Evaluation of the Differex™ System

Differential extraction is an efficient method to separate sperm cells from epithelial cells. A manual Chelex^®-100 based method is used at the Swedish National Laboratory of Forensic Science, SKL. The Differex™ System (Promega) uses a Proteinase K digestion of epithelial cells followed by centrifugation and phase separation. The sperm- and epithelial fractions are further purified with DNA IQ™ System (Promega) or with phenol/chloroform. The Differex™ System in combination with DNA IQ™ System were evaluated and compared to the Chelex^®-100 method used routinely. After modifications, the Differex™ System gave comparable results to the Chelex^®-100 method. The modifications included additional Proteinase K and DTT, longer incubation time and additional steps when removing the solid support from the Digestion Solution. In the Chelex^®-100 based method microscopic examination is done on the sperm pellet in a total volume of 50 μl. It was not possible to do a microscopic examination in less than 100 μl using the Differex™ System. Additionally the sperms were in clusters of epithelial cell debris. Microscopic examination is an important part of the differential extraction at SKL. Therefore, the Differex™ System will not be implemented at our laboratory.     

Developmental validation of the AmpF?STR SEfiler Plus™ PCR amplification kit: An improved multiplex with enhanced performance for inhibited samples

Since its introduction in 2002, the AmpF?STR^® SEfiler™ kit has provided a highly discriminating DNA profiling option to German forensic laboratories by combining the widely used SGM Plus^® Kit loci with the SE-33 locus required for the German DNA Database. Whilst proving successful on database samples, laboratories using the SEfiler™ kit have reported the need for chemistry better able to handle the ever-increasing number of casework samples.The new AmpF?STR^® SEfiler Plus™ kit contains the same loci and primer sequences as the SEfiler™ kit but uses improved synthesis and purification processes to minimize the presence of dye-labeled artifacts. Other improvements include modified PCR cycling conditions for enhanced sensitivity and a new buffer formulation that improves performance with inhibited samples when compared to the original SEfiler™ kit.Validation studies demonstrating the effectiveness of the multiplex are presented with emphasis on the models of inhibition and casework samples.     

Successful STR and SNP typing of FTA Card samples with low amounts of DNA after DNA extraction using a Qiagen BioRobot EZ1 Workstation

FTA Cards (GE Healthcare) have been used for more than 4 years in Denmark for the collection of buccal cells as reference samples in crime cases. Semi-automated protocols for STR typing of DNA on punches of FTA Cards are routinely used. In average, full STR profiles were generated from approximately 95% of the FTA Cards with a standard punching protocol, while partial or no STR profile were obtained from 5% of the samples. Here, the Qiagen BioRobot^® EZ1 Workstation (Qiagen) and the EZ1 DNA Investigator Kit (Qiagen) was used to extract DNA from 29 FTA Cards from which a complete STR profile was not generated with the standard punching protocol. All 29 samples were successfully typed with the AmpF?STR^® Identifiler™ PCR Amplification Kit (Applied Biosystems) and with the SNPforID 49plex SNP assay. The lowest amount of DNA that resulted in complete STR and SNP profiles was 80 pg. The STR and SNP profiles were identical to those generated from another sample collected from each of the 29 individuals.     

Optimization and validation of a fast amplification protocol for AmpFlSTR Profiler Plus for rapid forensic human identification

The goal of this work was to optimize and validate a fast amplification protocol for the multiplex amplification of the STR loci included in AmpFlSTR^® Profiler Plus^® to expedite human DNA identification. By modifying the cycling conditions and by combining the use of a DNA polymerase optimized for high speed PCR (SpeedSTAR™ HS) and a more efficient thermal cycler instrument (Bio-RAD C1000™), we were able to reduce the amplification process from 4 h to 26 min. No modification to the commercial AmpFlSTR^® Profiler Plus^® primer mix was required. When compared to the current Royal Canadian Mounted Police (RCMP) amplification protocol, no differences with regards to specificity, sensitivity, heterozygote peak height ratios and overall profile balance were noted. Moreover, complete concordance was obtained with profiles previously generated with the standard amplification protocol and minor alleles in mixture samples were reliably typed. An increase in n − 4 stutter ratios (2.2% on average for all loci) was observed for profiles amplified with the fast protocol compared to the current procedure. Our results document the robustness of this rapid amplification protocol for STR profiling using the AmpFlSTR^® Profiler Plus^® primer set and demonstrate that comparable data can be obtained in substantially less time. This new approach could provide an alternative option to current multiplex STR typing amplification protocols in order to increase throughput or expedite time-sensitive cases.     

Direct amplification of STRs from blood or buccal cell samples

Forensic databasing laboratories routinely analyze blood or buccal cell samples deposited on FTA^® paper. Prior to PCR amplification of the STRs, the FTA^® samples must undergo multi-step sample purification protocols to remove the PCR inhibitors present within the sample and from the FTA^® paper. The multi-step sample purification protocols are laborious, time-consuming and increase the potential for sample cross-contamination.To eliminate the need for DNA purification, we conducted studies to optimize the PCR buffer and thermal cycling parameters to allow for direct amplification of STRs from blood or buccal samples on FTA^® paper. We evaluated the effect of various factors on the DNA profile including: FTA^® disc size, blood sample load variation, and buffer formulation. The new STR assay enables the direct amplification of DNA from single source samples on FTA^® discs without sample purification. The new STR assay improves the workflow by eliminating tedious steps and minimizing sample handling. Furthermore, the new STR assay reduces cost by eliminating the need for purification reagents and expensive robots.     

Adaptation and evaluation of the PrepFiler™ DNA extraction technology in an automated forensic DNA analysis process with emphasis on DNA yield, inhibitor removal and contamination security

Within the initial step of the forensic DNA analysis process, the DNA extraction efficiency and especially the removal of potential PCR inhibitors is crucial for subsequent steps, e.g. quantification by real-time PCR and amplification of short tandem repeats (STRs). The protocol of the PrepFiler™ Forensic DNA Extraction Kit was optimized for the application on a Tecan liquid handling workstation Freedom EVO^® 150. This modified application of the PrepFiler™ technology was compared with respect to DNA yield, sensitivity and the ability to remove potential PCR inhibitors to an established routine method working on the same liquid handling workstation based on ChargeSwitch^® Technology (CST) from Invitrogen.     

Utility validation of extraction of genomic DNA from hard tissues, bone and nail, using PrepFiler™ Forensic DNA Extraction Kit

STR profiling using hard tissues obtained from a severely decomposed body is sometimes a laborious work. There is now on a market a new DNA extraction kit, PrepFiler™ Forensic DNA Extraction Kit (AppliedBiosystems), and we tested it for missing persons. Postmortem intervals ranged from weeks to several years. Fifteen bone fragments and eleven nails were used in this report. Genomic DNA was quantified by QuantiFiler^® DUO Quantification Kit (AppliedBiosystems), and STRs were analyzed using AmpFlSTR^® Identifiler^® PCR Amplification Kit (AppliedBiosystems). The profiling of 16 STR loci was successful in all nail samples. However, STR profiling was successful in only 6 of 15 bone materials. Nine cases failed to analyze STR polymorphisms using another DNA extraction kit, the QIAamp DNA Mini Kit (QIAGEN). For bone samples, it seems that STR profiling depends on the quality of samples.     

Allele frequency distribution for 21 autosomal STR loci in Bhutan

We studied the allele frequency distribution of 21 autosomal STR loci contained in the AmpFlSTR^® Identifiler™ (Applied Biosystems), the Powerplex^®16 (Promega) and the FFFL (Promega) multiplex PCR kits among 936 individuals from the Royal Kingdom of Bhutan. As such these are the first published autosomal DNA results from this country.     

The use of Hemastix® severely reduces DNA recovery using the BioRobot® EZ1

Abstract: The choice of reagents for presumptive tests for blood, and subsequent extraction methodologies, can significantly affect both the quantity and quality of purified DNA. Blood samples directly tested with Hemastix^® yielded <1% of the DNA recovered from untested samples when purified using the Qiagen BioRobot^® EZ1 and EZ1^® DNA Investigator kit. Full short tandem repeat profiles were obtained from both tested and untested samples, suggesting that the Hemastix^® reagent(s) affect DNA binding, rather than produce DNA damage. The Hemastix^® inhibition of DNA yield could be overcome by the addition of MTL buffer to the sample prior to extraction. Laboratories may wish to modify current procedures for extracting blood samples, utilize other extraction/purification methodologies, or inform their submitting agencies to avoid direct exposure of questioned bloodstains to Hemastix^® reagents.     

Validation of the AmpF?STR SEfiler Plus™ PCR Amplification kit for forensic STR analysis

Validation of the AmpF?STR^® SEfiler Plus™ PCR Amplification kit with 29 and 30 PCR cycles for forensic STR analysis demonstrated that the kit had fewer artefacts than the AmpF?STR^® SGM Plus™ kit (28 PCR cycles). The SEfiler Plus kit was more sensitive and devoid of colour artefacts, but showed more stutters, drop-ins, drop-outs and allelic imbalances.     

Effect of blood stained soils and time period on DNA and allele drop out using Promega 16 Powerplex kit

Blood stained soils may be of great interest in forensic incidents. Amplification of DNA from soil is often inhibited by co-purified contaminants. Different soils types from Pakistan and Turkey were stained with blood and samples were collected systematically after specified intervals. Rapid, inexpensive, large-scale DNA extraction method involving minimal purification was developed. DNA was quantized using Spectrophotometer and Fluorometer and was confirmed by Agarose Gel Electrophoresis. DNA extracted from different soils in different periods showed a remarkable decrease in yield as well as degradation in every extraction. PCR amplification was performed using various DNA targets present in Promega 16 Powerplex^® System kit. Amplification could not carry out in all loci especially in degraded samples taken after 20 days. Allele n locus drop out was noticed which shows that DNA was degraded. For some loci more than 2 alleles were also noticed showing contamination while working with the blood stained soils.     

Automated extraction of DNA from reference samples from various types of biological materials on the Qiagen BioRobot EZ1 Workstation

We have validated and implemented a protocol for DNA extraction from various types of biological materials using a Qiagen BioRobot EZ1 Workstation. The sample materials included whole blood, blood from deceased, buccal cells on Omni swabs and FTA Cards, blood on FTA Cards and cotton swabs, and muscle biopsies. The DNA extraction was validated according to EN/ISO 17025 for the STR kits AmpF?STR^® Identifiler^® and AmpF?STR^® Yfiler^® (Applied Biosystems). Of 298 samples extracted, 11 (4%) did not yield acceptable results. In conclusion, we have demonstrated that extraction of DNA from various types of biological material can be performed quickly and without the use of hazardous chemicals, and that the DNA may be successfully STR typed according to the requirements of forensic genetic investigations accredited according to EN/ISO 17025.     

Evaluation of five DNA extraction systems for recovery of DNA from bone

Five DNA extraction systems were assessed for their DNA extraction efficiency on samples of fresh pig bone. Four commercially available silica-based extraction kits (ChargeSwitch^® gDNA Plant Kit (Life Technologies), DNA IQ^TM System Kit (Promega), DNeasy^® Blood & Tissue Kit (Qiagen) and PrepFiler^® BTA Forensic DNA Extraction Kit (Life Technologies)) and a conventional phenol-chloroform method were tested in this study. Extracted DNA samples were quantitated with GoTaq^® qPCR Master Mix (Promega) using an Applied Biosystems^® 7500 Real-Time PCR System and the extracts were amplified using an in-house multiplex system. The phenol-chloroform extraction produced higher yields of DNA than the silica-based extraction methods. Among the silica-based extractions ChargeSwitch^® gDNA Plant Kit recovered the highest amounts of DNA. However, all methods produced DNA that could be amplified and none of the extracts contained any detectable inhibition.     

A dedicated automated system for extraction, quantification and STR amplification of forensic evidence samples

Forensic DNA analysis is a multi-step process involving extraction of DNA, quantification of human DNA in the extract, amplification using multiplex STR systems, separation of products, and data analysis. The backlog of forensic casework is increasing worldwide. Automation is one significant way to alleviate the bottleneck of sample processing in forensic labs. The HID EVOlution™ Combination System described here is a robust, reliable sample processing platform, easily adapted to forensic laboratory workflows. Using a variety of forensic sample types including: blood stained FTA paper, cotton fabric and denim, dried blood spiked with known PCR inhibitors, saliva on cotton swabs, and semen stains, we found that yields of human DNA and STR profiles obtained with AmpFlSTR^® Idenitfiler^® kits were complete, highly reproducible, and equivalent to results obtained using the manual PrepFiler™ reagent extraction method. Automated operation was clean, and no cross-contamination was detected between extraction blanks and interspersed high DNA content samples.     

Extraction of high quality DNA from biological materials and calcified tissues

Calcified tissues, such as bone and tooth, and some other sample types, such as those containing adhesive, present a challenge to standard extraction protocols. We have developed a lysis reagent, BTA™ lysis buffer, which is designed for use with PrepFiler™ Kit reagents. The BTA™ lysis buffer disrupts calcified tissue matrices and achieves effective extraction of DNA from pulverized bone and tooth samples. In addition, the BTA™ lysis buffer mildly but efficiently extracts DNA from challenging substrates like tape, chewing gum, and cigarette butts and, as with bone and tooth, DNA from these lysates is purified using established PrepFiler™ reagent extraction protocols.We successfully extracted DNA from powdered human bone samples, chewed gum and smoked cigarettes using BTA™ lysis buffer. Extraction yields for bone, gum and cigarette samples tested were consistent and reproducible. This extraction method efficiently removed potential PCR inhibitors from all samples tested, and C_T values for the internal PCR control of Quantifiler^® Human DNA Quantification Kit were consistent and within the normal range. The DNA extracted from these samples also provided conclusive profiles that were free of PCR artifacts when amplified using the AmpF?STR^® Identifiler^® PCR Amplification Kit. The protocol is easily adapted for automation.     

Automated extraction of DNA and PCR setup using a Tecan Freedom EVO liquid handler

We have implemented and validated automated methods for DNA extraction and PCR setup developed for a Tecan Freedom EVO^® liquid handler mounted with a Te-MagS™ magnetic separation device. The DNA was extracted using the Qiagen MagAttract^® DNA Mini M48 kit. The DNA was amplified using AmpF?STR^® Identifiler^®, Y-filer^® (Applied Biosystems), GenePrint^® FFFL and PowerPlex^® Y (Promega). The methods were validated for fresh whole blood and blood from deceased according to EN/ISO 17025.     

Optimization of DNA recovery from toothbrushes

In human identification, the victim's toothbrush is an invaluable personal item as the deposited cellular material contains DNA from which a reference profile can be produced. The profile obtained then allows direct comparison to be made with the profile from the unidentified body. This study was undertaken to determine the minimum number of bristle bundles that would generate a complete DNA profile. The minimum period of usage for a toothbrush to retain enough cells for genotyping was also investigated. We also tested two commonly used DNA extraction methods: QIAamp^® DNA Mini Kit and Chelex^® 100 to explore the efficiency of these protocols in recovering DNA from toothbrushes. In this experiment, volunteers brushed their teeth for 1, 7, 14, or 30 days. DNA was extracted from 5 and 10 bundles of bristles cut from the collected toothbrushes. The amount of DNA recovered was quantified by quantitative real-time PCR, and DNA genotyping was performed for each sample. Data revealed that QIAamp^® DNA Mini Kit performed better at yielding DNA in terms of purity, quantity, and quality than Chelex^® 100. It was also found that, with a suitable method of recovery, DNA samples from five bundles of bristles from all of the toothbrushes generated complete profiles. Based on the experimental results, a general guideline concerning the appropriate extraction method and the quantity of the starting material for the analysis of DNA from toothbrushes could be suggested.     

The Upper Silesia (Poland) population and forensic usefulness of 15 autosomal STR loci

Allele frequencies, forensic parameters for the 15 STR loci in the AmpFlSTR^® Identifiler Kit (Applied Biosystems), D8S1179, D21S11, D7S820, CSF1PO, D3S1358, TH01, D13S317, D16S539, D19S433, VWA, TPOX, D18S51, D5S818 and FGA were determined in a sample of 150 unrelated dead and alive adults from the Upper Silesia region (Poland). The values of heterozygosity (Ht), polymorphic information content (PIC), power of discrimination (PD), matching probability (PM), mean exclusion chance (MEC) and mean exclusion probability (MEP) were calculated. Possible divergence from HWE was determined. Comparison of allele frequencies for examined STR loci between the Upper Silesia population and other Polish populations was carried out.     

The BodeChecks solution: A high throughput analysis software combining GeneMapper ID, FSS-i, LIMS, and artificial intelligence

Combining key attributes of GeneMapper^® ID and FSS-i³ software packages with our internally created LIMS and some additional analytical programming has permitted us to increase quality checks on DNA profile data review while eliminating analysis time.