Estimating the probability of allelic drop-out of STR alleles in forensic genetics

In crime cases with available DNA evidence, the amount of DNA is often sparse due to the setting of the crime. In such cases, allelic drop-out of one or more true alleles in STR typing is possible. We present a statistical model for estimating the per locus and overall probability of allelic drop-out using the results of all STR loci in the case sample as reference. The methodology of logistic regression is appropriate for this analysis, and we demonstrate how to incorporate this in a forensic genetic framework.     

Stochastic sampling effects in STR typing: Implications for analysis and interpretation

The analysis and interpretation of forensic STR typing results can become more complicated when reduced template amounts are used for PCR amplification due to increased stochastic effects. These effects are typically observed as reduced heterozygous peak-height balance and increased frequency of undetected alleles (allelic “dropout”). To investigate the origins of these effects, a study was performed using the AmpFlSTR^® Identifiler Plus^® and MiniFiler^® kits to amplify replicates from a dilution series of NIST Human DNA Quantitation Standard (SRM^® 2372A). The resulting amplicons were resolved and detected on two different genetic analyzer platforms, the Applied Biosystems 3130xL and 3500 analyzers. Results from our study show that the four different STR/genetic analyzer combinations exhibited very similar peak-height ratio statistics when normalized for the amount of template DNA in the PCR. Peak-height ratio statistics were successfully modeled using the Poisson distribution to simulate pre-PCR stochastic sampling of the alleles, confirming earlier explanations that sampling is the primary source for peak-height imbalance in reduced template dilutions. In addition, template-based pre-PCR sampling simulations also successfully predicted allelic dropout frequencies, as modeled by logistic regression methods, for the low-template DNA dilutions. We discuss the possibility that an accurately quantified DNA template might be used to characterize the linear signal response for data collected using different STR kits or genetic analyzer platforms, so as to provide a standardized approach for comparing results obtained from different STR/CE combinations and to aid in validation studies.     

Validation and assessment of the Investigator® 24plex QS kit for forensic casework application: Comparison with the PowerPlex® fusion system and GlobalFiler™ PCR amplification kits

Casework evidence samples are likely to be placed under diverse and harsh environments as compared to quantified DNA samples including serial-diluted standard DNA samples. Internal validation of a novel STR kit using casework evidence sample, which is conducted according to various conditions such as DNA contamination and degradation, is crucial before being used as a forensic application. Therefore, this study aimed to elucidate the reliability of the Investigator® 24plex QS kit through DNA derived from casework evidence and to assess whether it is applicable to STR analysis together with PowerPlex® Fusion System and GlobalFiler™ PCR Amplification Kit. DNA was extracted from 189 casework evidence samples in a total of 77 cases. The mismatch of the allelic size of this kit through allelic sizing precision test, was suitable according to ENFSI guidelines. All heterozygous balance of the three kits were above 0.6 recommended value of ENFSI guideline. The number of allele drop-in was most frequent in the GlobalFiler™ PCR Amplification Kit. In addition, the number of allele drop-out was most frequent in the Investigator® 24plex QS kit. The cutoff concentration of DNA detected in three kits of one complete STR was approximately 45 pg/μL on average. Despite of several limitations, the Investigator® 24plex QS kit is considered to have the capability to be used for STR analysis of casework evidence samples.     

Investigation of single nucleotide polymorphism loci susceptible to degradation by ultraviolet light

DNA in biological fluids is often degraded by environmental factors. Given that single nucleotide polymorphism (SNP) analyses require shorter amplicons than short tandem repeat (STR) analyses do, their use in human identification using degraded samples has recently attracted attention. Although various SNP loci are used to analyze degraded samples, it is unclear which ones are more appropriate. To characterize and identify SNP loci that are susceptible or resistant to degradation, we artificially degraded DNA, obtained from buccal swabs from 11 volunteers, by exposure to ultraviolet (UV) light for different durations (254 nm for 5, 15, 30, 60, or 120 min) and analyzed the resulting SNP loci. DNA degradation was assessed using gel electrophoresis, STR, and SNP profiling. DNA fragmentation occurred within 5 min of UV irradiation, and successful STR and SNP profiling decreased with increasing duration. However, 73% of SNP loci were still detected correctly in DNA samples irradiated for 120 min, a dose that rendered STR loci undetectable. The unsuccessful SNP typing and the base call failure of nucleotides neighboring the SNPs were traced to rs1031825, and we found that this SNP was susceptible to UV light. When comparing the detection efficiencies of STR and SNP loci, SNP typing was more successful than STR typing, making it effective when using degraded DNA. However, it is important to use rs1031825 with caution when interpreting SNP analyses of degraded DNA.     

Forensic genetic SNP typing of low-template DNA and highly degraded DNA from crime case samples

Heterozygote imbalances leading to allele drop-outs and disproportionally large stutters leading to allele drop-ins are known stochastic phenomena related to STR typing of low-template DNA (LtDNA). The large stutters and the many drop-ins in typical STR stutter positions are artifacts from the PCR amplification of tandem repeats. These artifacts may be avoided by typing bi-allelic markers instead of STRs. In this work, the SNPforID multiplex assay was used to type LtDNA. A sensitized SNP typing protocol was introduced, that increased signal strengths without increasing noise and without affecting the heterozygote balance. Allele drop-ins were only observed in experiments with 25 pg of DNA and not in experiments with 50 and 100 pg of DNA. The allele drop-in rate in the 25 pg experiments was 0.06% or 100 times lower than what was previously reported for STR typing of LtDNA. A composite model and two different consensus models were used to interpret the SNP data. Correct profiles with 42–49 SNPs were generated from the 50 and 100 pg experiments, whereas a few incorrect genotypes were included in the generated profiles from the 25 pg experiments. With the strict consensus model, between 35 and 48 SNPs were correctly typed in the 25 pg experiments and only one allele drop-out (error rate: 0.07%) was observed in the consensus profiles.A total of 28 crime case samples were selected for typing with the sensitized SNPforID protocol. The samples were previously typed with old STR kits during the crime case investigation and only partial profiles (0–6 STRs) were obtained. Eleven of the samples could not be quantified with the Quantifiler™ Human DNA Quantification kit because of partial or complete inhibition of the PCR. For eight of these samples, SNP typing was only possible when the buffer and DNA polymerase used in the original protocol was replaced with the AmpFℓSTR^® SEfiler Plus™ Master Mix, which was developed specifically for challenging forensic samples. All the crime case samples were successfully typed with the SNPforID multiplex assay and the match probabilities ranged from 1.1 × 10⁻¹⁵ to 7.9 × 10⁻²³. In comparison, four of the samples could not be typed with the AmpFℓSTR^® SEfiler Plus™ kit and the match probabilities were higher than 10⁻⁷ for another six samples.     

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.     

AB0 blood group genotyping of ancient DNA by PCR-RFLP

The paper presents an PCR-RFLP-based method to determine AB0 blood groups at the genotype level. In order to ensure the applicability of the method to severely degraded DNA, new sets of primers were designed that amplify 103/104 bp and 64 bp sequences on exon 6 and exon 7 of chromosome 9, respectively. The amplification of the two PCR products and the subsequent RFLP analysis with four endonucleases was revealed to be an effective and reliable way to determine AB0 bloodgroups at the genotype level, distinguishing the alleles A, B, 0(1), 0(1v), and 0(2). PCR analysis of severely degraded sample material may possibly require higher cycle numbers. Therefore, the experiments presented here including those on positive control samples, were carried out employing 45 amplification cycles in order to ensure the validity of the amplification and RFLP analysis. As positive controls, small amounts of modern intact DNA extracted from saliva samples of 12 individuals with known AB0 phenotypes were used. The protocols for the AB0 typing were then applied to ancient degraded DNA extracted from 15 archaeological bones and teeth about 250 and 3,000 years old, respectively. The results presented for the archaeological sample material are based on repeated analysis derived from two independently processed DNA extracts of each sample. Moreover, the authentification process for the results derived from the archaeological samples included repeated multiplex STR genotyping of the extracts, showing the genetic uniqueness of the extracts which is the strongest possible indicator for the authenticity of an unknown DNA sample. Additionally, it was possible to compare the STR typing results to those from previous studies using the same material. Both the AB0 typing and the STR typing revealed fully reproducible results in all cases.     

A proposed nomenclature for 15 canine-specific polymorphic STR loci for forensic purposes

We performed a population study on 15 polymorphic STR loci (FH2010, FH2079, PEZ2, VWF.X, FH2054, FH2087Ub, FH2611, WILMS-TF, PEZ12, PEZ15, PEZ6, FH2087Ua, ZUBECA4, ZUBECA6, FH2132) on 131 randomly selected dogs. Alleles were identified and grouped according to their estimated fragment length using fixed allelic bins encompassing one base-pair. The allele assignment was confirmed by sequence analysis of homozygote and cloned heterozygote alleles. In order to develop a uniform repeat-based nomenclature, extensive sequence analysis was performed on a selection of alleles from each STR locus. The proposed nomenclature refers to the internationally recognised recommendations for human-specific STR loci in forensic applications. The 15 canine-specific STR loci were grouped into 3 classes (simple STRs, compound STRs and complex/hypervariable STRs) according to their complexity and variability within the repeat structure. Finally, we evaluated the precision of fragment size estimation on a capillary electrophoresis platform and demonstrated reproducibility of fragment length estimation for single base-pair intermediate alleles.     

Development of a SNP set for human identification: A set with high powers of discrimination which yields high genetic information from naturally degraded DNA samples in the Thai population

This study describes the development of a SNP typing system for human identification in the Thai population, in particular for extremely degraded DNA samples. A highly informative SNP marker set for forensic identification was identified, and a multiplex PCR-based Invader assay was developed. Fifty-one highly informative autosomal SNP markers and three sex determination SNP markers were amplified in two multiplex PCR reactions and then detected using Invader assay reactions. The average PCR product size was 71 base pairs. The match probability of the 54-SNP marker set in 124 Thai individuals was 1.48 × 10⁻²¹, higher than that of STR typing, suggesting that this 54-SNP marker set is beneficial for forensic identification in the Thai population. The selected SNP marker set was also evaluated in 90 artificially degraded samples, and in 128 naturally degraded DNA samples from real forensic casework which had shown no profiles or incomplete profiles when examined using a commercial STR typing system. A total of 56 degraded samples (44%) achieved the matching probability (PM) equivalent to STR gold standard analysis (successful genotyping of 44 SNP markers) for human identification. These data indicated that our novel 54-SNP marker set provides a very useful and valuable approach for forensic identification in the Thai population, especially in the case of highly to extremely degraded DNA.In summary, we have developed a set of 54 Thai-specific SNPs for human identification which have higher discrimination power than STR genotyping. The PCRs for these 54 SNP markers were successfully combined into two multiplex reactions and detected with an Invader assay. This novel SNP genotyping system also yields high levels of genetic information from naturally degraded samples, even though there are much more difficult to recover than artificially degraded samples.     

Performance of two 17 locus forensic identification STR kits-Applied Biosystems's AmpFℓSTR® NGMSElect™ and Promega's PowerPlex® ESI17 kits

We compared the performance of two recently released 17 loci STR multiplexes for human identification: Applied Biosystems's AmpF?STR^® NGMSElect? and Promega's PowerPlex^® ESI17. The comparative parameters were chosen by their relevance in forensic identification and particularly in crime cases. The comparative analyses encompass: amplification ability, heterozygote balance, allelic drop-out, drop-in, stutter analysis and inter-locus balance.Four DNA profiles were analysed in various concentrations in a serial dilution experiment. The amounts of DNA in the PCR ranged from 3 pg to 420 pg and were analysed in triplicate using 28, 29 and 30 PCR cycles. In order to compare the kits, aliquots from each sample were analysed with both kits under identical conditions. Furthermore, DNA profiles from 200 reference profiles were analysed using both kits.The results from the statistical analyses did not indicate any substantial differences of practical relevance between the kits for forensic case work. For all parameters included in this comparative study, the two kits showed no departure from previously observed patterns relative to e.g. the amounts of DNA or amplicon lengths. Based on our analyses, both kits are considered applicable for forensic crime case work.     

Parentally imprinted allele typing at a short tandem repeat locus in intron 1a of imprinted gene KCNQ1

A short tandem repeat (STR) in the intron 1a of paternally imprinted gene, KCNQ1, is evaluated as a new probe for use in parentally imprinting allele (PIA) typing. This typing can determine the inheritance of one allele from father by the methylation difference. Allelic and genotypic frequencies of the STR were determined using samples from 175 unrelated Japanese and 170 unrelated Germans. The polymorphism information contents were 0.652 and 0.634 for the Japanese and the Germans, respectively, indicating usefulness in individual identification. This method was applied to five Japanese families consisting of 19 individuals. Genomic DNA was digested by methylation-sensitive restriction endonucleases, HhaI and HapII, followed by PCR amplification using two-step sandwich primer sets and the products were analyzed on polyacrylamide gel electrophoresis. For all of the families, each child's paternal allele given by PIA typing corresponded to one of the two alleles from father, not the two from mother, that were determined by the STR genotyping. The results demonstrate that this STR probe is feasible for use in PIA typing and that its typing method can contribute to paternity testing.     

DNA identification of formalin-fixed organs is affected by fixation time and type of fixatives: using the AmpF l STR(R) Identifiler(R) PCR Amplification Kit

Personal identification using DNA typing of formalin-fixed tissue is very important in the forensic sciences. However, few studies have been conducted to determine the detection limit of DNA typing of formalin fixation time in samples using the AmpF?STR(?) Identifiler(?) PCR Amplification Kit (Identifiler Kit). We collected samples from five cadavers submitted for forensic autopsies, and fixed them either in a 10% formalin solution, or in a 10% neutral-buffered formalin solution. The amount of template DNA for polymerase chain reaction (PCR) amplification and the detection limit of DNA typing for the Identifiler Kit were determined. When tissues were fixed in 10% formalin, 10 ng of DNA template was required for successful genotyping even after three-hour fixation and 100 ng was required after one-week fixation for PCR amplification. However, when tissues were fixed in 10% neutral-buffered formalin, the required amount of DNA template was 1 ng for a fixation time of three hours to three days and 125 ng for three months. Fixation time in neutral-buffered formalin was longer for successful PCR than that in formalin solution. Dropout was more common with increasing formalin fixation time. These results suggest that neutral-buffered formalin is preferred to formalin for fixation of tissues if they are to be subjected to DNA typing and that tissues fixed with neutral-buffered formalin can be used for DNA typing using the Identifiler Kit unless the fixation time exceeds one month.     

Nuclear,chloroplast, and mitochondrial data of a US cannabis DNA database

As Cannabis sativa (marijuana) is a controlled substance in many parts of the world, the ability to track biogeographical origin of cannabis could provide law enforcement with investigative leads regarding its trade and distribution. Population substructure and inbreeding may cause cannabis plants to become more genetically related. This genetic relatedness can be helpful for intelligence purposes. Analysis of autosomal, chloroplast, and mitochondrial DNA allows for not only prediction of biogeographical origin of a plant but also discrimination between individual plants. A previously validated, 13-autosomal STR multiplex was used to genotype 510 samples. Samples were analyzed from four different sites: 21 seizures at the US–Mexico border, Northeastern Brazil, hemp seeds purchased in the US, and the Araucania area of Chile. In addition, a previously reported multi-loci system was modified and optimized to genotype five chloroplast and two mitochondrial markers. For this purpose, two methods were designed: a homopolymeric STR pentaplex and a SNP triplex with one chloroplast (Cscp001) marker shared by both methods for quality control. For successful mitochondrial and chloroplast typing, a novel real-time PCR quantitation method was developed and validated to accurately estimate the quantity of the chloroplast DNA (cpDNA) using a synthetic DNA standard. Moreover, a sequenced allelic ladder was also designed for accurate genotyping of the homopolymeric STR pentaplex. For autosomal typing, 356 unique profiles were generated from the 425 samples that yielded full STR profiles and 25 identical genotypes within seizures were observed. Phylogenetic analysis and case-to-case pairwise comparisons of 21 seizures at the US–Mexico border, using the Fixation Index (F_ST) as genetic distance, revealed the genetic association of nine seizures that formed a reference population. For mitochondrial and chloroplast typing, subsampling was performed, and 134 samples were genotyped. Complete haplotypes (STRs and SNPs) were observed for 127 samples. As expected, extensive haplotype sharing was observed; five distinguishable haplotypes were detected. In the reference population, the same haplotype was observed 39 times and two unique haplotypes were also detected. Haplotype sharing was observed between the US border seizures, Brazil, and Chile, while the hemp samples generated a distinct haplotype. Phylogenetic analysis of the four populations was performed, and results revealed that both autosomal and lineage markers could discern population substructure.

     

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.     

A simple Duplex-PCR to evaluate the DNA quality of anthropological and forensic samples prior short tandem repeat typing

Typing of DNA from ancient or otherwise highly degraded material, e.g. formalin fixed tissues, can be difficult, time consuming and costly. Very often, genetic typing is not possible at all. We present an inexpensive and easy to use Duplex-PCR that amplifies a 164 bp fragment specific for nuclear DNA together with a 260 bp mitochondrial DNA fragment and that can be employed as a pretest prior to short tandem repeat (STR) typing. All together, we analyzed DNA from 20 ancient bones, 20 formalin fixed tissues and 20 other forensic samples in different concentrations. Each sample that failed in the presented Duplex-amplification was also negative for STR typing, while samples that showed strong and clear signals in the Duplex-PCR led to reproducible genetic profiles using the multiplex kits AmpFLSTR Identifiler and Powerplex ES. The Duplex-PCR worked as a reliable indicator of DNA quality in the sample.     

Next-generation sequencing analysis of off-ladder alleles due to migration shift caused by sequence variation at D12S391 locus

In short tandem repeat (STR) analysis, length polymorphisms are detected by capillary electrophoresis (CE). At most STR loci, mobility shift due to sequence variation in the repeat region was thought not to affect the typing results. In our recent population studies of 1501 Japanese individuals, off-ladder calls were observed at the D12S391 locus using PowerPlex Fusion in nine samples for allele 22, one sample for allele 25, and one sample for allele 26. However, these samples were typed as ordinary alleles within the bins using GlobalFiler. In this study, next-generation sequencing analysis using MiSeq was performed for the D12S391 locus from the 11 off-ladder samples and 33 other samples, as well as the allelic ladders of PowerPlex Fusion and GlobalFiler. All off-ladder allele 22 in the nine samples had [AGAT]₁₁[AGAC]₁₁ as a repeat structure, while the corresponding allele was [AGAT]₁₅[AGAC]₆[AGAT] for the PowerPlex Fusion ladder, and [AGAT]₁₃[AGAC]₉ for the GlobalFiler ladder. Overall, as the number of [AGAT] in the repeat structure decreased at the D12S391 locus, the peak migrated more slowly using PowerPlex Fusion, the reverse strand of which was labeled, and it migrated more rapidly using GlobalFiler, the forward strand of which was labeled. The allelic ladders of both STR kits were reamplified with our small amplicon D12S391 primers and their mobility was also examined. In conclusion, off-ladder observations of allele 22 at the D12S391 locus using PowerPlex Fusion were mainly attributed to a relatively large difference of the repeat structure between its allelic ladder and off-ladder allele 22.     

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.     

Optimization and validation of a fast amplification protocol for AmpFlSTR® Profiler Plus® for rapid forensic human identification

The goal of this work was to optimize and validate a fast amplification protocol for the multiplex amplification of the STR loci included in AmpFlSTR(?) Profiler Plus(?) to expedite human DNA identification. By modifying the cycling conditions and by combining the use of a DNA polymerase optimized for high speed PCR (SpeedSTAR? HS) and a more efficient thermal cycler instrument (Bio-RAD C1000?), we were able to reduce the amplification process from 4h to 26 min. No modification to the commercial AmpFlSTR(?) Profiler Plus(?) primer mix was required. When compared to the current Royal Canadian Mounted Police (RCMP) amplification protocol, no differences with regards to specificity, sensitivity, heterozygote peak height ratios and overall profile balance were noted. Moreover, complete concordance was obtained with profiles previously generated with the standard amplification protocol and minor alleles in mixture samples were reliably typed. An increase in n-4 stutter ratios (2.2% on average for all loci) was observed for profiles amplified with the fast protocol compared to the current procedure. Our results document the robustness of this rapid amplification protocol for STR profiling using the AmpFlSTR(?) Profiler Plus(?) primer set and demonstrate that comparable data can be obtained in substantially less time. This new approach could provide an alternative option to current multiplex STR typing amplification protocols in order to increase throughput or expedite time-sensitive cases.     

Prediction of autosomal STR typing success in ancient and Second World War bone samples

Human-specific quantitative PCR (qPCR) has been developed for forensic use in the last 10 years and is the preferred DNA quantification technique since it is very accurate, sensitive, objective, time-effective and automatable. The amount of information that can be gleaned from a single quantification reaction using commercially available quantification kits has increased from the quantity of nuclear DNA to the amount of male DNA, presence of inhibitors and, most recently, to the degree of DNA degradation. In skeletal remains samples from disaster victims, missing persons and war conflict victims, the DNA is usually degraded. Therefore the new commercial qPCR kits able to assess the degree of degradation are potentially able to predict the success of downstream short tandem repeat (STR) typing. The goal of this study was to verify the quantification step using the PowerQuant kit with regard to its suitability as a screening method for autosomal STR typing success on ancient and Second World War (WWII) skeletal remains. We analysed 60 skeletons excavated from five archaeological sites and four WWII mass graves from Slovenia. The bones were cleaned, surface contamination was removed and the bones ground to a powder. Genomic DNA was obtained from 0.5 g of bone powder after total demineralization. The DNA was purified using a Biorobot EZ1 device. Following PowerQuant quantification, DNA samples were subjected to autosomal STR amplification using the NGM kit. Up to 2.51 ng DNA/g of powder were extracted. No inhibition was detected in any of bones analysed. 82% of the WWII bones gave full profiles while 73% of the ancient bones gave profiles not suitable for interpretation. Four bone extracts yielded no detectable amplification or zero quantification results and no profiles were obtained from any of them. Full or useful partial profiles were produced only from bone extracts where short autosomal (Auto) and long degradation (Deg) PowerQuant targets were detected. It is concluded that STR typing of old bones after quantification with the PowerQuant should be performed only when both Auto and Deg targets are detected simultaneously with no respect to [Auto]/[Deg] ratio. Prediction of STR typing success could be made according to successful amplification of Deg fragment. The PowerQuant kit is capable of identifying bone DNA samples that will not yield useful STR profiles using the NGM kit, and it can be used as a predictor of autosomal STR typing success of bone extracts obtained from ancient and WWII skeletal remains.     

Usefulness of blood vessels as a DNA source for PCR-based genotyping based on two cases of corpse dismemberment

The success of PCR-based genotyping of decomposed remains depends on the quality of extracted DNA. Hard tissues and muscles are preferred because of their DNA stability. However, in dismembered corpses the choice of a suitable DNA source is more limited. In short tandem repeat (STR) analysis in two cases of dismembered corpses, we found an advantage of using blood vessels over muscles. To confirm that blood vessels are better for STR typing compared to muscle, we collected nine sets of blood vessels and the adjacent muscle from six other decomposed remains and compared the STR profiles between the blood vessel and muscle samples. Better results for STR typing were obtained in blood vessels. Based on these results, we recommend use of blood vessels as material for PCR-based genotyping in identification of dismembered human remains with heavy postmortem changes.