Lysosomal accumulation of Masitinib alters autophagy via pH-dependent trapping.

Small-molecule kinase inhibitors often exhibit complex cellular behaviors that cannot be explained solely by target inhibition. Masitinib is a clinically investigated tyrosine kinase inhibitor with reported anti-inflammatory and neuroprotective effects, yet its intracellular mechanism of action remains poorly defined. Here, we show that masitinib undergoes pH-dependent lysosomal sequestration that dominates its cellular activity. Across multiple cell lines, masitinib suppresses mTORC1 signaling while paradoxically inducing AKT phosphorylation through a VPS34 and rapamycin-sensitive pathway independent of class I PI3K. Thermal proteome profiling identifies lysosomal proteins as the primary off-target signature of masitinib. Using defined membrane model systems that recapitulate lysosomal lipid composition and acidity, we demonstrate that masitinib preferentially accumulates and intercalates into acidic, negatively charged membranes. This lysosomal accumulation impairs lysosomal acidification and disrupts autophagic flux, providing a mechanistic link between the physicochemical properties of masitinib and its downstream signaling effects. Together, our findings highlight lysosomal sequestration as a key determinant of kinase inhibitor behavior and underlie the importance of subcellular drug distribution in modulating cellular responses. • Masitinib alters mTROC1 and AKT signaling. • Lysosomal proteins are a primary off-target signature of masitinib. • Masitinib undergoes lysosomal trapping in a pH-dependent manner. • Masitinib alters lysosome acidification and autophagic flux.