analysis was carried out using Randomisation in R, which is a robust model making no assumption of the distribution of data. Based on the amount of DNA extracted and the types of profiles no significant difference in the performance of the two extraction kits was seen. However, the processing time taken with the Differex™ System was about half than that of the QIAamp^® DNA mini kit and involved fewer liquid transfers.     

A search for obligatory paternal alleles in a DNA database to find an alleged rapist in a fatherless paternity case

Abstract: A sexual assault case resulted in a pregnancy, which was subsequently aborted. The alleged father of the fetus was unknown. Maternal and fetal types were obtained using the 11‐locus AmpF?STR^® SGM Plus^® kit. The national DNA database was searched for the paternal obligatory alleles and detected two suspects who could not be excluded as father of the male fetus. Additional typing using the AmpF?STR^® Minifiler^? kit, containing three additional autosomal loci, was not sufficient to exclude either suspect. Subsequent typing using the PowerPlex^® 16, containing four additional loci, and Y‐Filer^? kits resulted in excluding one suspect. Searching a database for paternal obligatory alleles can be fruitful, but is fraught with possible false positive results so that finding a match must be taken as only preliminary evidence.     

Long Allele Designations at D2S1338 and D19S433 Loci as Influenced by Various Multiplex STR Kits

European forensic laboratories are replacing the STR multiplex kits with the new generation 16/17 STR kits. This study examines the influence of the new generation kits and the new Applied Biosystems 3500xL Genetic Analyzer on the designation of long D2S1338 and D19S433 off‐ladder alleles. Different allele calls were obtained using the new NGM? (Applied Biosystems) and PowerPlex^® ESI? (Promega) kits compared with AmpF?STR^® SGM Plus? kit (Applied Biosystems). Sequence analysis was used to determine accurate allele designation. The new multiplex kits and the 3500xL Genetic Analyzer improved accuracy of long allele designations. DNA databases worldwide include countless profiles obtained by previous kits. Discrepancies between the new and former technologies may cause failure to detect hits. Discordance is expected due to primer sequence differences between various kits. An additional discordance, occurring in long alleles, independent of primer sequence is reported in this study.     

Simplified Direct PCR Method for Reference Buccal Samples Using a Non-FTA Card by Omitting the Pretreatment Step

When using non-FTA cards in commercial multiplex STR kits for direct PCR, pretreatment steps with specific buffers are recommended. Here, we designed a rapid direct PCR method utilizing a non-FTA card, Oral Cell Sampling Kit, by omitting the pretreatment step involving Prep-n-Go™ Buffer, and it showed compatibility with the GlobalFiler™ Express PCR Amplification Kit, GlobalFiler™ PCR Amplification Kit, and PowerPlex^® Fusion system. To optimize the PCR conditions, we tested the method with different final PCR volumes and cycles. Finally, we conducted a performance test using 50 Korean buccal samples and confirmed the high performance of the method, detecting more than 90% of the samples with full profiles when using GlobalFiler™ PCR Amplification Kit and PowerPlex^® Fusion system at 29 cycles in a 10 μL final PCR volume. Thus, we report a simple direct PCR set-up to analyze reference samples collected using a non-FTA card manufactured in Korea.     

Autosomal short tandem repeat analysis of ancient DNA by coupled use of mini- and conventional STR kits

Abstract: Multiplex autosomal short tandem repeat (STR) genotyping enables researchers to obtain genetic information from ancient human samples. In this study, we tested newly developed AmpF?STR^® MiniFiler? kit for autosomal STR analysis of ancient DNA (aDNA), using human femurs (n = 8) collected from medieval Korean tombs. After extracting aDNA from the bones, autosomal STR analyses were repeated for each sample using the AmpF?STR^® MiniFiler? and Identifiler? kits. Whereas only 21.87% of larger‐sized loci profiles could be obtained with the Identifiler? kit, 75% of the same loci profiles were determined by MiniFiler? kit analysis. This very successful amplification of large‐sized STR markers from highly degraded aDNA suggests that the MiniFiler? kit could be a useful complement to conventional STR kit analysis of ancient samples.     

Inferring the Number of Contributors to Complex DNA Mixtures Using Three Methods: Exploring the Limits of Low‐Template DNA Interpretation

In forensic DNA casework, the interpretation of an evidentiary profile may be dependent upon the assumption on the number of individuals from whom the evidence arose. Three methods of inferring the number of contributors—NOCIt, maximum likelihood estimator, and maximum allele count, were evaluated using 100 test samples consisting of one to five contributors and 0.5–0.016 ng template DNA amplified with Identifiler^® Plus and PowerPlex^® 16 HS. Results indicate that NOCIt was the most accurate method of the three, requiring 0.07 ng template DNA from any one contributor to consistently estimate the true number of contributors. Additionally, NOCIt returned repeatable results for 91% of samples analyzed in quintuplicate, while 50 single‐source standards proved sufficient to calibrate the software. The data indicate that computational methods that employ a quantitative, probabilistic approach provide improved accuracy and additional pertinent information such as the uncertainty associated with the inferred number of contributors.     

The effect of cleaning agents on the ability to obtain DNA profiles using the Identifiler™ and PowerPlex® Y multiplex kits

Abstract: A year after the introduction of Identifiler? into the forensic DNA laboratories of the Institute of Environmental Science and Research Limited (ESR), increasing occurrences of dropout of the three loci, D7S820, D18S51, and FGA, were observed in samples where the DNA was not degraded and sufficient DNA was present that full DNA profiles were to be expected. The dropout was either partial or complete at these loci. Full profiles could sometimes be obtained by reamplification of samples using the same input amount of DNA. After a thorough investigation of the methods and procedures used in the laboratory, the cause of this inhibition was identified as the cleaning agent TriGene? ADVANCE. This was determined after the deliberate addition of varying amounts of different cleaning reagents into the DNA amplification reactions. At concentrations of 0.004% TriGene? ADVANCE caused inhibition resulting in tri‐loci dropout. At concentrations of 0.04% and higher, complete inhibition was observed. An effect was also seen on the amplification of samples using the Y STR profiling system PowerPlex^®Y. This work highlights the importance of checking all reagents and chemicals prior to use, even those with no apparent direct influence on the DNA profiling process.     

Mitochondrial DNA Validation in a State Laboratory*,†

Abstract: Because of the inception of the FBI Regional mitochondrial DNA (mtDNA) laboratories, many do not see establishing state/local mtDNA processing laboratories as a priority. Yet there is a long‐term need for mtDNA processing that will exceed the capabilities of the FBI Regional mtDNA laboratories and the few other laboratories that are currently processing mtDNA, and that need can be fulfilled by state/local laboratories. Thus, the DNA Unit of the Delaware Office of the Chief Medical Examiner (OCME‐DNA Unit) completed validation of in‐house mtDNA testing in January 2007. The validation plan for mtDNA processing included the following sections: preliminary research, sensitivity and contamination studies, ExoSAP‐IT^® optimization, BigDye^® optimization, sequencing and 310 optimization, sample preparation and extraction optimization, heteroplasmy, mixtures, and reproducibility. All sections of the validation were successfully completed, and mtDNA processing of skeletal remains, teeth, and hairs, as well as blood and buccal reference samples was adopted by the OCME‐DNA Unit.     

Detection and Identification of Psilocybe cubensis DNA Using a Real‐Time Polymerase Chain Reaction High Resolution Melt Assay,

Psilocybe cubensis, or “magic mushroom,” is the most common species of fungus with psychedelic characteristics. Two primer sets were designed to target Psilocybe DNA using web‐based software and NBCI gene sequences. DNA was extracted from eighteen samples, including twelve mushroom species, using the Qiagen DNeasy^® Plant Mini Kit. The DNA was amplified by the polymerase chain reaction (PCR) using the primers and a master mix containing either a SYBR^® Green I, Radiant? Green, or LCGreen Plus^® intercalating dye; amplicon size was determined using agarose gel electrophoresis. The PCR assays were tested for amplifiability, specificity, reproducibility, robustness, sensitivity, and multiplexing with primers that target marijuana. The observed high resolution melt (HRM) temperatures for primer sets 1 and 7 were 78.85 ± 0.31°C and 73.22 ± 0.61°C, respectively, using SYBR^® Green I dye and 81.67 ± 0.06°C and 76.04 ± 0.11°C, respectively, using Radiant? Green dye.     

Effects of histological staining on the analysis of human DNA from archived slides

Abstract: Archived slides of cell smears treated with histological stains for sperm detection are often the only source of DNA available when cold cases are reopened. There have been conflicting reports as to the negative effects of particular histological stains on DNA recovery and quality from human cells, making stain selection an important consideration for forensic laboratories. This study investigates the effect of several staining systems on DNA recovery from histological slide samples stored from 0 to 10 weeks. DNA profiles obtained after analysis of these samples with AmpFlSTR^® Identifiler? and increased cycle AmpFlSTR^® SGM Plus? short tandem repeat (STR) profiling systems and the effects that these stains have on DNA quantity and quality over time are described. Results indicate that Christmas Tree and Hematoxylin and Eosin stains do not have significantly different effects on DNA quality after 10‐week storage of slides. This research will assist scientists to select staining systems that have minimal deleterious effects on the DNA recovered.     

Developmental validation of the AmpFℓSTR® Identifiler® Plus PCR Amplification Kit: an established multiplex assay with improved performance

Abstract: Analysis of length polymorphism at short tandem repeat (STR) loci utilizing multiplex polymerase chain reaction (PCR) remains the primary method for genotyping forensic samples. The AmpF?STR^® Identifiler^® Plus PCR Amplification Kit is an improved version of the AmpF?STR^® Identifiler^® PCR Amplification Kit and amplifies the core CODIS loci: D3S1358, D5S818, D7S820, D8S1179, D13S317, D16S539, D18S51, D21S11, CSF1PO, FGA, TH01, TPOX, and vWA. Additional loci amplified in the multiplex reaction are the sex‐determinant, amelogenin, and two internationally accepted loci, D2S1338 and D19S433. While the primer sequences and dye configurations were unchanged, the AmpF?STR^® Identifiler^® Plus PCR Amplification Kit features an enhanced buffer formulation and an optimized PCR cycling protocol that increases sensitivity, provides better tolerance to PCR inhibitors, and improves performance on mixture samples. The AmpF?STR^® Identifiler^® Plus PCR Amplification Kit has been validated according to the FBI/National Standards and Scientific Working Group on DNA Analysis Methods (SWGDAM) guidelines. The validation results support the use of the AmpF?STR^® Identifiler^® Plus PCR Amplification Kit for human identity and parentage testing.     

Developmental validation of the PowerPlex ESX 16 and PowerPlex ESX 17 Systems

We describe the developmental validation study performed on the PowerPlex^® ESX 16 (European Standard Extended 16) and the PowerPlex^® ESX 17 Systems, part of a suite of four new DNA profiling kits developed by Promega in response to the ENFSI and EDNAP groups’ call for new STR multiplexes for Europe. The PowerPlex^® ESX 16 System combines the 11 loci compatible with the UK National DNA Database, contained within the AmpFlSTR^® SGM Plus^® PCR Amplification Kit, with five additional loci: D2S441, D10S1248, D22S1045, D1S1656 and D12S391. The multiplex was designed to incorporate these five new loci as mini- and midi-STRs while maintaining the loci found in the AmpFlSTR^® SGM Plus^® kit as standard size. The PowerPlex^® ESX 17 System amplifies the same loci as the PowerPlex^® ESX 16 System, but with the addition of a primer pair for the SE33 locus. Tests were designed to address the developmental validation guidelines issued by the Scientific Working Group on DNA Analysis Methods (SWGDAM), and those of the DNA Advisory Board (DAB). Samples processed include DNA mixtures, PCR reactions spiked with inhibitors, a sensitivity series, and 306 United Kingdom donor samples to determine concordance with data generated with the AmpFlSTR^® SGM Plus^® kit. Allele frequencies from 242 white Caucasian samples collected in the United Kingdom are also presented. The PowerPlex^® ESX 16 and ESX 17 Systems are robust and sensitive tools, suitable for the analysis of forensic DNA samples. Full profiles were routinely observed with 62.5 pg of a fully heterozygous single source DNA template. In mixture analysis, a range of 52-95% of unique minor contributor alleles was observed at 19:1 mixture ratios where only 25 pg of the minor component was present. Improved sensitivity combined with the robustness afforded by smaller amplicons has substantially improved the quantity of information obtained from degraded samples, and the improved chemistry confers exceptional tolerance to high levels of laboratory prepared inhibitors.     

Getting Ahead: Extraction of DNA from Skeletonized Cranial Material and Teeth

Between 1990 and 2018, the Defense POW/MIA Accounting Agency submitted 2177 cranial elements and 1565 teeth to the Armed Forces Medical Examiner System—Armed Forces DNA Identification Laboratory for DNA testing. In an effort to identify missing United States service members, materials were recovered from wartime losses inclusive of World War II, the Korean War, and Southeast Asia. Using four different DNA extraction protocols, DNA testing was performed using mitochondrial DNA Sanger sequencing, modified AmpFlSTR^® Yfiler?, AmpFlSTR^® MiniFiler?, PowerPlex^® Fusion, or Next Generation Sequencing. This paper aims to provide optimal strategies for the DNA testing of skeletonized cranial materials. Cranial elements produced the most consistent results in Sanger sequencing using an organic purification; however, teeth were most successful for the same platform with an inorganic purification. The inverse is true for STR testing of cranial bones. Of the cranial elements, the temporal provided the most consistent results.     

Qiagen's Investigator™ Quantiplex Kit as a Predictor of STR Amplification Success from Low‐Yield DNA Samples,

Qiagen's Investigator? Quantiplex kit, a total human DNA quantitation kit, has a 200‐base pair internal control, fast cycling time, and scorpion molecules containing a covalently linked primer, probe, fluorophore, and quencher. The Investigator? Quantiplex kit was evaluated to investigate a value under which complete short tandem repeat (STR) failure was consistently obtained. Buccal swabs were extracted using the Qiagen QIAamp^® DNA Blood Mini Kit, quantified with the Investigator? Quantiplex kit using a tested half‐volume reaction, amplified with the ABI AmpFlSTR^® Identifiler kit, separated on the 3100Avant Genetic Analyzer, and data analyzed with GeneMapper^® ID v.3.2. While undetected samples were unlikely to produce sufficient data for statistical calculations or CODIS upload (2.00 alleles and 0.82 complete loci on average), data may be useful for exclusionary purposes. Thus, the Investigator? Quantiplex kit may be useful for predicting STR success. These findings are comparable with previously reported data from the Quantifiler? Human kit.     

An Accelerated Analytical Process for the Development of STR Profiles for Casework Samples

Significant efforts are being devoted to the development of methods enabling rapid generation of short tandem repeat (STR) profiles in order to reduce turnaround times for the delivery of human identification results from biological evidence. Some of the proposed solutions are still costly and low throughput. This study describes the optimization of an analytical process enabling the generation of complete STR profiles (single‐source or mixed profiles) for human identification in approximately 5 h. This accelerated process uses currently available reagents and standard laboratory equipment. It includes a 30‐min lysis step, a 27‐min DNA extraction using the Promega Maxwell^®16 System, DNA quantification in <1 h using the Qiagen Investigator^® Quantiplex HYres kit, fast amplification (<26 min) of the loci included in AmpF?STR^® Identifiler^®, and analysis of the profiles on the 3500‐series Genetic Analyzer. This combination of fast individual steps produces high‐quality profiling results and offers a cost‐effective alternative approach to rapid DNA analysis.