61 Tumor mutational burden assessments by two commercial targeted sequencing assays

61 Tumor mutational burden assessments by two commercial targeted sequencing assays

BackgroundTumor mutational burden (TMB) is a key biomarker for immune checkpoint inhibitor across several cancer types. While TMB as calculated from whole exome sequencing of the tumor tissue is still the gold standard, enabling TMB in clinical labs requires targeted sequencing panels for faster tur...

Full description

Saved in:
Bibliographic Details
Published in:Journal for immunotherapy of cancer Vol. 8; no. Suppl 3; p. A38
Main Authors: Chaudhary, Ruchi, Vaidya, Gitanjali, Sunil, Meeta, Sakthivel Murugan, SM, Ramprasad, VL, Gupta, Ravi, Stawiski, Eric
Format: Journal Article
Language:English
Published: London BMJ Publishing Group LTD 01-11-2020
BMJ Publishing Group
Subjects:
Immunotherapy
Large intestine
Mutation
Oral cancer
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:BackgroundTumor mutational burden (TMB) is a key biomarker for immune checkpoint inhibitor across several cancer types. While TMB as calculated from whole exome sequencing of the tumor tissue is still the gold standard, enabling TMB in clinical labs requires targeted sequencing panels for faster turnaround time and low input requirements. Herein, we assess two commercially available, targeted sequencing (research-use-only) TMB assays for the possibility of offering in the Medgenome labs.MethodsTwo assays, Oncomine Tumor Mutation Load Assay (or Oncomine) by Thermo Fisher Scientific and QIAseq Tumor Mutational Burden Panel (or QIAseq) by Qiagen, were studied. One negative control (NA12878), five positive control (A549, lung; T47D, breast; SKMEL2, skin; HCT-15, large intestine; HCT116, large intestine) cell lines, and 18 FFPE (13 colon, 1 lung, 1 testicular, and 1 oral cancer; 2 healthy) samples were ran on both assays. Sample QC was performed through measuring DNA fragmentation on TapeStation and concentration on Qubit. Failure rates on FFPE samples were investigated. TMB values by both assays were compared on all samples, as well as with expected TMB on cell line samples. Expected TMB on the negative control was considered zero; expected TMB for positive cell lines was calculated by restricting somatic mutations (from cBioPortal.com) to each panel, normalizing by panel size, and averaging. TMB values of 3 samples with known MSI were evaluated and signature patterns of relatively high TMB samples were studied.ResultsOn cell line samples, high correlation (r2 = 0.9994) was observed between TMB values by both assays. TMB values were consistently zero on negative control by both assays. Both assays estimated lower than expected TMB on positive control samples. 6/18 FFPE samples failed on both assays, with Oncomine’s error mode was high deamination (i.e., number of C:G>T:A mutations at low allelic frequency) and QIAseq’s was low confidence (i.e., < 0.9 Mb sequenced panel). All 6 failed samples showed either low DNA integrity (DIN<2) or low concentration (<6 ng/µl). A combined analysis of all QC pass samples showed high correlation (r2 = 0.97) between two assays. TMB values on two MSI cell lines was > 50 by both assays, but 14 by QIAseq and 33 by Oncomine on one MSI FFPE sample. Four out of five FFPE samples with > 25 TMB by both assays displayed MSI signature patterns from COSMIC or incorporated a pathogenic mutation in MLH1 gene.ConclusionsPreliminary analyses showed comparative accuracy and failure rates on FFPE samples. Future analyses will aim at comparison with WES based TMB on reference cell line and FFPE material.
ISSN:2051-1426
DOI:10.1136/jitc-2020-SITC2020.0061