Abstract
The MET receptor tyrosine kinase is a pivotal regulator of cellular survival, motility, and proliferation. Mutations leading to skipping of exon 14 (METΔex14) within the juxtamembrane domain of MET impair receptor degradation and prolong oncogenic signaling, contributing significantly to tumor progression across multiple cancer types. METΔex14 mutations are associated with aggressive clinical behavior, therapeutic resistance, and poor outcomes. Next-generation sequencing from both tissue and liquid biopsies has significantly improved the detection frequency of METΔex14 in lung and other cancers. However, clinical trials targeting METΔex14 have rendered partial responses and mixed outcomes due to the lack of a comprehensive mechanistic understanding of METΔex14 regulation and a diverse mutational landscape. This review synthesizes current knowledge on the mechanistic basis of METΔex14-driven oncogenesis, including alterations in receptor dynamics, downstream signaling perturbations, genomic alterations underlying this mutation, and mechanisms of acquired therapeutic resistance. We further discuss the clinical implications of these insights and highlight future research directions essential for optimizing targeted therapies.