Dissecting cell membrane tension dynamics and its effect on Piezo1-mediated cellular mechanosensitivity using force-controlled nanopipettes.
Ines LüchtefeldIgor V PivkinLucia GardiniElaheh Zare-EelanjeghChristoph GäbeleinStephan J IhleAndreas M ReichmuthMarco CapitanioBoris MartinacTomaso ZambelliMassimo VassalliPublished in: Nature methods (2024)
The dynamics of cellular membrane tension and its role in mechanosensing, which is the ability of cells to respond to physical stimuli, remain incompletely understood, mainly due to the lack of appropriate tools. Here, we report a force-controlled nanopipette-based method that combines fluidic force microscopy with fluorescence imaging for precise manipulation of the cellular membrane tension while monitoring the impact on single-cell mechanosensitivity. The force-controlled nanopipette enables control of the indentation force imposed on the cell cortex as well as of the aspiration pressure applied to the plasma membrane. We show that this setup can be used to concurrently monitor the activation of Piezo1 mechanosensitive ion channels via calcium imaging. Moreover, the spatiotemporal behavior of the tension propagation is assessed with the fluorescent membrane tension probe Flipper-TR, and further dissected using molecular dynamics modeling. Finally, we demonstrate that aspiration and indentation act independently on the cellular mechanobiological machinery, that indentation induces a local pre-tension in the membrane, and that membrane tension stays confined by links to the cytoskeleton.
Keyphrases
- single molecule
- molecular dynamics
- single cell
- fluorescence imaging
- atomic force microscopy
- high resolution
- living cells
- induced apoptosis
- mental health
- oxidative stress
- quantum dots
- density functional theory
- cell therapy
- photodynamic therapy
- mesenchymal stem cells
- ultrasound guided
- rna seq
- signaling pathway
- cell cycle arrest
- bone marrow
- cell death
- optical coherence tomography
- endoplasmic reticulum stress