Mechanical forces stimulate Golgi export

Human cells face a wide range of external mechanical stimuli that vary with cell type, state, and pathological conditions. The rapidly growing field of mechanobiology investigates how cells sense and respond to these forces. While most work has focused on focal adhesions (FAs), plasma membrane, and nucleus as primary mechanosensors, how reciprocal inside-out signals adapt intracellular organelles to extracellular mechanics has remained largely unexplored. Here, we show that extracellular mechanical signals influence the secretory function of the Golgi apparatus. By subjecting adherent cells to various mechanical challenges -cell spreading on surfaces coated with different ligands, altering substrate stiffness, or applying equibiaxial strains to the cells-, we reveal that extracellular forces modulate Golgi transport carrier biogenesis, thereby regulating exocytosis. Together with modulation of Golgi membrane tension, we identify molecular determinants of the underlying mechanotransduction pathway, including microtubule acetylation, diacylglycerol (DAG) production, and protein kinase D (PKD) activity. These findings uncover a bidirectional mechanotransduction axis in which extracellular mechanics tune Golgi secretory output, providing a framework for investigating organelle-based mechanoadaptation in physiology and disease, particularly in cancer and fibrosis where secretion is critical.