Abstract
Somatic mutations identified on genes related to the cancer-developing signaling pathways have drawn attention in the field of personalized medicine in recent years. Treatments developed to target a specific signaling pathway may not be effective when tumor activating mutations occur downstream of the target and bypass the targeted mechanism. For instance, mutations detected in KRAS/BRAF/NRAS genes can lead to EGFR-independent intracellular signaling pathway activation. Most patients with these mutations do not respond well to anti-EGFR treatment. In an effort to detect various mutations in FFPE tissue samples among multiple solid tumor types for patient stratification many mutation assays were evaluated. Since there were more than 30 specific mutations among three targeted RAS/RAF oncogenes that could activate MAPK pathway genes, a custom designed Single Nucleotide Primer Extension (SNPE) multiplexing mutation assay was developed and analytically validated as a clinical trial assay. Throughout the process of developing and validating the assay we overcame many technical challenges which include: the designing of PCR primers for FFPE tumor tissue samples versus normal blood samples, designing of probes for detecting consecutive nucleotide double mutations, the kinetics and thermodynamics aspects of probes competition among themselves and against target PCR templates, as well as validating an assay when positive control tumor tissue or cell lines with specific mutations are not available. We used Next Generation sequencing to resolve discordant calls between the SNPE mutation assay and Sanger sequencing. We also applied a triplicate rule to reduce potential false positives and false negatives, and proposed special considerations including pre-define a cut-off percentage for detecting very low mutant copies in the wild-type DNA background.
Highlights
Mutational status of solid tumors is becoming increasingly important for identifying the best treatment options for cancer patients [1]
Activating BRAF mutations have been documented in a variety of human cancers other than melanoma, such as,10% in colorectal cancer (CRC), approximately 50% in thyroid cancer [7], and several percent in non-small cell lung cancers (NSCLCs) [11]
KRAS, BRAF NRAS Single Nucleotide Primer Extension (SNPE) Mutation Detection Assay The KRAS, BRAF, NRAS SNPE (KBN-SNPE) mutation detection assay begins with the PCR amplification of regions of the KRAS, BRAF and NRAS genes from Genomic DNA (gDNA) isolated from one or two 5 mm mFFPE slide
Summary
Mutational status of solid tumors is becoming increasingly important for identifying the best treatment options for cancer patients [1]. It has been reported that activating mutations of RAS are identified in ,25% of all cancers [6] These mutations, especially in KRAS, are present at even higher rates in pancreatic cancer and colorectal cancer [3,6]. RAS mutations (HRAS, KRAS, or NRAS) have been identified in ,55–60% of thyroid cancers, and BRAF mutations have been identified in ,60% of malignant melanomas [5,9,10]. The high frequency of RAS or BRAF mutations in these cancers makes targeting this pathway an attractive strategy for new anti-cancer agent development that relies on a patient stratification to identify individuals most likely to benefit from MAPK inhibitors [12]
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