ABSTRACT
The generation of high-quality DNA profiles from trace amounts of DNA continues to be an issue in forensic casework. Several methods have been proposed over the years to increase recovery rates for low input DNA, including purification of PCR products, an increase in PCR cycle numbers and increasing injection time or voltage during electrophoresis. In this study, the characteristics of DNA profiles generated using QIAGEN MinElute® purification of Promega PowerPlex® 21 amplified products for low DNA input samples, ranging from 80â¯pg down to 4â¯pg, were evaluated. MinElute® purification was found to be a simple, effective and time efficient method, which can greatly improve the resolution of amplified PCR products, recovering 100% of donor concordant alleles from as little 16â¯pg of input template DNA and generating sufficient allelic information for interpretation from as low as 4â¯pg inputs. However, as is commonly observed with low template DNA samples, the results exhibited extensive disparity in the effects of stochastic variation in amplification, including increased heterozygote peak height imbalance, stutter ratios and instances of allelic drop-in and drop-out, both within and between replicates. As such, it is important that the extent and variability of these stochastic effects are appropriately incorporated in the development of robust profile interpretation guidelines for DNA profiles generated from purified PCR products.
Subject(s)
DNA Fingerprinting , DNA , Microsatellite Repeats , Polymerase Chain Reaction , DNA Fingerprinting/methods , Humans , DNA/isolation & purification , AllelesABSTRACT
Tape-lifting is a non-destructive method employed in the laboratory to recover and collect trace DNA evidence from crime scene exhibits with porous surfaces. The success of tape-lifting is a balance between capturing the biological material and compatibility with downstream DNA extraction processes to ensure efficient release of the tape-lifted material during DNA extraction. In this study, six commercially available low-, regular- and high-tack adhesive tapes were evaluated. The low-tack S183 tape and the highly adhesive S-Hold tape were compared for DNA recovery efficiency from different materials commonly encountered in casework. All tape-lifts were processed using PrepFiler Express™ BTA and AutoMate Express™ Forensic DNA extraction systems, DNA samples quantitated by Quantifiler TRIO, amplified using Powerplex® 21 and VeriFiler™ PLUS (VFP), and analysed on a 3500xl genetic analyser to evaluate the quality of the resultant STR profiles obtained. The more adhesive S-Hold tape recovered comparable or more DNA than the low-tack S183 tape from the majority of materials tested. However, STR profiles obtained from S183 tape-lifts were of markedly higher quality compared to S-Hold tape-lifts. This was most evident for towel, denim and printed chiffon, where S-Hold samples exhibited severe PCR inhibition, with VFP internal quality markers confirming the presence of inhibitors. The findings suggest that strong adhesion is not necessarily beneficial for tape-lifting, as the low tack S183 tape was able to efficiently recover cellular material from the surface of porous substrates commonly encountered in casework, while avoiding the co-transfer of PCR-inhibitory substances from the sampled material.