Lena Poulsen

Typing of 30 insertion/deletions in Danes using the first commercial indel kit--Mentype® DIPplex.

In this study, we tested the first commercial kit with insertion/deletion (indel) polymorphisms, the Mentype(®) DIPplex PCR Amplification Kit (DIPplex kit). A total of 30 biallelic autosomal indels and Amelogenin were amplified with the DIPplex kit. All loci were amplified in one PCR multiplex and all amplicon lengths were shorter than 160 bp. Full indel profiles were generated from as little as 100 pg of DNA. A total of 117 individuals from Danish paternity cases were successfully typed. No deviation from Hardy-Weinberg equilibrium was observed for any of the indels. The combined mean match probability was 3.3 × 10(-13), the mean paternity exclusion probability was 99.7% and the typical paternity indices for trios and duos were 2350 and 165, respectively. Furthermore, we typed five highly degraded DNA samples with the DIPplex kit, the AmpFlSTR(®) SGM Plus kit and the AmpFlSTR(®) SEfiler Plus kit. Full indel profiles were obtained with the DIPplex kit, whereas only partial profiles were obtained with the STR kits. In general, the DIPplex kit performed well and it would be a valuable assay for forensic genetic testing, especially in crime cases with partially degraded DNA or low amounts of template DNA. However, some difficulties with pull-ups were observed at DNA concentrations of 1000 pg. Rearrangement of the allele windows by changing the lengths of some of the PCR primers would greatly improve the assay, and more robustness towards higher amounts of DNA would allow the use of the DIPplex kit without prior quantification of the samples.

Increasing the specificity and function of DNA microarrays by processing arrays at different stringencies

DNA microarrays have for a decade been the only platform for genome-wide analysis and have provided a wealth of information about living organisms. DNA microarrays are processed today under one condition only, which puts large demands on assay development because all probes on the array need to function optimally under one condition only. Microarrays are often burdened with a significant degree of cross-hybridization, because of a poor combination of assay conditions and probe choice. As reviewed here, a number of promising microfluidics-based technologies can provide automatic processing of arrays under different assay conditions. These new array processors provide researchers and assay developers with novel possibilities to construct highly specific DNA arrays even towards regions of DNA greatly varying in G + C content. These array processors are also a powerful development tool for building arrays, because they combine high sample throughput with investigation of optimal assay conditions. The array processors can increase specificity in all DNA microarray assays, e.g. for gene expression, and microRNA and mutation analysis. Increased specificity of the array will also benefit microarray-based loci selection prior to high-throughput sequencing.

ISO 17025 validation of a next-generation sequencing assay for relationship testing.

The HID‐Ion AmpliSeq™ Identity Panel is a next‐generation sequencing assay with 90 autosomal and 34 Y‐chromosome SNPs that are amplified in one PCR step and subsequently sequenced using the Ion Personal Genome Machine (Ion PGM™) System. This assay was validated for relationship testing in our ISO 17025 accredited laboratory in 2015. Here, the essential parts of the validation report submitted to the Danish Accreditation Fund are presented. A total of 100 unrelated Danes were typed in duplicates and the locus balance, heterozygote balance (Hb) and noise levels were analysed in detail. Two loci were disregarded for casework because genotyping was uncertain. Hb for rs7520386 was skewed and high levels of noise were observed in rs576261. Three general acceptance criteria for analysis of single‐source samples were defined: (i) sequencing depth > 200 reads, (ii) noise level < 3% and (iii) Hb > 0.3. A Python script named SNPonPGM was developed to assist the analyst by highlighting loci that do not fulfil the general acceptance criteria. Furthermore, SNPonPGM has functions that reduce the hands‐on time of the reporting officer to a few minutes per case. Mixtures with DNA from two individuals in a 1:24 ratio were readily identified using the three criteria and the SNPonPGM script.

Results for five sets of forensic genetic markers studied in a Greek population sample

A population sample of 223 Greek individuals was typed for five sets of forensic genetic markers with the kits NGM SElect™, SNPforID 49plex, DIPplex®, Argus X-12 and PowerPlex® Y23. No significant deviation from Hardy-Weinberg expectations was observed for any of the studied markers after Holm-Šidák correction. Statistically significant (P<0.05) levels of linkage disequilibrium were observed between markers within two of the studied X-chromosome linkage groups. AMOVA analyses of the five sets of markers did not show population structure when the individuals were grouped according to their geographic origin. The Greek population grouped closely to the other European populations measured by F(ST)(*) distances. The match probability ranged from a value of 1 in 2×10(7) males by using haplotype frequencies of four X-chromosome haplogroups in males to 1 in 1.73×10(21) individuals for 16 autosomal STRs.

Evaluation of Four Automated Protocols for Extraction of DNA from FTA Cards

Extraction of DNA using magnetic bead-based techniques on automated DNA extraction instruments provides a fast, reliable, and reproducible method for DNA extraction from various matrices. Here, we have compared the yield and quality of DNA extracted from FTA cards using four automated extraction protocols on three different instruments. The extraction processes were repeated up to six times with the same pieces of FTA cards. The sample material on the FTA cards was either blood or buccal cells. With the QIAamp DNA Investigator and QIAsymphony DNA Investigator kits, it was possible to extract DNA from the FTA cards in all six rounds of extractions in sufficient amount and quality to obtain complete short tandem repeat (STR) profiles on a QIAcube and a QIAsymphony SP. With the PrepFiler Express kit, almost all the extractable DNA was extracted in the first two rounds of extractions. Furthermore, we demonstrated that it was possible to successfully extract sufficient DNA for STR profiling from previously processed FTA card pieces that had been stored at 4 °C for up to 1 year. This showed that rare or precious FTA card samples may be saved for future analyses even though some DNA was already extracted from the FTA cards.

Typing of Amerindian Kichwas and Mestizos from Ecuador with the SNPforID multiplex

A total of 119 unrelated individuals from two of the major ethnic groups in Ecuador were typed for 49 of the autosomal single nucleotide polymorphisms (SNPs) in the SNPforID 52plex using the SNapShot(®) assay. Of the above, 42 samples originated from Mestizos (an admixed population) and the remaining 77 were from Native Amerindian Kichwas. We obtained full SNP profiles in all individuals and concordance of duplicated analyses. No deviation from Hardy-Weinberg equilibrium (HWE) was observed for any SNP in the Mestizo and Kichwa populations and only one and four pairs of loci, respectively showed significant linkage disequilibrium. A relatively low genetic diversity and global positive F(IS) value was observed in Kichwas. A statistically significant global F(ST) value was obtained when the two Ecuadorian populations were compared with populations in Spain, Portugal, Argentina, Denmark, Greenland, China, Somalia and Mozambique. All pairwise F(ST) values were statistically significant. A multi-dimensional scaling based on pairwise F(ST) values showed that the Kichwa population differed from all other populations investigated and that the Mestizos had an intermediate position between Kichwas and Europeans. An admixture analysis indicated that the greater contributor to the Mestizo population was the Kichwas (71.2%) compared to the European contribution. The combined mean match probability and mean paternity exclusion probability were 3.3 × 10(-17) and 0.998, respectively, for the Mestizo population and 3.3 × 10(-14) and 0.993, respectively, for the Kichwa population.

NGMSElect™ and Investigator(®) Argus X-12 analysis in population samples from Albania, Iraq, Lithuania, Slovenia, and Turkey.

The analysis of STRs is the main tool when studying genetic diversity in populations or when addressing individual identification in forensic casework. Population data are needed to establish reference databases that can be used in the forensic context. To that end, this work investigated five population samples from Albania, Iraq, Lithuania, Slovenia, and Turkey. Individuals were typed for 16 autosomal STRs and 12 X-chromosomal STRs using the NGMSElect™ and Investigator(®) Argus X-12 kits, respectively. The aim of the study was to characterize the diversity of both STR kits in these population samples and to expand our forensic database. The results showed that all markers were polymorphic in the five populations studied. No haplotype was shared between the males analysed for X-STRs. No statistically significant deviations from Hardy-Weinberg equilibrium were observed for any of the genetic markers included in both the kits. Pairwise LD was only detected in X-STRs between markers located in the same linkage group. Power of discrimination values for males and females and the probability of exclusion in duos and trios were high for the populations in this study.

Population and forensic data for three sets of forensic genetic markers in four ethnic groups from Iran: Persians, Lurs, Kurds and Azeris.

A total of 255 individuals (Persians, Lurs, Kurds and Azeris) from Iran were typed for three sets of forensic genetic markers with the NGM SElect™, DIPplex(®) and Argus X-12 kits. Statistically significant deviations (P≤0.002) from Hardy-Weinberg expectations were observed for the insertion-deletion markers HLD97 and HLD93 after Holm-Šidák correction. Statistically significant (P<0.05) levels of linkage disequilibrium were observed between markers within two of the four studied X-chromosomal linkage groups. AMOVA analyses of the three sets of markers did not show population structure when the individuals were grouped according to their ethnic group. The Iranian population grouped closely to populations living geographically near to Iran based on pairwise FST distances. The matching probabilities ranged from 1 in 3.2×10(7) males by using haplotype frequencies of four X-chromosomal haplogroups to 1 in 3.4×10(21) individuals for the 16 autosomal STRs.

Thirty autosomal insertion-deletion polymorphisms analyzed using the Investigator® DIPplex Kit in populations from Iraq, Lithuania, Slovenia, and Turkey

Thirty autosomal insertion-deletion (InDel) polymorphisms were analyzed in four populations from Iraq, Lithuania, Slovenia, and Turkey using the commercial kit Investigator® DIPplex. Genotyping issues were encountered for five of the 30 InDels. They were most probably caused by polymorphisms located in the primer binding sites. Population and forensic parameters were calculated. No significant deviations from Hardy-Weinberg equilibrium or significant linkage disequilibrium were detected. The observed heterozygosities ranged from 33% to 61% depending on the marker and the population. The combined probability of exclusion for the 30 markers was 99.7% in all four populations and the matching probabilities were 1 in 3-4×1012 individuals. The multidimensional scaling plot drawn from FST distances showed a good concordance between the relative position of the 15 populations included in the plot and their geographic locations.