CLINCIAL VALIDATION OF APC AND TP53 AS BIOMARKERS FOR CETUXIMAB RESPONSE

PROJECT SUMMARY/ABSTRACT The objective of this combined UH2/UH3 application is to develop a cost-effective, rapid, test that can be rapidly translated to the clinic and ultimately be used to re-purpose a class of FDA-approved colorectal cancer (CRC) EGFR inhibitor (EGFRi) therapeutics (cetuximab and panitumumab). To date, only negative

genetic predictors (mutant KRAS/NRAS) of EGFRi response have been employed clinically, currently restricting EGFRi use to wild-type RAS/RAF subpopulations, and more recently, just to “left-sided” lesions. We recently reported a new prognostic role for APC that relates to the number of alleles mutated and to the

association with other mutant genes such as KRAS and TP53 (Nat Commun, 2016). Further analysis also revealed that mutant APC (A) genotypes, in combination with mutant TP53 (P), are strongly correlated with a gene expression signature measuring cetuximab sensitivity (CTX-S). These data led to the provocative

hypothesis that mutant APC + TP53 (AP) genotypes together---more so than either mutant gene alone (A_ / _P), or wild-type AP (_ _)---may have a new role in positively-predicting EGFRi outcomes (Nat Commun, Under Review, 2018). This hypothesis is based on 3 key observations we have recently made in our cohort

and in TCGA data: (1) CTX-S scores are significantly higher in: AP > A_ / _P > _ _ tumors in both WT and MUT KRAS tumors; (2) AP mutations are more frequent in Left (cetuximab-sensitive) > Right (cetuximab-resistant) CRC; (3) AP mutations are almost non-existent in MSI tumors (highly cetuximab-resistant).

These findings have two potentially high-impact clinical implications: (1) they re-define the patient selection strategy by further restricting EGFRi therapies to wild-type RAS/RAF patients harboring AP mutations, thereby increasing response rates; (2) they could expand the therapeutic opportunity to treat a substantial number of

previously-excluded mutant KRAS/NRAS patients who have AP mutations in both left and right CRCs. If the test for these mutations is developed and clinically validated, the utilization of these drugs could be expanded to ~25% more patients, including more first-line patients. For the vast majority of CRC patients, AP

mutations are not assessed in current practice. Unlike KRAS/NRAS oncogenes, both A and P are tumor suppressor genes that can have a multitude of inactivating mutations that must be detected. Thus, there is an opportunity to change clinical practice and standards of care to ultimately improve CRC outcomes with a new

test. In the LabCorp CAP/CLIA environment, we plan to develop a new highly sensitive, specific and cost-effective targeted DNA-sequencing “assay” to detect mutations in the coding regions of the principal genes APC, TP53, KRAS, BRAF, NRAS from formalin fixed paraffin embedded (FFPE) tissue samples.

In the UH2 Phase of this proposal, a new FFPE targeted DNA sequencing assay, with greater potential to accurately detect mutations at low allelic frequencies, will be analytically validated with the following approaches so that it can be offered in a CAP/CLIA laboratory for testing clinical samples:

(1) A variety of cell lines, both native and engineered, will be used to ensure analytic sensitivity, specificity, and reproducibility. (2) ~100 formalin fixed paraffin embedded (FFPE) samples of variable age, quality, tumor heterogeneity, grade, and stage matched to the highest quality, “gold standard” fresh frozen (FF) samples from the same

originating tumor will be used to assess assay performance. In the UH3 Phase, we plan to perform clinical validation of the test developed in the UH2 Phase to provide evidence that the presence of AP mutations may predict EGFRi responses translating into improved clinical outcomes. Here, we will demonstrate that assay of APC and TP53 genotypes along with those already

performed as SOC (KRAS/NRAS/BRAF) can be clinically validated (i.e. used to predict cetuximab sensitivity/response) using human samples derived from: (1) a retrospective CRC observational study relating CRC genetics to predicted cetuximab sensitivity. (2) a historical NCI trial (CALGB 80203) where patients were treated with cetuximab but were not sequenced.