Mechanical confinement induces ferroptosis through mitochondrial dysfunction

Cells exist in highly crowded environments where they are exposed to fluctuating mechanical forces arising from surrounding cells and the extracellular matrix microenvironment. In these settings, external forces are transmitted to intracellular organelles including the nucleus. While cells can survive confinement, extended duration of confinement or confinement in settings where cells are unable to escape, can result in cell death. How cells sense and respond to prolonged confinement to trigger cell death remains unclear. Here, we demonstrate that nuclear deformation generated by axial confinement triggers the programmed cell death pathway – ferroptosis. We show that axial confinement results in Drp1-dependent mitochondrial fragmentation and cPLA2 translocation to mitochondria, where Drp1 undergoes acute phase separation. Ensuing mitochondrial ROS accumulation and arachidonic acid production concertedly leads to lipid peroxidation evoking ferroptosis. Finally, of clinical relevance, we find that in human osteoarthritis tissue cPLA2 exhibits mitochondrial localization and high ROS levels. Together, our findings unveil a pivotal role for Drp1 and cPLA2 in linking mechanical confinement with mitochondrial dysfunction resulting in ferroptosis, which sheds new light on a mechanical mechanism of pathophysiology in osteoarthritis. ### Competing Interest Statement The authors have declared no competing interest.