The genetic identification of skeletal remains found in Second World War mass graves is complicated because of the poor quality of the samples. The aim of this study was to set up a workflow for STR typing of such samples combining PCR/CE and PCR/NGS technologies. To this end, 57 DNA samples from an equal number of 75-yearold femurs were studied. After a first round of PCR typing using GlobalFiler CE, 42 samples yielded a full profile and were therefore submitted to our standard workflow. The 15 samples that yielded no or a limited number (2–17/21) of autosomal STR markers as well four bone control samples that provided a full profile with the conventional PCR/CE test were typed in duplicate by the GlobalFiler NGS kit. Despite the degradation of the samples, which resulted in lower coverage and a lower % of on-target reads, reliable sequencing data were obtained from 16/19 samples. The use of a threshold of 30× for the locus call led to a consensus profile (cp) of 20–31/31 STR autosomal loci in 10 samples and to a cp of 8–10/31 loci in two samples, whereas the four control samples yielded a cp of 26–31/31 loci. Finally, the data of the NGS typing were combined with those of the CE typing. This last task allowed us to recover (on average) three alleles per sample and to increase the number of the heterozygous patterns in 37 cases. In total, the combined approach proposed here made possible the genetic typing of 65–100% of the autosomal STR markers in 10/15 (66.6 %) skeletal remains that yielded no or very poor results with the conventional PCR/CE approach. However, because several artefacts (such as allelic drop-out and allelic drop-in) were scored, the risk of mistyping cannot be neglected.
COBISS.SI-ID: 34066179
DNA yield varies by anatomical region, and the selection of bone types that yield maximum recovery of DNA is important to maximize the success of human identification of skeletal remains. The goal of our study was to explore inter- and intra-individual variation in DNA content by measuring nuclear DNA quantity and quality and autosomal STR typing success to determine the most promising skeletal elements for bone sampling. To exclude the influence of taphonomic issues as much as possible, three complete male skeletons from a single Second World War mass grave were examined and all representative skeletal element types of the human body were analyzed. Forty-eight different types of bones from the head, torso, arm, leg, hand, and foot were sampled from each skeleton, 144 bones altogether. The samples were cleaned, and half a gram of bone powder was decalcified using a full demineralization extraction method. The DNA was purified in a Biorobot EZ1 (Qiagen). DNA content and rates of DNA degradation were determined with the PowerQuant (Promega), and the Investigator ESSplex SE QS (Qiagen) was used for STR typing. The highest-yielding bones mostly produced the most complete STR profiles. Among the skeletal elements containing on average the most DNA and producing the most complete profiles in all three skeletons examined were metacarpals, metatarsals, and the petrous portion of the temporal bone. Metatarsals and metacarpals can easily be sampled without using a saw, thus reducing potential DNA contamination. Skeletons from the Second World War can be used as a model for poorly preserved skeletal remains, and the results of the investigation can be applied for genetic identification of highly degraded skeletal remains in routine forensic casework. Although the research was limited to only three skeletons found in a unique mass grave, the data obtained could contribute to sampling strategies for identifying old skeletal remains. More Second World War skeletons will be analyzed in the future to investigate inter-bone variation in the preservation of DNA.
COBISS.SI-ID: 39471619
The killings during the Second World War, with nearly one hundred thousand victims, is one of the greatest losses of life in Slovenia's modern history. This article presents the genetic identification of the victims of the largest family massacre that occurred in Slovenia, in which 10 members of the same family were killed. Seven of them were buried in a hidden mass grave and only two children survived. In 2015 and 2016, two graves were found and three incomplete female skeletons and at least three incomplete male skeletons were exhumed. A total of 12 bones and teeth were analysed and compared to two living relatives. Extracted DNA was quantified using the PowerQuant kit, and various autosomal and Y-STR kits were used for STR typing. Up to 2.7 ng DNA/g of powder was acquired from the samples analysed. We managed to obtain nuclear DNA for successful STR typing from seven bones and one molar. From the female grave, autosomal profiles were obtained only from one skeleton, and from the male grave from five out of six femurs. The relationships between the males were additionally confirmed by analyses of Y-STRs. STR profiles made possible the identification of four family members; one of the aunts from the female grave, and two uncles and the father of the surviving children, who were used as family references, from the male grave. The product rule was used to calculate a combined likelihood ratio for autosomal and Y-STRs, and statistical analyses showed high confidence of correct identification with posterior probability (PP) greater than 99.9% for three out of four victims identified. For identifying the aunt, the PP obtained after ESI-17 and NGM STR typing was too low. To increase the PP, the next-generation sequencing Precision ID GlobalFiler NGS STR Panel was used and, after the analysis of additional STR loci, the statistical analysis showed a PP greater than 99.9%, indicating that a sufficient number of genetic markers had been investigated in identifying the skeletal remains of the aunt. An elimination database containing the genetic profiles of all individuals that had been in contact with the bones was created to ensure traceability in case of contamination, and no matches were found. After more than 70 years, the skeletal remains were returned to the surviving children, who buried their relatives in a family grave.
COBISS.SI-ID: 34586073
This chapter presents analyses of skeletal remains from World War II using a forensic approach. Aged bones are challenging samples of biological material for DNA typing because their DNA content is very low and greatly degraded. The exceptional risk of contamination and the presence of inhibitors further limit the success of DNA typing. Because the DNA content is so limited, aged skeletons are exposed to contamination by people involved in excavation, anthropological analyses, and genetic testing. To prevent and track potential contamination by contemporary DNA, a number of standard precautions are used and they are described. The composition of bones and teeth and their degradation process is discussed. In addition to morphological structure, special attention is paid to factors affecting the preservation of DNA in old bones and teeth. Based on the literature reviewed and some analyses performed, the chapter summarizes which skeletal elements are most suitable for investigating World War II skeletal remains. It discusses how to clean and grind bone and tooth samples, how DNA can be extracted from the powder obtained, and how DNA quality and quantity can be determined for extracts using real-time quantification. The genetic markers most frequently examined in aged DNA and the advantages of new, high-performing sequencing techniques for the development and study of aged DNA are described. Using innovative methods that may help in retrieving higher-quality and increased data makes it possible to investigate more degraded DNA. Storing samples is especially important in laboratories engaged in forensic genetics. Efficient long-term bone storage is necessary to guarantee sample stability across time so that new markers as well as new technologies can be used for future retesting. The results of some aged bone sample storage studies are presented. The chapter concludes with a presentation of World War II victim identifications performed in Slovenia.
COBISS.SI-ID: 42457859
DNA analysis of Second World War skeletal remains is challenging because of the limited yield of DNA that is usually recovered. Recent forensic research has focused on determining which skeletal elements are superior in their preservation of DNA, and little focus has been placed on measuring intra-bone variability. Metatarsals and metacarpals outperformed all the other bones in DNA yield when analyzing all representative skeletal elements of three Second World War victims, and intra-bone variability was not studied. Soft-tissue remnants were found to contribute to higher DNA yield in trabecular bone tissue. Because metatarsals and metacarpals are composed of trabecular epiphyses and a dense diaphysis, the goal of this study was to explore intra-bone variability in DNA content by measuring nuclear DNA quantity and quality using the PowerQuant System (Promega). A total of 193 bones from a single Second World War mass grave were examined. From each bone, DNA was extracted from the compact diaphysis and from both spongy epiphyses combined. This study confirms higher DNA quantity in epiphyses than diaphyses among all the bones analyzed, and more DNA was obtained from metacarpal epiphyses than from metatarsal epiphyses. Therefore, whenever the possibility for sampling both metacarpals and metatarsals from skeletal remains exists, collecting metacarpals is recommended. In cases in which the hands are missing, metatarsals should be sampled. In any case, epiphyses are a richer source of DNA than diaphyses.
COBISS.SI-ID: 53039107