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Investigating nanostructure and -mechanics of contracting actin stress fibers by scanning ion conductance microscopy

Zhang, Y.; Takahashi, Y.; Lin, Y.-R.; Shevchuk, A.; Korchev, Y.; Franz, C. M.

2026-07-07 biophysics
10.64898/2026.07.01.735957 bioRxiv
Show abstract

Scanning ion conductance microscopy (SICM) provides gentle, non-contact cell surface imaging, but it has not been used to investigate intracellular structures because the plasma membrane restricts nanopipette access. Here, we combined SICM with microsonication-based cell de-roofing to expose intracellular actin stress fibers (SFs) in U2OS cells for nanotopographical and -mechanical characterization. Importantly, the de-roofing conditions preserved actomyosin contractility, allowing analysis of SF structural and biomechanical changes during ATP-induced contraction. Resting SFs displayed an average height of 203{+/-}38 nm and width of 357{+/-}73 nm, and a complex surface architecture characterized by regularly spaced long-range height modulations (~500 nm periodicity; Wq ~25 nm) and smaller irregular corrugations (Ra ~19.2 nm). ATP stimulation reduced SF height and width by ~39% and ~15%, respectively, while largely preserving surface corrugation patterns. During contraction, some SFs separated into two longitudinal strands. High-resolution SICM imaging also revealed filamentous crosslinks mechanically coupling neighboring SFs, and nanomechanical measurements demonstrated local stiffening during contraction. These findings provide new insight into the structural and mechanical regulation of SF contraction and highlight the potential of SICM combined with cell de-roofing as a powerful platform for studying dynamic intracellular processes at nanometer resolution.

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