Fragmentation assessment of FFPE DNA helps in evaluating NGS library complexity and interpretation of NGS results.

Formalin-fixed paraffin-embedded (FFPE) tissue remains the most common source for DNA extraction from human tissue both in research and routine clinical practice. FFPE DNA can be considerably fragmented, and the amount of DNA measured in nanograms may not represent the amount of amplifiable DNA available for next-generation sequencing (NGS). Two samples with similar input DNA amounts in nanograms can yield NGS analyses of considerably different quality. Nevertheless, many protocols for NGS library preparation from FFPE DNA describe input DNA in nanograms without indication of a minimum requirement of amplifiable genome equivalent DNA. An important NGS quality metric is the library complexity, reflecting the number of DNA fragments from the original specimen represented in the final library. Aiming to illustrate the relationship between DNA fragmentation degree and library complexity, we assessed the fragmentation degree of 116 lung cancer FFPE DNA samples to calculate the amount of amplifiable input DNA used for library preparation. Mean unique coverage, coverage uniformity, and mean number of PCR duplicates with the same unique molecular identifier were used to evaluate library complexity. We showed that the amount of amplifiable input DNA predicted library complexity better than the input measured in nanograms. The frequent discrepancy between DNA amount in nanograms and the amount of amplifiable DNA indicate that the fragmentation degree should be considered when performing NGS of FFPE DNA. Importantly, the fragmentation assessment may help when interpreting NGS data and be a useful tool for evaluating library complexity in the absence of unique molecular identifiers.

Prognostic value of absolute quantification of mutated KRAS in circulating tumour DNA in lung adenocarcinoma patients prior to therapy.

Droplet digital polymerase chain reaction (ddPCR) is a highly sensitive and accurate method for quantification of nucleic acid sequences. We used absolute quantification of mutated v-Ki-ras2 Kirsten rat sarcoma viral oncogene homology gene (KRAS) by ddPCR to investigate the prognostic role of mutated KRAS in patients with KRAS-mutated lung adenocarcinomas. Pre-treatment plasma samples from 60 patients with stages I-IV KRAS-mutated lung adenocarcinomas were analysed for KRAS mutations. The associations between survival, detectable KRAS mutations in plasma, and the plasma concentration of mutated KRAS were assessed. Overall, 23 of 60 (38%) patients had detectable KRAS mutation in plasma. The percentage of patients with detectable mutation was 8% in stage I, 30% in stage II, 71% in stage III, and 73% in stage IV. Estimated overall median progression-free survival (PFS) and overall survival (OS) were 26.2 months [95% confidence interval (CI) 12.5-39.9] and 50.8 months (95% CI 0-107.3), respectively. Patients with detectable mutations in plasma had significantly worse median PFS compared to patients with undetectable mutation (13.1 versus 70.1 months) and shorter median OS (20.7 versus not reached). High circulating tumour DNA (ctDNA) concentrations of mutated KRAS were significantly associated with shorter PFS [hazard ratio (HR) 1.008, 95% CI 1.004-1.012] and OS (HR 1.007, 95% CI 1.003-1.011). All associations remained statistically significant in multivariable analyses. In conclusion, ddPCR is an accurate and easily feasible technique for quantification of KRAS mutations in ctDNA. The presence of detectable KRAS mutation in plasma at baseline was associated with worse PFS and OS. High concentration of mutated KRAS in ctDNA was an independent negative prognostic factor for both PFS and OS.