Abstract
For the adoption of massively parallel sequencing (MPS) systems by forensic laboratories, validation studies on specific workflows are needed to support the feasibility of implementation and the reliability of the data they produce. As such, the whole mitochondrial genome sequencing methodology—Precision ID mtDNA Whole Genome Panel, Ion Chef, Ion S5, and Converge—has been subjected to a variety of developmental validation studies. These validation studies were completed in accordance with the Scientific Working Group on DNA Analysis Methods (SWGDAM) validation guidelines and assessed reproducibility, repeatability, accuracy, sensitivity, specificity to human DNA, and ability to analyze challenging (e.g., mixed, degraded, or low quantity) samples. Intra- and inter-run replicates produced an average maximum pairwise difference in variant frequency of 1.2%. Concordance with data generated with traditional Sanger sequencing and an orthogonal MPS platform methodology was used to assess accuracy, and generation of complete and concordant haplotypes at DNA input levels as low as 37.5 pg of nuclear DNA or 187.5 mitochondrial genome copies illustrated the sensitivity of the system. Overall, data presented herein demonstrate that highly accurate and reproducible results were generated for a variety of sample qualities and quantities, supporting the reliability of this specific whole genome mitochondrial DNA MPS system for analysis of forensic biological evidence.
Highlights
The mitochondrial genome has a number of characteristics that make it useful for analyzing forensic biological evidence
Results are presented from a series of validation studies performed in accordance with Scientific Working Group on DNA Analysis Methods (SWGDAM) Validation Guidelines for Forensic DNA Analysis
Despite the number of nucleotide positions in some samples that reached the 20X read depth threshold used for analysis, the data presented opportunities to identify the presence of non-human
Summary
The mitochondrial genome (mtGenome) has a number of characteristics that make it useful for analyzing forensic biological evidence. Due to the workflow’s high cost and the labor demands involved in sequencing the entire mtGenome with this technology, laboratories generally have targeted the highly polymorphic control region. With the development and maturation of massively parallel sequencing (MPS) technologies [9,10,11,12,13,14,15,16,17,18,19], there is interest in enhancing mtDNA analysis, with some laboratories already tackling the validation and implementation process [20,21,22,23,24]. MPS provides an increase in sensitivity over currently-used CE-based technologies allowing for detection and characterization of lower-level heteroplasmies [20,24,25,26]
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