Identifying victims of the largest Second World War family massacre in Slovenia

An optimal skeletal element for DNA testing: Evaluation of DNA quantity and quality from various bone types in routine forensic practice

For human identification, the quality and quantity of DNA must be sufficient for amplification and analysis. When DNA extraction from bone tissues and teeth is required, the optimal skeletal elements should be selected as samples for DNA extraction because DNA yield differs among elements. Recently, some studies have reported that a high quantity of high-quality DNA can be extracted from the small cancellous bones of the hands and feet. In this study, we evaluated the effectiveness of small cancellous bones in the human identification of skeletal remains in routine forensic genetic casework. Cancellous bones [phalanges, (meta)carpal bones, and (meta)tarsal bones)] and the cortical bones (femur and petrous bones) and teeth, which have generally been recommended as samples, were collected from the same individuals that needed identifying using DNA analysis in our laboratory. The quantity of DNA from small cancellous bones tended to be higher than that from cortical bones, and the quality from the former was as high as that from the latter. This study showed that in routine forensic casework, the small cancellous bones of the hands and feet should be actively selected as samples for DNA testing.

Concealed Homicides-A Postmortem Study and Review

ABSTRACT

A study was undertaken at Forensic Science SA, Adelaide, South Australia, of all cases of homicide (January 2003-December 2022) where the victims' bodies had been concealed. Three hundred twenty-six homicides were identified, which included 27 cases where bodies had been deliberately hidden (8%) (age range, 2-82 years; ave, 34.9 years; M:F = 1.5:1). Deaths were due to blunt force trauma (n = 11), sharp force trauma (n = 4), asphyxia (n = 4), gunshot wound (n = 2), and a combination of drowning and asphyxia (n = 1). In 5 cases, the cause of death was not determinable. The methods of concealment (which were sometimes overlapping) included the following: dumping at a hidden/isolated location (n = 8), burial (n = 7), dismembering (n = 3), incinerating (n = 3), hiding in a wheeled garbage bin (n = 2), disposing in garbage resulting in the remains being located at waste disposal facilities (n = 2), hiding in a shed (n = 1), under a concrete floor (n = 1), in a suitcase (n = 1), in a river (n = 1), in a mine shaft (n = 1), and in a septic tank (n = 1). Although it has been asserted that concealed homicides are rarely encountered in forensic practice, the current study has demonstrated that the bodies in at least 8% of victims of homicide in South Australia have undergone some form of concealment.

The last flight of F/O Tadeusz Stabrowski. Identification of the polish pilot

The paper presents the process of identifying an unnamed soldier of the Polish armed forces in the west, whose remains were found in a nameless grave at the municipal cemetery in Le Crotoy in France. The Polish Genetic Database of Victims of Totalitarianism team carried out the research in cooperation with the Ministry of Culture and National Heritage. A comprehensive analysis of autosomal and Y-STR markers was performed. Historical, anthropological, and forensic examinations of the remains were also carried out. The items found with the remains were also examined. Identification based on DNA analysis made it possible to restore the identity of the Polish pilot who died on 11 March 1943 near the French coast, F/O Tadeusz Stabrowski. The airman regained his name in 2018, he was about 26 years old at the time of his death and left behind a grieving wife and son in the United Kingdom. The success of identifying the NN remains was guaranteed by the appointment of an interdisciplinary team consisting of specialists in archaeology, anthropology, history, forensic medicine and forensic genetics. The analysis of historical sources allowed to determine 4 missing airmen whose remains could have been buried in the cemetery in Le Crotoy. An interesting aspect of the research was the cooperation with history enthusiasts and fans of Polish aviation, thanks to which it was finally possible to narrow down the group of pilots sought and reach the family of Tadeusz Stabrowski, who submitted comparative material for research. This is the first case of establishing the identity of a Polish pilot killed in France. Many institutions have been involved in the project, including Polish Ministry of Culture and National Heritage (MDiKN), which partially funded the research.

Improving kinship probability in analysis of ancient skeletons using identity SNPs and MPS technology

In forensic kinship analysis and human identification cases, analysis of STRs is the gold standard. When badly preserved ancient DNA is used for kinship analysis, short identity SNPs are more promising for successful amplification. In this work, kinship analysis was performed on two skeletons from the Early Middle Ages. The surface contaminants of petrous bones were removed by chemical cleaning and UV irradiation; DNA was isolated through full demineralization and purified in an EZ1 Advanced XL machine. The PowerQuant kit was used to analyze DNA yield and degradation, and on average, 17 ng DNA/g of petrous bone was obtained. Both skeletons were typed in duplicate for STR markers using the Investigator EssplexPlus SE QS kit, and comparison of partial consensus genotypes showed shared allelic variants at most loci amplified, indicating close kinship. After statistical calculation, the full-sibling kinship probability was too low for kinship confirmation, and additional analyses were performed with PCR-MPS using the Precision ID Identity Panel. The HID Ion Chef Instrument was used to prepare the libraries and for templating and the Ion GeneStudio S5 System for sequencing. Analysis of identity SNPs produced full genetic profiles from both skeletons. For combined likelihood ratio (LR) calculation, the product rule was used, combining LR for STRs and LR for SNPs, and a combined LR of 3.3 × 10⁷ (corresponding to a full-sibling probability of 99.999997%) was calculated. Through the SNP PCR-MPS that followed the STR analysis, full-sibling kinship between the ancient skeletons excavated from an early medieval grave was confirmed.

Comparison of DNA preservation between adult and non-adult ancient skeletons

Studies evaluating DNA preservation in non-adults, or comparing preservation in adults and non-adults, are very rare. This study compares the preservation of DNA in the skeletal remains of adults and non-adults. It compares the quality and quantity of DNA recovered from different skeletal elements of adults and non-adults, and from non-adults of different age classes. In addition, the preservation of DNA in males and females is compared. Bone DNA preservation was estimated by measuring nuclear DNA concentration and its degradation, and through STR typing success. The study analyzed 29 adult skeletons and 23 non-adult skeletons from the Ljubljana-Polje archeological site, dating from the seventeenth to nineteenth century, and up to four skeletal elements (petrous bone, femur, calcaneus, and talus) were included. After full demineralization extraction, the PowerQuant System and the PowerPlex ESI 17 Fast System (Promega) were used for qPCR and STR typing, respectively. The results showed that, among the four bone types analyzed, only the petrous bone proved to be a suitable source of DNA for STR typing of non-adult skeletal remains, and DNA yield is even higher than in the adult petrous bone, which can be attributed to the higher DNA degradation observed in the adult petrous bone. In adult skeletons, petrous bones and tali produced high STR amplification success and low DNA yield was observed in adult femurs. The results of this study are applicable for the sampling strategy in routine forensic genetics cases for solving identification cases, including badly preserved non-adult and also adult skeletons.

Direct STR typing from human bones

Identification by STR analysis of bones is time-consuming, mainly due to the lengthy decalcification required and complex DNA extraction process. To streamline this process, we developed a direct STR typing protocol from bone samples. We optimized bone sample amounts using femur and tibia and two commercial PCR kits (Identifiler™ Plus and IDplex Plus kits). Optimally, 100 mg of bone powder in 300 µL PBS buffer was heated at 98 °C for three minutes to produce a supernatant for DNA amplification. IDplex Plus performed better than Identifiler™ Plus in terms of allele recovery and peak height. Fifteen samples of each of seven bone elements (1st distal phalange of hand, capitate, femur, metacarpal 4, patella, talus, and tibia; N = 105) were then subjected to direct STR typing with the optimized protocol, and 94.3% were high partial to full profiles. The performance of the developed protocol was similar for all bone elements. Median peak heights were significantly better in profiles of cancellous bone than compact bone (p = 0.033) and significantly different across the bone elements (p < 0.001). Ten casework samples from various conditions and up to 7-year-PMI were subjected to both direct STR and conventional STR typing. No significant difference in the number of alleles was seen (95% HDI of -13.5 to 5.15). As well as being rapid, convenient, and safe, the protocol could help improve STR typing from bones.

Identification of a Slovenian prewar elite couple killed in the Second World War

Genetic identification of a Slovenian prewar elite couple killed in 1944 was performed by typing autosomal and Y-chromosomal STRs, and phenotypic HIrisPlex SNPs for hair and eye color prediction were analyzed for the female skeleton using next-generation sequencing (NGS) technology. The clandestine grave containing the couple's skeletal remains was found in 2015 and only the partial remains were found. Living distant relatives could be found only for the male victim. Because of a lack of comparative reference samples, it was not possible to identify the female victim through autosomal and mitochondrial DNA typing. However, the possibility of comparison of eye and hair color with a painting exhibited in the City Museum of Ljubljana by the prominent Slovenian painter Ivana Kobilca existed. Nuclear DNA obtained from the samples was quantified using the PowerQuant System, and then STR typing was carried out with different autosomal and Y-STR kits. From 0.09-9.36 ng DNA/g of powder was obtained from teeth and bones analyzed. Complete autosomal and Y-STR profiles made it possible to identify the male skeleton via comparison with two nephews. For the female victim, predicted eye and hair color was compared to colors on the painting. Kobilca's painting confirms the genetically predicted eye and hair color. After more than seventy years, the skeletal remains of the couple were handed over to their relatives, who buried the victims with dignity in a family grave.

Intra-bone nuclear DNA variability and STR typing success in Second World War 12th thoracic vertebrae

Bones are an important source of DNA for identification in forensic medicine, especially when the remains are skeletonized, which is the case when dealing with victims of the Second World War. Often the amount of bone available for sampling is limited, and therefore it is crucial to sample the bone segment with the highest adequate DNA quantity for identification. Studies performed on all representative skeletal element types of the human body showed that the amount of DNA obtained from different skeletal elements of different body regions varies greatly. When bones from torso were analyzed, thoracic vertebrae outperformed other vertebrae (cervical and lumbar) and, alongside the first ribs, were among the most appropriate bone elements for identification purposes. It was also shown that the quantity of DNA varies significantly within a single bone type. This study focused on exploring intra-bone DNA variability between five parts of 12th thoracic vertebrae (laminae + spinous process, pedicles + transverse processes, and corpus right, left, and middle). The research was based on the theory that the distribution of body weight and consequently bone remodeling, as well as the ratio between cancellous and cortical bone, contribute to different quantities of DNA in different parts of vertebra sampled. The vertebrae were cleaned and cut into five parts, and each part was completely ground to obtain homogenous bone powder. Half a gram of powder from each part was decalcified using a full demineralization extraction method. The DNA was purified in a Biorobot EZ1 machine (Qiagen). DNA quantity and quality were determined using the PowerQuant System (Promega) and autosomal STR typing success using the GlobalFiler Amplification Kit (Applied Biosystems). Thirty-five 12th thoracic vertebrae were sampled from a single Second World War mass grave. The best results with the highest DNA quantity were found in laminae and the spinous process, and among them all vertebrae analyzed yielded full STR profiles except three, where only a few dropouts occurred. The second-ranked bone part was the pedicles and transverse processes. The comparison of DNA degradation in the vertebral segments analyzed does not show statistically significant differences. Considering our research, when only the torso is available for identification, the 12th thoracic vertebra should be collected and the vertebral arch should be sampled for genetic analyses.

Comparison of nuclear DNA yield and STR typing success in Second World War petrous bones and metacarpals III

DNA yield and STR typing success differ among skeletal element types and within individual bones. Consequently, it is necessary to identify the skeletal elements and their intra-skeletal parts that will most likely yield utilizable and informative endogenous DNA for human identification of skeletal remains. The petrous portion of the temporal bone has been shown to be the most suitable skeletal part for sampling archaeological skeletons, and it has also been used successfully in some forensic cases. When all representative bone types were analyzed for three complete Second World War skeletons, metatarsals and metacarpals yielded more DNA than petrous bones (which generated full profiles even if the DNA yield was lower) and, among almost 200 Second World War metatarsals and metacarpals analyzed, metacarpals III were found to be the highest-yielding bones. To further improve the sampling strategy in DNA analysis of aged skeletal remains, a comparison between 26 petrous bones and 30 metacarpals III from Second World War skeletons was made considering intra-bone DNA yield variability. In metacarpals III only epiphyses were sampled, and in petrous bones only the dense part within the otic capsule was used. To exclude the influence of taphonomic issues as much as possible, petrous bones and metacarpals III from a single Second World War mass grave were examined. The difference between petrous bones and metacarpals III was explored by measuring nuclear DNA yield and success of STR typing. After cleaning the samples, full demineralization extraction was used to decalcify 0.5 g of powdered bone. PowerQuant (Promega) was used to determine DNA content and DNA degradation rates, and STR typing was performed using the PowerPlex ESI 17 Fast System (Promega). Metacarpals III produced the same DNA yields and STR typing success as petrous bones with no intra-individual difference observed in concentration of DNA, degradation rate, percentage of successfully amplified alleles, and intensity of electrophoretic signals. Sampling and processing of metacarpal III epiphyses is consequently recommended for genetic identification of highly degraded skeletal remains in routine forensic casework and in buried non-commingled aged skeletal remains whenever metacarpals III are preserved. Metacarpals III are easy to sample and less prone to contamination with modern DNA because no saw is needed for sampling in comparison to the petrous portion of the temporal bone. The data obtained in this study further improve the sampling strategy for genetic identification of Second World War skeletal remains in Slovenia.

Intra-bone nuclear DNA variability and STR typing success in Second World War first ribs

DNA sampling and typing are used for identifying missing persons or war victims. In recent forensic studies, little focus has been placed on determining intra-bone variability within a single skeletal element. When dealing with aged human bones, complete skeletal remains are rarely present. In cases in which only the torso is available, studies have shown that ribs are one of the most appropriate samples, but intra-bone variability has not yet been studied. A higher degree of remodeling was found to contribute to higher DNA yield in the parts of the skeletal element where the most strain is concentrated. This study explores intra-bone variability in proximal, middle, and distal parts of the first human rib by determining the quantity and quality of DNA using the PowerQuant System (Promega) and autosomal STR typing success using the PowerPlex ESI 17 Fast System (Promega). Thirty first ribs from a single Second World War mass grave were sampled. No variation in DNA degradation was observed across the individual rib. The highest quantity of DNA was measured in the proximal part of the first rib, and in all ribs except three, full or almost full genetic profiles were obtained. Thus, when only the torso is present in archaeological or medico-legal cases, first ribs are recommended to be collected if possible, and the proximal or vertebral ends should be sampled for genetic analysis.

Intra-bone nuclear DNA variability in Second World War metatarsal and metacarpal bones

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.

DNA Data Collection and Analysis in the Forensic Arena

Recent scientific advancements in the field of genetics have fostered significant changes for the criminal justice system. Growing National DNA databases, public DNA databases, private direct-to-consumer (DTC) DNA testing companies, and improvements in next-generation sequencing (NGS) have resulted in effective methods for tracking down criminals and exonerating the innocent. While these recently discovered and profound techniques seem to provide benefits, their use in forensic detection has become subject to harsh legal opposition. Ultimately, should law enforcement be permitted to analyze DNA found at crime scenes and DNA that has accumulated in national, public, and private databases to aid in their investigations, or are individuals' privacy rights breached in the process?

High DNA yield from metatarsal and metacarpal bones from Slovenian Second World War skeletal remains

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.

Strategy for STR typing of bones from the Second World War combining CE and NGS technology: A pilot study

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-year-old 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.

Assessment of PowerPlex® Fusion 5C's ability to type degraded DNA

DNA samples collected at crime scenes are often degraded so this research focused on the ability of the Promega PowerPlex® Fusion 5C amplification kit to type both naturally and artificially degraded DNA. DNA was degraded naturally by placing equal volumes of blood on white fabric that was stored either inside, outside in a shaded area, or outside in direct sunlight. Samples were then collected every 10 days for 60 days and the DNA extracted (QIAamp® DNA Investigator). Artificially degraded samples were created by exposing extracted DNA to either UV light or 95 °C heat for varying times. DNA was also degraded artificially by placing blood samples into a 50% bleach solution for varying times prior to extraction. Following sample treatment, standard forensic DNA analysis was performed including quantification (Investigator® Quantiplex) and amplification (PowerPlex® Fusion 5C). Separation and detection were performed on an ABI 3130xl capillary electrophoresis unit and analysis was performed using GeneMapper ID v3.2.1. While the time and shade samples showed similar amounts of degradation, the samples exposed to direct sun showed more degradation. The artificially degraded samples showed more signs of degradation such as reduced overall peak height and peak height imbalance at heterozygous loci. There were also some cases where an allele that was known to be in the profile exhibited total dropout. Although there were some instances of both allelic dropout and heterozygote peak imbalance, PowerPlex® Fusion was able to reliably type degraded DNA as all alleles detected were consistent with the known donor profile. The results show that PowerPlex® Fusion is a robust kit capable of handling forensically challenged samples.