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.     

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.     

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.     

Development and validation of InnoQuant™, a sensitive human DNA quantitation and degradation assessment method for forensic samples using high copy number mobile elements Alu and SVA

There is a constant need in forensic casework laboratories for an improved way to increase the first-pass success rate of forensic samples. The recent advances in mini STR analysis, SNP, and Alu marker systems have now made it possible to analyze highly compromised samples, yet few tools are available that can simultaneously provide an assessment of quantity, inhibition, and degradation in a sample prior to genotyping. Currently there are several different approaches used for fluorescence-based quantification assays which provide a measure of quantity and inhibition. However, a system which can also assess the extent of degradation in a forensic sample will be a useful tool for DNA analysts. Possessing this information prior to genotyping will allow an analyst to more informatively make downstream decisions for the successful typing of a forensic sample without unnecessarily consuming DNA extract. Real-time PCR provides a reliable method for determining the amount and quality of amplifiable DNA in a biological sample.Alu are Short Interspersed Elements (SINE), approximately 300 bp insertions which are distributed throughout the human genome in large copy number. The use of an internal primer to amplify a segment of an Alu element allows for human specificity as well as high sensitivity when compared to a single copy target. The advantage of an Alu system is the presence of a large number (>1000) of fixed insertions in every human genome, which minimizes the individual specific variation possible when using a multi-copy target quantification system. This study utilizes two independent retrotransposon genomic targets to obtain quantification of an 80 bp “short” DNA fragment and a 207 bp “long” DNA fragment in a degraded DNA sample in the multiplex system InnoQuant™. The ratio of the two quantitation values provides a “Degradation Index”, or a qualitative measure of a sample's extent of degradation. The Degradation Index was found to be predictive of the observed loss of STR markers and alleles as degradation increases. Use of a synthetic target as an internal positive control (IPC) provides an additional assessment for the presence of PCR inhibitors in the test sample.In conclusion, a DNA based qualitative/quantitative/inhibition assessment system that accurately predicts the status of a biological sample, will be a valuable tool for deciding which DNA test kit to utilize and how much target DNA to use, when processing compromised forensic samples for DNA testing.     

STR typing of ductal adenocarcinomas of the pancreas and healthy control tissue in 18 individuals

Recently, different work groups have demonstrated that short tandem repeat (STR) typing of various tumor tissues may lead to erroneous results due to tumor microsatellite instability (MSI). This may have considerable implications for genetic profiling of tumor tissue, e.g. in paternity testing or sample individualization. To elucidate whether this is true for ductal adenocarcinomas (DAC) of the pancreas, we genetically investigated tumor and corresponding healthy tissue from 18 patients using a commercially available multiplex PCR kit commonly used in forensic laboratories. STR typing of the samples revealed no differences between tumor and healthy tissue in 17 out of 18 samples. One sample, however, showed an allele expansion at locus D21S11. In heterozygous cases, peak heights varied strongly at different loci, mocking a loss of heterozygozity. This investigation shows that even though tetranucleotide MSI in pancreatic DAC is a rare event, the interpretation of genetic profiles obtained from cancerous samples can be difficult and lead to misinterpretations.     

Effects of storage conditions on forensic examinations of blood samples and bloodstains stored for 20 years

The effects of various storage conditions on blood identification tests, DNA degradation, and short tandem repeat (STR) typing were evaluated. Bloodstains stored at room temperature, 4 °C, −20 °C, and −80 °C for 20 years; blood samples stored at −20 °C and −80 °C for 20 years; and fresh blood samples were analyzed. Leuco-malachite-green testing, anti-human hemoglobin (Hb) testing (using immunochromatography), and tests for hemoglobin-beta (HBB) mRNA were performed as blood identification tests. DNA degradation was evaluated by quantifying the ratios of 305 and 129 base pair (bp) fragments to 41 bp fragments. STR typing was performed using an AmpFlSTR® Identifiler™ Plus PCR Amplification Kit. All samples were positive in leuco-malachite-green staining and anti-human Hb assays. HBB was not detected in blood samples stored at −20 °C or −80 °C, although this marker was detected in all bloodstains. As indicated by the ratio of 129:41 bp and 305:41 bp DNA fragments, DNA from bloodstains stored at room temperature or 4 °C were significantly degraded compared to DNA from all other samples. STR typing analyses revealed that a portion of the loci was undetected in bloodstains stored at room temperature. Therefore, to prevent DNA degradation during long-term storage, it is recommended that bloodstains and blood be stored at below −20 °C. In addition, because bloodstains are more suitable for detection of blood-specific mRNAs than blood sample, it is desirable that blood is stored as bloodstain for this method.     

Increasing the discrimination power of forensic STR testing by employing high-performance mass spectrometry, as illustrated in indigenous South African and Central Asian populations

Short tandem repeat (STR) typing has become the standard technique in forensic methodology for the identification of unknown samples. National DNA databases have been established that contain STR genotypes for intelligence purposes. Due to their success, national DNA databases have been growing so fast that the number of advantageous matches may become a logistic problem for the analysts. This is especially true for partial STR profiles as they display reduced discrimination power. To overcome this drawback, modified versions (so-called mini-STRs) of existing loci were introduced as well as new loci to improve the information content of (partial) STR profiles. We pursue an alternative approach that makes use of nucleotide variation within the amplified STR fragments, which can be discerned by mass spectrometry. We have developed an assay that determines molecular masses from crude STR amplicons which were purified and separated by a liquid chromatographic system directly hyphenated to an electrospray ionization mass spectrometer. We present here new population data of forensically relevant STRs in Khoisan and Yakut populations. These autochthonous groups were selected as they may harbor additional STR alleles that are rare or unobserved in modern humans from cosmopolitan areas, especially for the Khoisan, which are known to represent a very ancient human population. The analysis of the molecular mass of STRs offered a widened spectrum of allele variability escorted by enhanced forensic use. Thus, established STR data derived from fragment size analysis can still be used in casework or in the context of intelligence databasing.     

Real-time forensic DNA analysis at a crime scene using a portable microchip analyzer

An integrated lab-on-a-chip system has been developed and successfully utilized for real-time forensic short tandem repeat (STR) analysis. The microdevice comprises a 160-nL polymerase chain reaction reactor with an on-chip heater and a temperature sensor for thermal cycling, microvalves for fluidic manipulation, a co-injector for sizing standard injection, and a 7-cm-long separation channel for capillary electrophoretic analysis. A 9-plex autosomal STR typing system consisting of amelogenin and eight combined DNA index system (CODIS) core STR loci has been constructed and optimized for this real-time human identification study. Reproducible STR profiles of control DNA samples are obtained in 2 h and 30 min with ≤0.8 bp allele typing accuracy. The minimal amount of DNA required for a complete DNA profile is 100 copies. To critically evaluate the capabilities of our portable microsystem as well as its compatibility with crime scene investigation processes, real-time STR analyses were carried out at a mock crime scene prepared by the Palm Beach County Sheriff's Office (PBSO). Blood stain sample collection, DNA extraction, and STR analyses on the portable microsystem were conducted in the field, and a successful “mock” CODIS hit was generated on the suspect's sample within 6 h. This demonstration of on-site STR analysis establishes the feasibility of real-time DNA typing to identify the contributor of probative biological evidence at a crime scene and for real-time human identification.     

DNA profile of dog feces as evidence to solve a homicide

Dog fecal samples were collected at the crime scene and from the shoes of the suspect to see whether they could be linked. DNA was genotyped using a 145 bp fragment containing a 60 bp hotspot region of the mitochondrial DNA (mtDNA) control region. Once the species origin was identified, sequences were aligned with the 23 canine haplotypes defined, showing that evidence and reference had 100% identity with haplotype 5. The frequency of haplotype 5 and the exclusion power of the reference population were 0.056 and 0.89, respectively. The forensic index showed that it was 20 times more likely that the evidence belonged to the reference dog than to some other unknown animal. The results support that the mtDNA hypervariable region 1 (HV1) is a good alternative for typing in trace or degraded casework samples when the STR panel fails, and demonstrate the utility of domestic animal samples to give additional information to solve human legal cases.     

STRs, mini STRs and SNPs--a comparative study for typing degraded DNA

Short tandem repeat (STR) systems are the most powerful and widely used genetic marker systems in forensic DNA typing. Optimized amplification conditions and PCR reagents in combination with laser fluorescence based detection methods have increased the sensitivity and decreased the detection threshold down to approximately 100 pg. The quality of human DNA from forensic samples can be influenced by environmental factors. These may cause different degrees of degradation which have a negative impact on the amplification process especially of STR systems with large amplicons. Therefore, methods which need only small amplicon sizes to detect DNA markers are a better choice for typing degraded DNA. Here we report investigations on different types of DNA markers and typing methods which should all be applicable for analysing degraded DNA. These are two commercially available mini STR kits and five SNP markers which were analysed with two self established assays, a 5' nuclease assay and a minisequencing (SNaPshot) assay. The investigations comprised sensitivity studies, different types of stain material, as well as intact and degraded DNA. Results indicate that mini STRs are superior to standard STR typing methods, especially for typing old stain material with small amounts of degraded DNA. SNP typing based on the minisequencing (SNaPshot) assay achieved a better success rate in typing aged blood and saliva stains compared to standard STRs and SNP typing using the 5' nuclease assay.     

Assessment of DNA degradation and the genotyping success of highly degraded samples

DNA becomes progressively more fragmented as biological tissue degrades resulting in decreasing ability to gain a complete DNA profile. Successful identification of samples exhibiting very high levels of DNA degradation may be complicated by presenting in minute quantities. The industry standard method for human DNA identification utilising short tandem repeats (STR) may produce partial or no DNA profile with such samples. We report a comparative study of genotyping using STRs, mini-STRs and single nucleotide polymorphisms (SNPs) with template at different levels of degradation in varying amounts. Two methods of assessing quantity and quality of a DNA sample prior to genotyping were investigated. The QIAxcel capillary gel electrophoresis system provided a rapid, cost effective screening method for assessing sample quality. A real-time quantitative PCR (qPCR) assay was able to simultaneously quantify total human DNA, male DNA, DNA degradation and PCR inhibition. The extent of DNA degradation could be assessed with reasonable accuracy to 62.5 pg and genomic targets could be quantified to a lower limit of 15.6 pg. The qPCR assay was able to detect male DNA to a lower limit of 20 pg in a 1:1,000 background of female DNA. By considering the amount of DNA and the degradation ratio of a sample, a general prediction of genotyping success using AmpFlSTR® Profiler Plus®, MiniFiler? kits and SNP analysis can be made. The results indicate mini-STRs and SNP markers are usually more successful in typing degraded samples and in cases of extreme DNA degradation (≤200 bp) and template amounts below 250 pg, mini-STR and SNP analysis yielded significantly more complete profiles and lower match probabilities than corresponding STR profiles.     

Modified DOP-PCR for improved STR typing of degraded DNA from human skeletal remains and bloodstains

Forensic and ancient DNA samples often are damaged and in limited quantity as a result of exposure to harsh environments and the passage of time. Several strategies have been proposed to address the challenges posed by degraded and low copy templates, including a PCR based whole genome amplification method called degenerate oligonucleotide-primed PCR (DOP-PCR). This study assessed the efficacy of four modified versions of the original DOP-PCR primer that retain at least a portion of the 5′ defined sequence and alter the number of bases on the 3′ end. The use of each of the four modified primers resulted in improved STR profiles from environmentally-damaged bloodstains, contemporary human skeletal remains, American Civil War era bone samples, and skeletal remains of WWII soldiers over those obtained by previously described DOP-PCR methods and routine STR typing. Additionally, the modified DOP-PCR procedure allows for a larger volume of DNA extract to be used, reducing the need to concentrate the sample and thus mitigating the effects of concurrent concentration of inhibitors.     

PCR inhibitor removal using the NucleoSpin® DNA Clean-Up XS kit

Forensic evidence samples are collected from an unlimited variety of substrates, which may contain compounds known to inhibit the polymerase chain reaction (PCR). These PCR inhibitors are co-extracted with the DNA sample and can negatively affect the DNA typing results, which can range from partial to complete inhibition of the short tandem repeat (STR) PCR. One potential solution is to remove the PCR inhibitors from the extracts prior to the STR PCR with the NucleoSpin^® DNA Clean-Up XS kit. The kit contains a NucleoSpin^® XS silica column that has a special funnel design of thrust rings along with a very small silica membrane, which allows for sample elution in a small volume that is appropriate for use with current STR typing kits. The NucleoSpin^® DNA Clean-Up XS kit was optimized for the best possible DNA recovery and then evaluated for its ability to remove eight commonly encountered PCR inhibitors including: bile salt, collagen, hematin, humic acid, indigo, melanin, tannic acid and urea. Each of these PCR inhibitors was effectively removed by the NucleoSpin^® DNA Clean-Up XS kit as demonstrated by generating more complete STR profiles from the cleaned up inhibitor samples than from the raw inhibitor samples.     

An evaluation of the RapidHIT® system for reliably genotyping reference samples

Short tandem repeat (STR) typing is used routinely for associating or excluding individuals with biological evidence left at a crime scene. Improvements have been made to reduce the turnaround time and labor involved with profile generation, but there is still some lag time between sample collection and interpretation of results. The RapidHIT^® (IntegenX; Pleasanton, CA, USA) system is an automated instrument that is configured to perform DNA extraction, bead-based DNA normalization, amplification, electrophoresis of PCR amplicons, and data analysis of five reference swabs simultaneously. The RapidHIT system provided reliable STR profiles from reference buccal swabs in approximately 90 min with nominal “hands-on” sample loading time with no evidence of contamination between samples. The overall success rate of typing buccal swabs was comparable to standard typing systems. In the event of a failed run due to instrument failure, the swab can be removed from the cartridge and reanalyzed in the RapidHIT system or with standard STR genotyping workflows.     

Short tandem repeat typing on the 454 platform: Strategies and considerations for targeted sequencing of common forensic markers

To investigate the feasibility of next generation sequencing technology (NGS) for the multiplex detection and sequence production of short tandem repeats (STRs) from degraded and low DNA quantity samples, standard polymerase chain reaction amplification methods were used to enrich for commonly employed STR markers. Samples were amplified with two multiplexing strategies: a multiplex containing thirteen miniSTR markers and a series of multiplexes containing four miniSTR markers each. Each sample multiplex was barcoded with a sample-specific multiplex identifier for subsequent parallel tagged sequencing on the GS Junior System (454 Life Sciences, a Roche company, Branford, CT). Sequencing results from over fifty DNA extracts representing both pristine samples and low-quality evidentiary specimens reflected known genotypes and were consistent across multiple extracts and/or amplifications of the same sample. Furthermore, the NGS data revealed sequence information not available with standard capillary electrophoresis-based detection alone. For the population samples tested, a total of 152 single nucleotide polymorphisms or insertions/deletions were identified in over 935 recovered alleles, averaging one polymorphism for every six recovered alleles. For three of the loci, the sequence information doubled the number of alleles detected via traditional STR typing by fragment analysis. In addition, twenty-eight of these variants were only seen once within our dataset, highlighting the potential for discrimination among individuals. These additional data are likely to be particularly valuable in missing persons and disaster victim identification cases for which only partial profiles may be recovered and/or only distant kin are available as references. And, considering the opportunity to target only small amplicons with NGS, this type of STR typing will allow for greater information recovery from challenging casework samples. While our results highlight the potential of new technologies for recovering discriminatory genetic information from evidentiary specimens, our data also reveal the complexities of NGS-based STR typing, both in terms of the laboratory assays themselves as well as the downstream data processing and analysis.     

Automated extraction of DNA from biological stains on fabric from crime cases. A comparison of a manual and three automated methods

The presence of PCR inhibitors in extracted DNA may interfere with the subsequent quantification and short tandem repeat (STR) reactions used in forensic genetic DNA typing. DNA extraction from fabric for forensic genetic purposes may be challenging due to the occasional presence of PCR inhibitors that may be co-extracted with the DNA. Using 120 forensic trace evidence samples consisting of various types of fabric, we compared three automated DNA extraction methods based on magnetic beads (PrepFiler Express Forensic DNA Extraction Kit on an AutoMate Express, QIAsyphony DNA Investigator kit either with the sample pre-treatment recommended by Qiagen or an in-house optimized sample pre-treatment on a QIAsymphony SP) and one manual method (Chelex) with the aim of reducing the amount of PCR inhibitors in the DNA extracts and increasing the proportion of reportable STR-profiles. A total of 480 samples were processed. The highest DNA recovery was obtained with the PrepFiler Express kit on an AutoMate Express while the lowest DNA recovery was obtained using a QIAsymphony SP with the sample pre-treatment recommended by Qiagen. Extraction using a QIAsymphony SP with the sample pre-treatment recommended by Qiagen resulted in the lowest percentage of PCR inhibition (0%) while extraction using manual Chelex resulted in the highest percentage of PCR inhibition (51%). The largest number of reportable STR-profiles was obtained with DNA from samples extracted with the PrepFiler Express kit (75%) while the lowest number was obtained with DNA from samples extracted using a QIAsymphony SP with the sample pre-treatment recommended by Qiagen (41%).     

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.     

Kinship analysis of 5th- to 6th-century skeletons of Romanized indigenous people from the Bled–Pristava archaeological site

The familial relationship between skeletons buried together in a shared grave is important for understanding the burial practices of past human populations. Four skeletons were excavated from the Late Antiquity part of the Bled–Pristava burial site in Slovenia, dated to the 5th to 6th century. They were anthropologically characterized as two adults (a middle-aged man and a young woman) and two non-adults (of unknown sex). Based on stratigraphy, the skeletons were considered to be buried simultaneously in one grave. Our aim was to determine whether the skeletons were related. Petrous bones and teeth were used for genetic analysis. Specific precautions were followed to prevent contamination of ancient DNA with contemporary DNA, and an elimination database was established. Bone powder was obtained using a MillMix tissue homogenizer. Prior to extracting the DNA using Biorobot EZ1, 0.5 g of powder was decalcified. The PowerQuant System was used for quantification, various autosomal kits for autosomal short tandem repeat (STR) typing, and the PowerPlex Y23 kit for Y-STR typing. All analyses were performed in duplicate. Up to 28 ng DNA/g of powder was extracted from the samples analyzed. Almost full autosomal STR profiles obtained from all four skeletons and almost full Y-STR haplotypes obtained from two male skeletons were compared, and the possibility of a familial relationship was evaluated. No amplification was obtained in the negative controls, and no match was found in the elimination database. Autosomal STR statistical calculations confirmed that the adult male was the father of two non-adult individuals and one young adult individual from the grave. The relationship between the males (father and son) was additionally confirmed by an identical Y-STR haplotype that belonged to the E1b1b haplogroup, and a combined likelihood ratio for autosomal and Y-STRs was calculated. Kinship analysis confirmed with high confidence (kinship probability greater than 99.9% was calculated for all three children) that all four skeletons belonged to the same family (a father, two daughters, and a son). Through genetic analysis, the burial of members of the same family in a shared grave was confirmed as a burial practice of the population living in the Bled area in Late Antiquity.     

Typing short amplicon binary polymorphisms: supplementary SNP and Indel genetic information in the analysis of highly degraded skeletal remains

Two sets of short amplicon binary markers (SABs): 50 single nucleotide polymorphisms (SNPs) and 38 insertion/deletion polymorphisms (Indels) were used to genotype bones of 35 years "post-mortem". Typing results of these binary markers were compared with those obtained for standard commercial STR and mini-STR DNA typing kits. We observed SAB marker performance to be better compared with conventional STR and mini-STR genotyping in degraded bone sample analysis. Furthermore, additional genetic information provided by these 88 binary markers, 50 SNPs and 38 Indels, combined with classical markers gave very high discrimination power even in severely degraded specimens, with all tested bone samples showing Random Match Probabilities (RMPs) higher than 1019. Missing person and disaster victim identification by kinship analysis is considerably strengthened by the addition of SAB markers since they can be successfully typed on degraded bone samples while adding considerable extra genetic data when poor or incomplete information is available from conventional forensic markers for the analysis of family pedigrees.     

Mixture interpretation: Experimental and simulated reevaluation of qualitative analysis

We present here analytical data using the 15 STR typing (Identifiler) kit regarding heterozygote balance in experimental DNA samples including one or two persons. Surprisingly, the allelic imbalance was observed even in samples consisting of only one person but adequate DNA for the standard protocol. The variance of heterozygote balance was more expanded in two-person mixtures than in one-person samples. Therefore, it is not suitable to use allelic peak heights/areas for estimating the genotypes of the contributors such as the quantitative analysis. We also reevaluated the effectiveness of qualitative analysis by simulation, i.e. consideration of the probability of all possible genotype combinations from the typing results of a mixed DNA sample. As demonstrated, the qualitative analysis using 15 STR loci is still extremely effective even in a mixture from two or three individuals.