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

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

A new SNP assay for identification of highly degraded human DNA

There is growing evidence that the histone-DNA complexes found in nucleosomes offer protection from DNA degradation processes, including apoptotic events in addition to bacterial and environmental degradation. We sought to locate human nucleosome regions and build a catalogue of SNPs sited near the middle of these genomic segments that could be combined into a single PCR multiplex specifically for use with extremely degraded human genomic DNA samples. Using recently optimized bio-informatics tools for the reliable identification of nucleosome sites based on sequence motifs and their positions relative to known promoters, 1395 candidate loci were collected to construct an 18-plex single base extension assay. Genotyping performance of the nucleosome SNPs was tested using artificially degraded DNA and 24 casework samples where the likely state of degradation of DNA was established by comparison to profile completeness in four other forensic assays: a standard 15-plex STR identification test, a miniaturized STR multiplex and two autosomal SNP multiplexes. The nucleosome SNP assay gave genotyping success rates 6% higher than the best existing forensic SNP assay: the SNPforID Auto-2 29-plex and significantly higher than the mini-STR assay. The nucleosome SNPs we located and combined therefore provide a new type of marker set that can be used to supplement existing approaches when the analysed DNA is likely to be extremely degraded and may fail to give sufficient STR genotypes for a reliable identification.     

Autosomal SNP typing of forensic samples with the GenPlex™ HID System: Results of a collaborative study

The GenPlex™ HID System (Applied Biosystems – AB) offers typing of 48 of the 52 SNPforID SNPs and amelogenin. Previous studies have shown a high reproducibility of the GenPlex™ HID System using 250–500 pg DNA of good quality. An international exercise was performed by 14 laboratories (9 in Europe and 5 in the US) in order to test the robustness and reliability of the GenPlex™ HID System on forensic samples. Three samples with partly degraded DNA and 10 samples with low amounts of DNA were analyzed in duplicates using various amounts of DNA. In order to compare the performance of the GenPlex™ HID System with the most commonly used STR kits, 500 pg of partly degraded DNA from three samples was typed by the laboratories using one or more STR kits. The median SNP typing success rate was 92.3% with 500 pg of partly degraded DNA. Three of the fourteen laboratories counted for more than two thirds of the locus dropouts. The median percentage of discrepant results was 0.2% with 500 pg degraded DNA. An increasing percentage of locus dropouts and discrepant results were observed when lower amounts of DNA were used. Different success rates were observed for the various SNPs. The rs763869 SNP was the least successful. With the exception of the MiniFiler™ kit (AB), GenPlex™ HID performed better than five other tested STR kits. When partly degraded DNA was analyzed, GenPlex™ HID showed a very low mean mach probability, while all STR kits except MiniFiler™ had very limited discriminatory power.     

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

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

Performance of a next generation sequencing SNP assay on degraded DNA

Forensic DNA casework samples are often of insufficient quantity or quality to generate full profiles by conventional DNA typing methods. Polymerase chain reaction (PCR) amplification of short tandem repeat (STR) loci is inherently limited in samples containing degraded DNA, as the cumulative size of repeat regions, primer binding regions, and flanking sequence is necessarily larger than the PCR template. Additionally, traditional capillary electrophoresis (CE) assay design further inherently limits shortening amplicons because the markers must be separated by size. Non-traditional markers, such as single nucleotide polymorphisms (SNPs) and insertion deletion polymorphisms (InDels), may yield more information from challenging samples due to their smaller amplicon size. In this study, the performance of a next generation sequencing (NGS) SNP assay and CE-based STR, mini-STR, and InDel assays was evaluated with a series of fragmented, size-selected samples. Information obtained from the NGS SNP assay exhibited higher overall inverse random match probability (1/RMP) values compared to the CE-based typing assays, with particular benefit for fragment sizes ≤150 base pairs (bp). The InDel, mini-STR, and NGS SNP assays all had similar percentages of loci with reportable alleles at this level of degradation; however, the relatively fewer number of loci in the InDel and mini-STR assays results in the NGS SNP assay having at least nine orders of magnitude higher 1/RMP values. In addition, the NGS SNP assay and three CE-based assays (two STR and one InDel assay) were tested using a dilution series consisting of 0.5 ng, 0.1 ng, and 0.05 ng non-degraded DNA. All tested assays showed similar percentages of loci with reportable alleles at these levels of input DNA; however, due to the larger number of loci, the NGS SNP assay and the larger of the two tested CE-based STR assays both resulted in considerably higher 1/RMP values than the other assays. These results indicate the potential advantage of NGS SNP assays for forensic analysis of degraded DNA samples.     

Screening for single nucleotide polymorphisms in highly degraded DNA by using the amplified fragment length polymorphism technique

Short tandem repeat (STR) analysis is generally used for human identification of forensic samples; however, standard STR analysis sometimes fails to generate full profiles since DNA is frequently degraded by various environmental factors. Recently, single nucleotide polymorphism (SNP) analysis has attracted attention for human identification since the shorter amplicons are better suited for degraded samples. Though various SNP loci are used for analysis of degraded samples, it is unclear which ones are more appropriate. To identify SNPs that were resistant to degradation, we artificially degraded DNA obtained from the buccal swabs of six volunteers and the K562 cell line by heat treatment. Subsequently, the amplified fragment length polymorphism (AFLP) technique was used for SNP screening. We focused on the AFLP bands detected in both the heat-treated and untreated samples, and DNA extracted from these bands was directly sequenced. DNA degradation increased as the duration of heat treatment increased, and no STR profiles could be generated after 6 h of heat treatment. When the AFLP band patterns were compared between 6 h heat-treated and untreated samples, eight common bands were detected. The sequences of the DNA fragments of these common bands had higher adenine-thymine (A-T) content and included 17 SNPs. The SNPs detected in the heat-treated and untreated samples were considered to be resistant to degradation. Although there was a little information available in databases regarding the nine SNPs identified in this study, this study shows that some of these SNPs might be useful for human identification of extremely degraded DNA.     

Pigment phenotype and biogeographical ancestry from ancient skeletal remains: inferences from multiplexed autosomal SNP analysis

In the present study, a multiplexed genotyping assay for ten single nucleotide polymorphisms (SNPs) located within six pigmentation candidate genes was developed on modern biological samples and applied to DNA retrieved from 25 archeological human remains from southern central Siberia dating from the Bronze and Iron Ages. SNP genotyping was successful for the majority of ancient samples and revealed that most probably had typical European pigment features, i.e., blue or green eye color, light hair color and skin type, and were likely of European individual ancestry. To our knowledge, this study reports for the first time the multiplexed typing of autosomal SNPs on aged and degraded DNA. By providing valuable information on pigment traits of an individual and allowing individual biogeographical ancestry estimation, autosomal SNP typing can improve ancient DNA studies and aid human identification in some forensic casework situations when used to complement conventional molecular markers.     

Autosomal SNPs in different forensic applications

The aim of this work was to test a 52 SNP-plex in our laboratory in order to apply it in casework cases, namely in kinship involving relatives of the true father leading to low Parentage Index (PI) values, and in unusual cases such as paraffin-embedded tissue samples or in other cases involving severely degraded samples related to some identification cases. For this, a standard DNA was used, artificially degraded by digestion with DNase I and by different UV exposure times. STR previously-analysed cases were revisited and studied. All the samples were typed for the SNP for ID 52plex using the SNaPshotTM assay. In all the cases, a SNP profile was achieved. In two cases involving paraffin-embedded tissue samples, it was only possible to obtain results for 48% (11 out of 23) and 61% (14 out of 23) STR and mini-STR markers, respectively. Concerning SNPs, results were possible for all the SNPs (52) in one of the cases and for 50 SNPs (96%) in the other. The PI or LR calculated values suffered a minimum of a fourfold increment. Autosomal SNPs can be used as additional markers to the profiling of ‘difficult’ cases that emerge in the routine of many laboratories.     

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.     

Massively parallel sequencing of 17 commonly used forensic autosomal STRs and amelogenin with small amplicons

The next-generation sequencing (NGS) method has been utilized to analyze short tandem repeat (STR) markers, which are routinely used for human identification purposes in the forensic field. Some researchers have demonstrated the successful application of the NGS system to STR typing, suggesting that NGS technology may be an alternative or additional method to overcome limitations of capillary electrophoresis (CE)-based STR profiling. However, there has been no available multiplex PCR system that is optimized for NGS analysis of forensic STR markers. Thus, we constructed a multiplex PCR system for the NGS analysis of 18 markers (13CODIS STRs, D2S1338, D19S433, Penta D, Penta E and amelogenin) by designing amplicons in the size range of 77–210 base pairs. Then, PCR products were generated from two single-sources, mixed samples and artificially degraded DNA samples using a multiplex PCR system, and were prepared for sequencing on the MiSeq system through construction of a subsequent barcoded library. By performing NGS and analyzing the data, we confirmed that the resultant STR genotypes were consistent with those of CE-based typing. Moreover, sequence variations were detected in targeted STR regions. Through the use of small-sized amplicons, the developed multiplex PCR system enables researchers to obtain successful STR profiles even from artificially degraded DNA as well as STR loci which are analyzed with large-sized amplicons in the CE-based commercial kits. In addition, successful profiles can be obtained from mixtures up to a 1:19 ratio. Consequently, the developed multiplex PCR system, which produces small size amplicons, can be successfully applied to STR NGS analysis of forensic casework samples such as mixtures and degraded DNA samples.     

Development and validation of a D-loop mtDNA SNP assay for the screening of specimens in forensic casework

Mitochondrial DNA (mtDNA) analysis is usually a last resort in routine forensic DNA casework. However, it has become a powerful tool for the analysis of highly degraded samples or samples containing too little or no nuclear DNA, such as old bones and hair shafts. The gold standard methodology still constitutes the direct sequencing of polymerase chain reaction (PCR) products or cloned amplicons from the HVS-1 and HVS-2 (hypervariable segment) control region segments. Identifications using mtDNA are time consuming, expensive and can be very complex, depending on the amount and nature of the material being tested. The main goal of this work is to develop a less labour-intensive and less expensive screening method for mtDNA analysis, in order to aid in the exclusion of non-matching samples and as a presumptive test prior to final confirmatory DNA sequencing. We have selected 14 highly discriminatory single nucleotide polymorphisms (SNPs) based on simulations performed by Salas and Amigo (2010) [1] to be typed using SNaPShot^TM (Applied Biosystems, Foster City, CA, USA). The assay was validated by typing more than 100 HVS-1/HVS-2 sequenced samples. No differences were observed between the SNP typing and DNA sequencing when results were compared, with the exception of allelic dropouts observed in a few haplotypes. Haplotype diversity simulations were performed using 172 mtDNA sequences representative of the Brazilian population and a score of 0.9794 was obtained when the 14 SNPs were used, showing that the theoretical prediction approach for the selection of highly discriminatory SNPs suggested by Salas and Amigo (2010) [1] was confirmed in the population studied. As the main goal of the work is to develop a screening assay to skip the sequencing of all samples in a particular case, a pair-wise comparison of the sequences was done using the selected SNPs. When both HVS-1/HVS-2 SNPs were used for simulations, at least two differences were observed in 93.2% of the comparisons performed. The assay was validated with casework samples. Results show that the method is straightforward and can be used for exclusionary purposes, saving time and laboratory resources. The assay confirms the theoretic prediction suggested by Salas and Amigo (2010) [1]. All forensic advantages, such as high sensitivity and power of discrimination, as also the disadvantages, such as the occurrence of allele dropouts, are discussed throughout the article.     

STR typing of archival Bouin's fluid-fixed paraffin-embedded tissue using new sensitive redesigned primers for three STR loci (CSF1P0, D8S1179 and D13S317)

Three new mini-STR primer sets are suggested for three conventional STRs, CSF1P0, D8S1179 and D13S317, included in multiplex PCR kits commercially available and commonly used for DNA typing in forensic applications. The primer pairs for the three loci were redesigned in order to reduce or eliminate the flanking regions of the polymorphism obtaining amplification products, which have dimensions less than 120bp in size. A comparison of results for typing carried out with the newly designed primers on DNA extracted from 100 blood samples provided by healthy donors, previously typed with conventional STRs, showed no genotype difference underlining their precision and reproducibility. The forensic usefulness of the new mini-STR primers was evaluated on highly degraded DNA from casework samples (e.g. archival post-mortem Bouin's fluid-fixed paraffin-embedded tissue specimens) for which commercial STR kit had proven inefficient.     

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.     

Applicability of the SNPforID 52-plex panel for human identification and ancestry evaluation in a Brazilian population sample by next-generation sequencing

SNP analysis is of paramount importance in forensic genetics. The development of new technologies in next-generation sequencing allowed processing a large number of markers in various samples simultaneously. Although SNPs are less informative than STRs, they present lower mutation rates and perform better when using degraded samples. Some SNP systems were developed for forensic usage, such as the SNPforID 52-plex, from the SNPforID Consortium, containing 52 bi-allelic SNPs for human identification. In this paper we evaluated the informativeness of this system in a Brazilian population sample (n = 340). DNA libraries were prepared using a customized HaloPlex Target Enrichment System kit (Agilent Technologies, Inc.) and sequenced in the MiSeq Personal Sequencer platform (Illumina Inc.). The methodology presented here allowed the analysis of 51 out of 52 SNPforID markers. Allele frequencies and forensic parameters were estimated, revealing high informativeness: the combined match probability and power of exclusion were 6.48 × 10⁻²¹ and 0.9997, respectively. Population admixture analysis indicates high European contribution (more than 70%) and low Amerindian contribution (less than 10%) in our population, while individual admixture analyses were consistent with the majority of individuals presenting high European contribution. This study demonstrates that the 52-plex kit is suitable for forensic cases in a Brazilian population, presenting results comparable with those obtained using a 16 STR panel.     

STRs vs. SNPs: thoughts on the future of forensic DNA testing

Largely due to technological progress coming from the Human Genome and International HapMap Projects, the issue has been raised in recent years within the forensic DNA typing community of the potential for single nucleotide polymorphism (SNP) markers as possible replacements of the currently used short tandem repeat (STR) loci. Our human identity testing project team at the U.S. National Institute of Standards and Technology (NIST) has explored numerous SNP and STR loci and assays as well as developing miniSTRs for degraded DNA samples. Based on their power of discrimination, use in deciphering mixture components, and ability to be combined in multiplex assays in order to recover information from low amounts of biological material, we believe that STRs rather than SNPs will fulfill the dominant role in human identity testing for the foreseeable future. However, SNPs may play a useful role in specialized applications such as mitochondrial DNA (mtDNA) testing, Y-SNPs as lineage markers, ancestry informative markers (AIMs), the prediction of phenotypic traits, and other potential niche forensic casework applications. Official disclaimer: Contribution of the U.S. National Institute of Standards and Technology. Not subject to copyright. Points of view in this document are those of the authors and do not necessarily represent the official position or policies of the U.S. Department of Justice. Certain commercial equipment, instruments and materials are identified in order to specify experimental procedures as completely as possible. In no case does such identification imply a recommendation or endorsement by the National Institute of Standards and Technology nor does it imply that any of the materials, instruments, or equipment identified are necessarily the best available for the purpose. This work was funded in part by the National Institute of Justice through interagency agreement 2003-IJ-R-029 with the NIST Office of Law Enforcement Standards.     

Fast and accurate kinship estimation using sparse SNPs in relatively large database searches

Forensic genetic genealogy (FGG) has primarily relied upon dense single nucleotide polymorphism (SNP) profiles from forensic samples or unidentified human remains queried against online genealogy database(s) of known profiles generated with SNP microarrays or from whole genome sequencing (WGS). In these queries, SNPs are compared to database samples by locating contiguous stretches of shared SNP alleles that allow for detection of genomic segments that are identical by descent (IBD) among biological relatives (kinship). This segment-based approach, while robust for detecting distant relationships, generally requires DNA quantity and/or quality that are sometimes not available in forensic casework samples. By focusing on SNPs with maximal discriminatory power and using an algorithm designed for a sparser SNP set than those from microarray typing, performance similar to segment matching was reached even in difficult casework samples. This algorithm locates shared segments using kinship coefficients in “windows” across the genome. The windowed kinship algorithm is a modification of the PC-AiR and PC-Relate tools for genetic relatedness inference, referred to here as the “whole genome kinship” approach, that control for the presence of unknown or unspecified population substructure. Simulated and empirical data in this study, using DNA profiles comprised of 10,230 SNPs (10K multiplex) targeted by the ForenSeq™ Kintelligence Kit demonstrate that the windowed kinship approach performs comparably to segment matching for identifying first, second and third degree relationships, reasonably well for fourth degree relationships, and with fewer false kinship associations. Selection criteria for the 10K SNP PCR-based multiplex and functionality of the windowed kinship algorithm are described.     

Forensic tri-allelic SNP genotyping using nanopore sequencing

The potential and current state-of-the-art of forensic SNP genotyping using nanopore sequencing was investigated with a panel of 16 tri-allelic single nucleotide polymorphisms (SNPs), multiplexing five samples per sequencing run. The sample set consisted of three single-source human genomic reference control DNA samples and two GEDNAP samples, simulating casework samples. The primers for the multiplex SNP-loci PCR were taken from a study which researched their value in a forensic setting using conventional single-base extension technology. Workflows for multiplexed Oxford Nanopore Technologies' 1D and 1D² sequencing were developed that provide correct genotyping of most SNP loci. Loci that are problematic for nanopore sequencing were characterized. When such loci are avoided, nanopore sequencing of forensic tri-allelic SNPs is technically feasible.     

Coding region mitochondrial DNA SNPs: Targeting East Asian and Native American haplogroups

We have developed a single PCR multiplex SNaPshot reaction that consists of 32 coding region SNPs that allows (i) increasing the discrimination power of the mitochondrial DNA (mtDNA) typing in forensic casework, and (ii) haplogroup assignments of mtDNA profiles in both human population studies (e.g. anthropological) and medical research. The selected SNPs target the East Asian phylogeny, including its Native American derived branches. We have validated this multiplex assay by genotyping a sample of East Asians (Taiwanese) and Native Americans (Argentineans). In addition to the coding SNP typing, we have sequenced the complete control region for the same samples. The genotyping results (control region plus SNaPshot profiles) are in good agreement with previous human population genetic studies (based on e.g. complete sequencing) and the known mtDNA phylogeny. We observe that the SNaPshot method is reliable, rapid, and cost effective in comparison with other techniques of multiplex SNP genotyping. We discuss the advantages of our SNP genotyping selection with respect to previous attempts, and we highlight the importance of using the known mtDNA phylogeny as a framework for SNP profile interpretation and as a tool to minimize genotyping errors.     

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.