Comparison of DNA yield after long-term storage of Second World War bone samples

Sample storage is of paramount importance in forensic genetics laboratories since only optimal storage enables successful recovery of DNA from old bones that contain very low amount of severely degraded DNA. When identification of missing persons from skeletal remains is completed, bone sample is routinely stored at -20 °C for long-term storage for retesting in future, if necessary. After molecular genetic analyses of Slovenian Second World War (WWII) victims, small fragments of femurs were stored at -20 °C. Reduction in DNA recovery has been observed in frozen liquid DNA extracts by some authors and the goal of our study was to explore how freezing of bone samples affects the preservation of DNA. To achieve this goal, the difference in DNA yield in extracts obtained from WWII bones analyzed in 2009 (data from published paper) and DNA yield in extracts obtained from the same bones (piece sampled next to the one used in 2009) taken out of the freezer after long-term storage on -20 °C for 10 years was examined, using the same extraction method and the same quantification kit. Up to 100 ng DNA/g of bone powder was obtained from 57 WWII femurs and up to 31 ng DNA/g of bone powder from the same femurs investigated after long-term storage in this study. 0,5 g of bone powder was decalcified using full demineralization extraction method. The DNA was purified in a Biorobot EZ1 device (Qiagen) and DNA quantity determined with the Human Quantifiler kit (TFS). Statistical analysis showed significant difference in DNA yield in extracts obtained from WWII bones in 2009 and extracts obtained from the same bones stored at -20 °C after 10 years. As reported for frozen liquid DNA extracts, reduction in recovery of DNA was confirmed for frozen bone samples as well.     

应用磁珠法提取陈旧骨骼DNA

目的探讨采用磁珠法提取陈旧骨骼DNA的可行性。方法取经土埋或室外暴露下存放1~5年不等的10根长骨,经水洗、刮净,钻取骨密质骨粉3g,应用EQ1000磁珠试剂盒提取DNA,经复合扩增,ABI 3130XL基因分析仪电泳分离,进行STR分型检测。结果 10根长骨均获得完整的STR分型,电泳图谱基线干净,除个别大片段基因座外,等位基因荧光信号分布均衡性较好。结论采用磁珠法提取陈旧骨骼的DNA,能满足分型要求,可在实际检案中选用。     

Forensic medical expertise on burned bone remains

The series of 1138 cadaveric humerus and femurs of people of both sexes who died at the age of 17-91 years and 468 animal bones (cow, pig, sheep) was studied. Bones were burned (experimentally) at various temperature values and in different conditions. Investigations were carried out using osteometric, microscopic, microroentgenographic and mathematical methods. Species identification as well as sex and age determination using burned bone remains are possible regardless of the level of their burning. Regression equations to calculate victim's stature according to fragments of burned bones were received.     

Next generation sequencing technology in Second World War victim identification

The killings during the Second World War (WWII), with nearly 100,000 victims, is one of the greatest losses of life in Slovenia’s modern history and most of the victims are still buried in hidden mass graves and remain unidentified. Identity, ancestry, and phenotypic SNPs, as well as STR markers are already used for solving various cases with Next Generation Sequencing (NGS) technology. In this study, the Precision ID GlobalFiler NGS STR panel was used to identify the WWII victim that could not be identified with capillary electrophoresis (CE) analyses because limited statistical support was obtained after amplification of autosomal STRs using CE STR kits. Bones and teeth were analysed and compared to family references (nephew and niece on paternal line). Prior to DNA isolation 0.5 g of powder was decalcified. The DNA was purified in a Biorobot EZ1 device. The nuclear DNA of the samples was quantified with the PowerQuant kit. Because the recommended posterior probability (PP) of 99.9% was followed with the goal of high confidence of correct identification, the NGS STR Panel was used, and after the analysis of additional STR loci the statistical calculation showed a PP of 99.99986%, showing that a large enough number of genetic markers were analysed when identifying the skeletal remains of the aunt. PP value endorsed the hypothesis that the tooth and bone samples were from individual related to the family references rather than from unrelated individual. In presented case, NGS technology proved to be a powerful tool for increasing the number of autosomal STRs needed for identification of WWII victims when linear markers cannot be used for comparison and only distant relatives are available for analyses.     

A simple and efficient method for extracting DNA from old and burned bone

It has been a challenge to extract DNA from bones previously soaked in water, burned, or buried for a long time, due to the reduced quality and quantity of DNA in the bone samples. The dramatic degradation of the DNA and the presence of PCR inhibitors in the collagen significantly complicate the process of DNA identification in dated and charred bones. In this article, we present a novel strategy to obtain DNA from bones based on the use of cetyltrimethylammonium bromide (CTAB) lysis buffer and isoamyl alcohol-chloroform extraction with subsequent DNA purification using the DNA IQ System, or alternatively the QIAquick system. When applied to bones soaked, burned or buried for up to nine years, this method increases the purity and yield of DNA with respect to the traditional phenol-chloroform method and significantly improves multiplex STR genotyping using fluorescence-based methods. The results of this research will assist forensic scientists in the identification of DNA from victims whose bodies underwent significant trauma or burning, precluding the utilization of traditional forensic DNA identification techniques.     

Determination of DNA yield rates in six different skeletal elements in ancient bones

Current sampling strategy for laboratories typing bones for human identification include samples obtained from femur, tooth and temporal bone. Latest studies suggest that the small bones of the hands and feet were very similar or even better in DNA yield. These bones can be easily sampled with a disposable scalpel and thus reduce potential DNA contamination. The aim of our study was to determine the suitability of metatarsals, metacarpals and phalanges for genetic identification. 48 bone samples from 8 different skeletons (six from 18^th century and two from 3rd century) were obtained from 5 archaeological sites in Slovenia. In each skeleton, 6 different skeletal elements were sampled (temporal bone, molar, femur, metacarpal bone, metatarsal bone and proximal phalanx of the hand), and strict precautions followed to prevent contamination. Half of gram of bone powder was decalcified using full demineralization extraction method. The DNA was purified in a Biorobot EZ1 (Qiagen), DNA content determined with the PowerQuant kit (Promega), and autosomal STR typing performed with the Investigator ESSplex Plus kit (Qiagen). Up to 8.75 ng DNA/g of powder was obtained from samples analyzed. The highest yields were detected in temporal bone and the lowest in femur. The success rate of STR typing was evaluated according to the number of successfully typed loci and a strong correlation between the success rate of STR typing and the amount of extracted DNA was confirmed. For all eight skeletons full consensus genetic profiles were determined from skeletal elements analyzed. Our findings suggest it would be suitable to include metatarsal and metacarpal bones in sampling strategy for human identification although further research is needed to substantiate the findings of this study.     

利用AutoMate Express~(TM)系统提取陈旧性骨骼DNA

目的建立利用AutoMate Express~(TM)系统提取陈旧性骨骼DNA的方法。方法将骨骼用冷冻研磨机研磨成骨粉,经AutoMate Express~(TM)系统提取后,用Identifiler~Plus、MiniFiler~(TM)试剂盒扩增分型。结果10例保存在不同环境中、死亡时间在10~20年的骨骼样本利用AutoMate Express~(TM)系统3 h内完成DNA提取,有8例获得完整STR分型。结论 AutoMate Express~(TM)系统能快速、高效地提取陈旧性骨骼DNA,可应用于法医实际案件检验。     

Discrimination between human and animal DNA: application of a duplex polymerase chain reaction to forensic identification

Identification of a report's species is one of the basic analyses in forensic laboratories. The authors report the case of 6 bone fragments recovered in a wooded area, which were not attributable to 1 animal species on the basis of morphologic examination. The aim of this study was to develop a duplex polymerase chain reaction (PCR) to discriminate human and animal origin of bone fragments. The method is based on the PCR amplification of cytochrome b and a 16S ribosomal mitochondrial DNA fragment, which has never been tested up to now. Our protocol combines a single-round PCR with direct visualization of amplicons in agarose gel, without sequencing analysis of the PCR products. The presence of a single band (359 bp) indicates a nonhuman origin of the sample, whereas 2 bands (157 and 359 bp) indicate a human biologic sample.This method revealed to be useful for forensic purposes because the 16S ribosomal mitochondrial DNA is a small human-specific fragment that is easily amplifiable even with degraded DNA from biologic materials such as old bones.     

Explanation of nonspecific serologic reactions in decomposed bone tissue

Bone fragments were stored in water for 2 years at room temperature and investigated serologically using the following methods: Absorption-elution, extraction of blood group substances and immunohistochemistry (PAP). All 3 methods gave essentially specific results for fresh bone tissue but with putrid bone tissue unspecific reactions were found predominantly with the absorption-elution and PAP techniques. In contrast, more specific reactions were obtained from the extracts although they were much weaker. From this it can be concluded that pure physical binding plays a substantial role in the unspecific reaction between antibodies and bone material. It is suggested that the relevant physical properties are altered by putrification.     

Application of mtDNA sequence analysis in forensic casework for the identification of human remains

In four forensic cases of unidentified skeletal remains investigated in the last year, we were able to attach three to missing persons. In one case we could show that the discovered bone sample did not fit to a missing child. The method for mitochondrial DNA analysis for the routine identification of skeletal remains was established in our institute by typing bone samples of defined age obtained from Frankfurt's cemetery. Reproducible results were obtained for bones up to 75 years old. For analysis the bone samples were pulverised to fine powder, decalcified and DNA was extracted. From the DNA we amplified a 404-bp fragment from HV-1 and a 379-bp fragment from HV-2 of the mtDNA control region. After sequencing of the PCR products, the results were compared to the Anderson reference sequence and to putative maternal relatives.     

A review of the current understanding of burned bone as a source of DNA for human identification

Identification of incinerated human remains may rely on genetic analysis of burned bone which can prove far more challenging than fresh tissues. Severe thermal insult results in the destruction or denaturation of DNA in soft tissues, however genetic material may be preserved in the skeletal tissues. Considerations for DNA retrieval from these samples include low levels of exogenous DNA, the dense, mineralised nature of bone, and the presence of contamination, and qPCR inhibitors. This review collates current knowledge in three areas relating to optimising DNA recovery from burned bone: 1) impact of burning on bone and subsequent effects on sample collection, 2) difficulties of preparing burned samples for DNA extraction, and 3) protocols for bone decalcification and DNA extraction. Bone decalcification and various DNA extraction protocols have been tested and optimised for ancient bone, suggesting that prolonged EDTA (Ethylenediaminetetraacetic acid) demineralisation followed by solid-phased silica-based extraction techniques provide the greatest DNA yield. However, there is significantly less literature exploring the optimal protocol for incinerated bones. Although burned bone, like ancient and diagenetic bone, can be considered “low-copy”, the taphonomic processes occurring are likely different. As techniques developed for ancient samples are tailored to deal with bone that has been altered in a particular way, it is important to understand if burned bone undergoes similar or different changes. Currently the effects of burning on bone and the DNA within it is not fully understood. Future research should focus on increasing our understanding of the effects of heat on bone and on comparing the outcome of various DNA extraction protocols for these tissues.     

Optimal storage conditions for highly dilute DNA samples: a role for trehalose as a preserving agent

DNA extraction from trace samples or noninvasively collected samples often results in the recovery of low concentration solutions of DNA that are prone to DNA degradation or other loss. Because of the difficulty in obtaining such samples, and their potentially high value in wildlife and forensic studies, it is critical that optimal methods are employed for their long-term storage. We assessed the amplification yield of samples kept under different storage conditions with the addition of potential preserving agents. We stored dilutions of known concentration human placental DNA, and gorilla fecal DNA, under four conditions (+4 degrees C, -20 degrees C, -80 degrees C, dry at room temperature), and with three additives (Tris EDTA (TE) buffer, Hind III digested Lambda DNA, trehalose). The effectiveness of the treatment methods was tested at regular intervals using qPCR to assess the quantity of amplifiable DNA, and a PCR assay of a larger 757 bp fragment to evaluate the quality of that remaining DNA. The highest quantity of DNA remained in samples stored at -80 degrees C, regardless of storage additives, and those dried at room temperature in the presence of trehalose. Surprisingly, DNA quality was best preserved in the presence of trehalose, either dried or at -80 degrees C; significant quality loss occurred with -20 degrees C and +4 degrees C storage.     

A Powder-free DNA Extraction Workflow for Skeletal Samples

The processing of skeletal material poses several challenges for forensic laboratories. Current methods can be laborious, time-consuming, require dedicated equipment, and are vulnerable to contamination. In this study, various sample mass (1 × 50 mg, 3 × 50 mg, and 1 × 150 mg chip(s)) and incubation times (2, 4, and 16 h) were tested using the PrepFiler^® BTA™ Forensic DNA Extraction Kit to digest whole bone chips in lieu of powdering. The most effective method was then applied to bones and tooth fragments collected from contemporary human cadavers exposed to various environmental conditions using an automated platform. Over a third of the samples tested generated full DNA profiles without having to powder the bone/tooth fragment or further alter the manufacturer's protocol. However, for most samples resulting in incomplete STR profiles due to low amounts of DNA, slightly better results were achieved with powdered tissue. Overall, this work demonstrates the potential use of a faster, nonpowdering DNA extraction method for processing skeletal samples as an effective first-pass screening tool.     

Mitochondrial DNA sequencing of human hair shafts stored for long time

Mitochondrial DNA (mtDNA) sequencing is commonly used for forensic genetic identification of relation and personality identification based on analysis of tooth and skeletal rudiments. We demonstrated the possibility of DNA extraction and subsequent enzymatic amplification of fragments of a hypervariable segment I of mtDNA control region from hair shafts after long storage (up to 75 years). Shed hairs are the most common biological material evidence in forensic investigations. Low content of DNA and its possible degradation in hair shafts without bulbs may cause artifacts in polymerase chain reaction. However comparative analysis of amplified nucleotide sequences of amplified fragments from hair stored for 75 years was identical to the sequence from hairs cut immediately before experiment. This indicates high quality of the resultant matrices, stability of results, and hence, the possibility of using DNA extracted from hair shafts without bulbs stored for a long time for expert genetic analysis. Theoretical and methodological prospects of using mtDNA polymorphism analysis for forensic expert evaluations are discussed.     

Towards molecular autopsies: Development of a FFPE tissue DNA extraction workflow

Sudden unexpected death (SUD) is a devastating event and forms a substantial proportion of the cases investigated at forensic mortuaries each year. Despite post-mortem investigations, the cause of death may remain undetermined. There is potential for these unresolved cases to benefit from retrospective molecular autopsies for investigation into genetic mutations which may have contributed towards death. Often, formalin fixed paraffin embedded tissues (FFPET) are the only archival sources of DNA available for retrospective analyses. However, extracting usable DNA from FFPET is challenging as current methods yield poor quality and quantity DNA. Thus, this study aimed to optimise DNA recovery from FFPET by investigating several variables within the DNA extraction workflow, including the selection of tissue type, number and thickness of tissue sections, deparaffinisation method, and DNA extraction kit. The quantity and quality of DNA recovered were assessed using spectrophotometry, real time PCR, digital capillary electrophoresis and DNA profiling. This study was the first to implement a nuclei quantification using microscopy to guide the selection of the best tissue type to use for DNA analysis. The use of a greater number of thinner tissue sections (100 sections, each 1 μm) significantly improved DNA concentration, purity and fragment length. Additionally, the combination of Deparaffinization Solution with the QIAamp® DNA FFPE Tissue Kit proved most favourable with a median DNA yield of 320 ng and 55% of DNA fragments greater than 400 bp. Isolated DNA was of single source, indicating no contamination in the workflow, and FFPET blocks that were stored for up to 3.5 years did not significantly affect DNA degradation (p = 0.1764). These results are especially informative for designing library preparation and sequencing workflows for determining cause of death in unresolved SUD cases.     

人骨骼及牙齿DNA提取方法的比较和优化

目的人骨骼和牙齿DNA提取方法的比较和优化。方法收集18份不同个体的长骨、30颗磨牙和同一个体2根股骨、8颗磨牙。利用TissueLyser-Ⅱ组织破碎仪和PreFiler Express BTA^TM法医DNA提取试剂盒（BTA法）,应用Automate Express^TM自动化法医DNA提取系统提取DNA,进行STR分型,与脱钙法进行比较,并进行实验条件优化。结果用TissueLyser-Ⅱ结合BTA法,约2.5h即可完成骨骼和牙齿的DNA提取,分型成功率分别为94.4%和96.7%。与脱钙法比较,两种方法获得DNA质量浓度和检出率比较接近（P〈0.05）,但BTA法在操作过程方面更具优势。最佳样本量为100mg,消化时间为2h。结论采用TissueLyser-Ⅱ组织破碎仪结合BTA法对骨骼和牙齿进行DNA提取和分型检验,能满足实际检案的要求,可在法医学实践中选择使用。     

Interindividual variability, pathological changes and decomposition as an impediment to the morphological determination of human specificity of bone finds

Playing children discovered several teeth close to the wall surrounding a village church. A subsequent police search yielded further teeth, three neurocranial fragments, a metacarpal bone and the fragment of a long tubular bone. The circumstances along with the results of the investigation and the morphological findings suggested historical bones from a former graveyard. However, a large fragment of bone shaft from a long bone could not definitely be classified as being of human origin. The tibia of a deer was amongst the possibilities considered. Comparative tests run at the Institute of Veterinary Anatomy of the University of Giessen in addition to histological examinations, however, ultimately established the human specificity. Interindividual variability and decomoositional changes were determined as causes for the conspicuous macroscopic and microscopic findings for the tibia fragment. Pathological changes could not be demonstrated.     

Validation of the InnoXtract™ DNA extraction method for bone,teeth, and rootless hair

Forensic casework samples often include human hairs, teeth, and bones. Hairs with roots are routinely processed for DNA analysis, while rootless hairs are either not tested or processed using mitochondrial DNA. Bones and teeth are submitted for human remains identifications for missing persons and mass disaster cases. DNA extraction from these low templates and degraded samples is challenging. The new InnoXtract DNA extraction method utilizes magnetic beads that are optimized to bind small DNA fragments, as small as 100 base pairs, to purify high-yield DNA from compromised samples. This validation study evaluates InnoXtract's ability to obtain amplifiable DNA from samples such as rootless hairs and skeletal remains. Studies performed include sensitivity, stability, repeatability, reproducibility, non-probative samples, and comparison to standard organic extractions. Sensitivity studies demonstrate average yield recoveries ranging from 53% to 100% and 73% to 85% for the InnoXtract hair and bone methods, respectively. Studies demonstrate consistent results across a range of sample types, such as insulted and un-insulted bone and teeth, as well as hair shafts from donors of various ages, gender, race, and hair characteristics. The InnoXtract bone method outperformed organic extraction. The method was successfully automated on a MagMAX™ Express-96, with recoveries over 70% relative to the manual version. InnoXtract has the potential as an automated high-throughput, high-yield bone extraction method with 6 h of total extraction time for up to 96 samples. The validation study results demonstrate that the InnoXtract kits produce high-yield and high-quality DNA from compromised bone, teeth, and hair shaft samples.     

A Concentrated Hydrochloric Acid-based Method for Complete Recovery of DNA from Bone

The successful extraction of DNA from historical or ancient animal bone is important for the analysis of discriminating genetic markers. Methods used currently rely on the digestion of bone with EDTA and proteinase K, followed by purification with phenol/chloroform and silica bed binding. We have developed a simple concentrated hydrochloric acid-based method that precludes the use of phenol/chloroform purification and can lead to a several-fold increase in DNA yield when compared to other commonly used methods. Concentrated hydrochloric acid was shown to dissolve most of the undigested bone and allowed the efficient recovery of DNA fragments <100 bases in length. This method should prove useful for the recovery of DNAs from highly degraded animal bone, such as that found in historical or ancient samples.     

The Successful Recovery of Low Copy Number and Degraded DNA from Bones Exposed to Seawater Suitable for Generating a DNA STR Profile

A universal method allowing for DNA profiling from bones exposed to seawater has not been reported yet. This study refers on the identification of a body immersed in seawater for 8 months. The biological material for identification was the mandibular body, usually characterized by low success rates of DNA analysis. Initially, two extraction protocols were performed with negative results: one used for bones immersed in fresh water and a silica‐column procedure. A third protocol was performed, which combined the extraction of a higher amount of bone powder, the use of multi‐silica‐based extraction columns followed by a concentration step. This protocol allowed to obtain low copy number DNA and to generate a 12‐loci STR profile by combining conventional STR typing and mini‐STR technologies. This protocol could be suitable when human bones have been exposed to severe environmental conditions, and the available nuclear DNA is highly degraded and in low copy number.