AUTHOR=Osterlund Emerik , Ristimäki Ari , Kytölä Soili , Kuopio Teijo , Heervä Eetu , Muhonen Timo , Halonen Päivi , Kallio Raija , Soveri Leena-Maija , Sundström Jari , Keinänen Mauri , Ålgars Annika , Ristamäki Raija , Sorbye Halfdan , Pfeiffer Per , Nunes Luís , Salminen Tapio , Lamminmäki Annamarja , Mäkinen Markus J. , Sjöblom Tobias , Isoniemi Helena , Glimelius Bengt , Osterlund Pia 

TITLE=KRAS-G12C Mutation in One Real-Life and Three Population-Based Nordic Cohorts of Metastatic Colorectal Cancer

JOURNAL=Frontiers in Oncology

VOLUME=12

YEAR=2022

URL=https://www.frontiersin.org/journals/oncology/articles/10.3389/fonc.2022.826073

DOI=10.3389/fonc.2022.826073

ISSN=2234-943X

ABSTRACT=<sec><title>Background</title><p><italic>KRAS</italic> mutations, present in over 40% of metastatic colorectal cancer (mCRC), are negative predictive factors for anti-EGFR therapy. Mutations in <italic>KRAS-</italic>G12C have a cysteine residue for which drugs have been developed. Published data on this specific mutation are conflicting; thus, we studied the frequency and clinical characteristics in a real-world and population-based setting.</p></sec><sec><title>Methods</title><p>Patients from three Nordic population-based cohorts and the real-life RAXO-study were combined. <italic>RAS</italic> and <italic>BRAF</italic> tests were performed in routine healthcare, except for one cohort. The dataset consisted of 2,559 patients, of which 1,871 could be accurately classified as <italic>KRAS</italic>, <italic>NRAS</italic>, and <italic>BRAF</italic>-V600E. Demographics, treatments, and outcomes were compared using logistic regression. Overall survival (OS) was estimated with Kaplan–Meier, and differences were compared using Cox regression, adjusted for baseline factors.</p></sec><sec><title>Results</title><p>The <italic>KRAS-</italic>G12C frequency was 2%–4% of all tested in the seven cohorts (mean 3%) and 4%–8% of <italic>KRAS</italic> mutated tumors in the cohorts (mean 7%). Metastasectomies and ablations were performed more often (38% vs. 28%, p = 0.040), and bevacizumab was added more often (any line 74% vs. 59%, p = 0.007) for patients with <italic>KRAS-</italic>G12C- vs. other <italic>KRAS</italic>-mutated tumors, whereas chemotherapy was given to similar proportions. OS did not differ according to <italic>KRAS</italic> mutation, neither overall (adjusted hazard ratio (HR) 1.03; 95% CI 0.74–1.42, reference <italic>KRAS</italic>-G12C) nor within treatment groups defined as “systemic chemotherapy, alone or with biologics”, “metastasectomy and/or ablations”, or “best supportive care”, <italic>RAS</italic> and <italic>BRAF</italic> wild-type tumors (n = 548) differed similarly to <italic>KRAS</italic>-G12C, as to other <italic>KRAS</italic>- or <italic>NRAS</italic>-mutated (n = 66) tumors.</p></sec><sec><title>Conclusions</title><p>In these real-life and population-based cohorts, there were no significant differences in patient characteristics and outcomes between patients with <italic>KRAS-</italic>G12C tumors and those with other <italic>KRAS</italic> mutations. This contrasts with the results of most previous studies claiming differences in many aspects, often with worse outcomes for those with a <italic>KRAS-</italic>G12C mutation, although not consistent. When specific drugs are developed, as for this mutation, differences in outcome will hopefully emerge.</p></sec>