Michael Stangegaard

Autosomal SNP typing of forensic samples with the GenPlex TM 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 250-500pg 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, 500pg 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 500pg 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 500pg 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.

Typing of 48 autosomal SNPs and amelogenin with GenPlex SNP genotyping system in forensic genetics

GenPlex (Applied Biosystems) is a new SNP genotyping system based on an initial PCR amplification followed by an oligo ligation assay (OLA). The OLA consists of the hybridization of allele and locus specific oligonucleotides (ASOs and LSOs) to PCR products and posterior ligation of ASOs and LSOs. The ligation products are immobilized to microtitre plates and reporter oligonucleotides (ZipChute probes) are hybridized to the ligation products. ZipChute probes are subsequently eluted and detected using capillary electrophoresis. Applied Biosystems developed the GenPlex SNP genotyping system with amelogenin and 48 of the 52 SNPs used in the 52 SNP-plex assay developed by the SNPforID consortium. The system requires equipment that is usually found in forensic genetic laboratories. The use of a robot for performance of the pipetting steps is highly recommendable. A total of 286 individuals from Denmark, Somalia and Greenland were investigated with GenPlex using a Biomek 3000 (Beckman Coulter) robot. The results were compared to results obtained with an ISO 17025 accredited SNP typing assay based on single base extension (SBE). With the GenPlex SNP genotyping system, full SNP profiles were obtained in 97.6% of the investigations. Perfect concordance was obtained in duplicate investigations and the SNP genotypes obtained with the GenPlex system were concordant with those of the accredited SBE based SNP typing system except for one result in rs901398 in one of 286 individuals most likely due to a mutation 6 bp downstream of the SNP. Reproducible SNP genotypes were obtained from as little as 250 pg of DNA.

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.

Automated Extraction of DNA from Blood and PCR Setup using a Tecan Freedom EVO Liquid Handler for Forensic Genetic STR Typing of Reference Samples

We have implemented and validated automated protocols for DNA extraction and PCR setup using a Tecan Freedom EVO liquid handler mounted with the Te-MagS magnetic separation device (Tecan, Mannedorf, Switzerland). The protocols were validated for accredited forensic genetic work according to ISO 17025 using the Qiagen MagAttract DNA Mini M48 kit (Qiagen GmbH, Hilden, Germany) from fresh whole blood and blood from deceased individuals. The workflow was simplified by returning the DNA extracts to the original tubes minimizing the risk of misplacing samples. The tubes that originally contained the samples were washed with MilliQ water before the return of the DNA extracts. The PCR was setup in 96-well microtiter plates. The methods were validated for the kits: AmpFSTR Identifier, SGM Plus and Yfiler (Applied Biosystems, Foster City, CA), GenePrint FFFL and PowerPlex Y (Promega, Madison, Wl). The automated protocols allowed for extraction and addition of PCR master mix of 96 samples within 3.5 h. In conclusion, we demonstrated that (1) DNA extraction with magnetic beads and (2) PCR setup for accredited, forensic genetic short tandem repeat typing can be implemented on a simple automated liquid handler leading to the reduction of manual work, and increased quality and throughput.

A simple method for validation and verification of pipettes mounted on automated liquid handlers

We have implemented a simple, inexpensive, and fast procedure for validation and verification of the performance of pipettes mounted on automated liquid handlers (ALHs) as necessary for laboratories accredited under ISO 17025. A six- or seven-step serial dilution of OrangeG was prepared in quadruplicates in a flat-bottom 96-well microtiter plate, manually using calibrated pipettes. Each pipette of the liquid handler (1–8) dispensed a selected volume (1–200μL) of OrangeG eight times into the wells of the microtiter plate. All wells contained a total of 200μL liquid. The absorbance was read, and the dispensed volume of each pipette was calculated based on a plot of volume and absorbance of a known set of OrangeG dilutions. Finally, the percent inaccuracy (%d) and the imprecision (%CV) of each pipette were calculated. Using predefined acceptance criteria, each pipette was then either approved or failed. Failed pipettes were either repaired or the volume deviation was compensated for by applying a calibration curve in the liquid-handler software. We have implemented the procedure on a Sias Xantus, an MWGt The ONYX, four Tecan Freedom EVO, a Biomek NX Span-8, and four Biomek 3000 robots, and the methods are freely available. In conclusion, we have set up a simple, inexpensive, and fast solution for the continuous validation of ALHs used for accredited work according to the ISO 17025 standard. The method is easy to use for aqueous solutions but requires a spectrophotometer that can read microtiter plates.

Gene Expression Analysis Using Agilent DNA Microarrays

Hybridization of labeled cDNA to microarrays is an intuitively simple and a vastly underestimated process. If it is not performed, optimized, and standardized with the same attention to detail as e.g., RNA amplification, information may be overlooked or even lost. Careful balancing of the amount of labeled cDNA added to each slide reduces dye-bias and slide to slide variation. Efficient mixing of the hybridization solution throughout the hybridization reaction increases signals several fold. The amount of near perfect target-probe hybrids may be reduced by efficient stringency washes of the hybridized microarray slides.

Biomek-3000 and GenPlex SNP Genotyping in Forensic Genetics

Single nucleotide polymorphism genotyping provides a supplement for conventional short tandem repeats-based kits currently used for human identification. GenPlex (Applied Biosystems (AB), Foster City, CA) is an SNP-genotyping kit based on a multiplex of 48 informative, autosomal SNPs from the SNPforID Consortium. Our objective was to setup, implement, and validate a small and affordable automated liquid-handling robot for forensic casework samples (buccal swaps on FTA-paper and Qiagen purified blood). The reaction scheme consisted of numerous steps and was cumbersome to perform consistently manually. Automation was accomplished with a Biomek-3000 (Beckmann Coulter) laboratory-automated workstation using five in-house-developed methods. All methods allowed the user to select the number of subsequent injections to the capillary electrophoresis instrument (ABI 3130xl, AB) enabling processing of both partial and full plates. A total of 286 samples were analyzed in duplicates with the GenPlex reaction using the Biomek-3000. The results were compared with those obtained from the same samples using the SNaPshot(AB) single-base extension system. Full concordance of the results was obtained in all but one sample. The results demonstrate that the Biomek-3000 can perform a series of complex reactions leading to highly consistent forensic genetic SNP-typing results.

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%).

Biomek 3000 The Workhorse in an Automated Accredited Forensic Genetic Laboratory

We have implemented and validated automated protocols for a wide range of processes such as sample preparation, PCR setup, and capillary electrophoresis setup using small, simple, and inexpensive automated liquid handlers. The flexibility and ease of programming enable the Biomek 3000 to be used in many parts of the laboratory process in a modern forensic genetics laboratory with low to medium sample throughput. In conclusion, we demonstrated that sample processing for accredited forensic genetic DNA typing can be implemented on small automated liquid handlers, leading to the reduction of manual work as well as increased quality and throughput.

Laboratory Automation and LIMS in Forensics

Implementation of laboratory automation and laboratory information management systems (LIMS) in a forensic laboratory enables the laboratory to standardize sample processing. Automated liquid handlers (ALHs) can increase throughput and eliminate manual repetitive pipetting operations, known to result in occupational injuries to the technical staff. Furthermore, implementation of ALHs reduces the risk of sample misplacement. A LIMS can efficiently control the sample flow through the laboratory and manage the results of the tests conducted for each sample. Integration of ALHs with a LIMS provides the laboratory with the tools required for setting up automated production lines of complex laboratory processes and monitoring the whole process and the results. Combined, this enables processing of a large number of samples. Selection of the best automated solution for an individual laboratory should be based on user requirements for the specific process and vendor requirements for, and availability of, local support. Implementation and validation should be performed according to user requirements with the amount of samples relevant for the individual process. ALHs used for routine work should have regular preventative maintenance inspections as well as performance checks to ensure reliable operation and trustworthy results.