0100495939

open access

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Mechanical control of osteoclast fusion by membrane-cortex attachment and BAR proteins

English (英語)

Journal of Cell Biology

224(7)

e202411024

The Rockefeller University Press

2025-05-08

2025-05-27

Osteoclasts are multinucleated giant cells that are formed by the fusion of precursor cells. Cell–cell fusion is mediated by membrane protrusion driven by actin reorganization, but the role of membrane mechanics in this process is unknown. Utilizing live-cell imaging, optical tweezers, manipulation of membrane-to-cortex attachment (MCA), and genetic interference, we show that a decrease in plasma membrane (PM) tension is a mechanical prerequisite for osteoclast fusion. Upon RANKL-induced differentiation, ezrin expression in fusion progenitor cells is reduced, resulting in a decrease in MCA-dependent PM tension. A forced elevation of PM tension by reinforcing the MCA conversely suppresses cell–cell fusion. Mechanistically, reduced PM tension leads to membrane protrusive invadosome formation driven by membrane curvature-inducing/sensing BAR proteins, thereby promoting cell–cell fusion. These findings provide insights into the mechanism of cell–cell fusion under the control of membrane mechanics.

Membrane and lipid biology

学術雑誌論文

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