Melanoma is the leading cause of death from skin cancer. Many patients develop metastatic disease that spreads to other parts of the body. One commonly used targeted therapy for metastatic melanomas works by attacking melanomas with mutations in the BRAF gene that make them susceptible to RAF-inhibiting drugs. However, many cancers quickly become resistant to the treatment. Now researchers at the NCI-designated Sidney Kimmel Cancer Center—Jefferson Health have discovered how one of the mechanisms of that resistance works, a finding that could lead to designing more effective combination therapies.
“The findings give us new clues about how we might combat resistance to this targeted melanoma therapy,” said Andrew Aplin, Ph.D., Associate Director for Basic Research and the Program Leader for Cancer Cell Biology and Signaling (CCBS) at the Sidney Kimmel Cancer Center. The research was published November 6th in Cell Reports.
About 13-30 percent of melanomas become resistant to RAF-inhibiting drugs because of a difference in how those cells produce and process the BRAF protein. The gene these patients carry is called a BRAF V600E isoform. These RAF-resistant isoform cancers produce BRAF proteins that become active complexes with another cancer-promoting protein called MEK.
Dr. Aplin, together with first author Michael Vido, an MD/PHD student in Dr. Aplin’s lab and colleagues, showed that when they blocked this complex, or dimerization, by targeting a specific site on the BRAF isoform, they could block MEK binding and restore the potency of the RAF-inhibitor.
“The work helps explain dual hypotheses for RAF-inhibitor resistance, one which focused on MEK and the other on dimerization,” said Dr. Aplin. “This work weaves the two together mechanistically. The results may also help guide the design of better combination therapies for melanoma.”
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