Atonosomes, compartments involved in membrane tension decrease

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Abstract

To ensure survival, cells need to buffer the effects of environmental stress on their plasma membrane, yet the structural mechanisms by which this is acutely achieved remain largely unknown. Here, we propose atonosomes as a unifying identity for a class of previously observed but enigmatic, tension-responsive, plasma membrane-derived compartments that arise across contexts of acute and chronic membrane tension loss. Leveraging unprecedented high resolution cryo-FIB-ET imaging in yeast, we show that atonosomes are complex, organelle-containing structures bounded by membranes and cell wall material, spanning hundreds of nanometers, and displaying a remarkable morphological diversity. Atonosomes form within seconds in response to reduced plasma membrane tension, and their emergence appears to require no dedicated molecular machinery, arising instead as a direct consequence of membrane biophysics. Upon formation, they recruit key membrane-associated proteins, including TORC2, Slm1, and septins. Under conditions of chronic disruption of PM homeostasis, atonosomes become constitutively present. Their stability and reversibility are further modulated by the cell wall, whose polymerization state influences atonosome dynamics. Structural conservation in fungi and ichthyosporea, demonstrates that atonosomes are a conserved stress-triggered response of cell-wall enclosed organisms. Together, these findings establish atonosomes as a novel compartment that mediates cellular responses to plasma membrane tension variation, coupling membrane remodeling and lipid homeostasis to preserve cellular integrity under stress.

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