BRAF- and MEK-targeted therapies are effective in BRAFV600E/K metastatic melanoma and lung cancers; however, responses are short-lived due to emergence of resistance.
Technical advance in targeted NGS analysis enables identification of lung cancer risk-associated low frequency TP53, PIK3CA, and BRAF mutations in airway epithelial cells.
These results indicate that AZ628 has greater potential than Dabrafenib, both as a single agent and combined with Trametinib, for the treatment of non-V600 BRAF mutant lung cancer.
Economic analysis of BRAF gene mutation testing in real world practice using claims data: costs of single gene versus panel tests in patients with lung cancer.
A group of thoracic oncology experts in the field of thoracic oncology met to describe the standard for biomarker testing for lung cancer in the Canadian context, focusing on evidence-based recommendations for standard-of-care testing for <i>EGFR</i>, anaplastic lymphoma kinase (<i>ALK</i>), <i>ROS1</i>, <i>BRAF V600</i> and programmed death-ligand (PD-L1) at the time of diagnosis of advanced disease and <i>EGFR T790M</i> upon progression.
Accordingly, the combination of MEK inhibitor with EGFR inhibitor was effective at shrinking tumors in mouse model of BRAF non-V600E mutant lung cancer.
One of our predicted biomarker pairs, a mutation in the BRAF gene and upregulated expression of the PIM1 gene, was experimentally validated to benefit from a therapy combining BRAF inhibitor and PIM1 inhibitor in lung cancer.
Our clinical data suggest that BRAF mutations define specific subsets of patients with NSCLC; while their oncogenic nature is yet to be established in lung cancer, especially for non-V600E mutations, the value of BRAF mutations to predict the efficacy of targeted agents remains unclear.
BRAF mutants with impaired or unknown kinase activity as well as concomitant kinase-impaired BRAF mutations and RAS mutations were detected in lung cancers, colorectal cancers and melanomas.
The three most common BRAF mutations in lung cancers accounted for only 41% of the observed BRAF mutations (p.D594G [18%], p.V600E [14%], and p.G469A [9%]).
BRAF fusions included 3% (14/531) of melanomas; 2% (15/701) of gliomas; 1.0% (3/294) of thyroid cancers; 0.3% (3/1,062) pancreatic carcinomas; 0.2% (8/4,013) nonsmall-cell lung cancers and 0.2% (4/2,154) of colorectal cancers, and were enriched in pilocytic (30%) vs. nonpilocytic gliomas (1%; p < 0.0001), Spitzoid (75%) vs. nonSpitzoid melanomas (1%; p = 0.0001), acinar (67%) vs. nonacinar pancreatic cancers (<1%; p < 0.0001) and papillary (3%) vs. nonpapillary thyroid cancers (0%; p < 0.03).
Recent evidence shows that BRAF-activated non-coding RNA (BANCR) acts as a critical role in the proliferation and metastasis in malignant melanoma and lung cancer; however, little is known about the significance of lncRNA BANCR in retinoblastoma.