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1. Effect of F-actin and Microtubules on Cellular Mechanical Behavior Studied Using Atomic Force Microscope and an Image Recognition-Based Cytoskeleton Quantification Approach

   https://doi.org/10.3390/ijms21020392  

   Liu, Yi; Mollaeian, Keyvan; Shamim, Muhammad Huzaifah; Ren, Juan (January 2020, International Journal of Molecular Sciences)

   Cytoskeleton morphology plays a key role in regulating cell mechanics. Particularly, cellular mechanical properties are directly regulated by the highly cross-linked and dynamic cytoskeletal structure of F-actin and microtubules presented in the cytoplasm. Although great efforts have been devoted to investigating the qualitative relation between the cellular cytoskeleton state and cell mechanical properties, comprehensive quantification results of how the states of F-actin and microtubules affect mechanical behavior are still lacking. In this study, the effect of both F-actin and microtubules morphology on cellular mechanical properties was quantified using atomic force microscope indentation experiments together with the proposed image recognition-based cytoskeleton quantification approach. Young’s modulus and diffusion coefficient of NIH/3T3 cells with different cytoskeleton states were quantified at different length scales. It was found that the living NIH/3T3 cells sense and adapt to the F-actin and microtubules states: both the cellular elasticity and poroelasticity are closely correlated to the depolymerization degree of F-actin and microtubules at all measured indentation depths. Moreover, the significance of the quantitative effects of F-actin and microtubules in affecting cellular mechanical behavior is depth-dependent. 

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2. Investigation of the Effect of Substrate Morphology on MDCK Cell Mechanical Behavior Using Atomic Force Microscopy

   Mollaeian, Keyvan; Liu, Yi; Bi, Siyu; and Ren, Juan. (August 2019, Applied physics letters)

   Living cells sense and respond to their extracellular environment. Their contact guidance is affected by the underlying substrate morphology. Previous studies of the effect of substrate pattern on the mechanical behavior of living cells were only limited to the quantification of the cellular elasticity. However, how the length and time scales of the cellular mechanical properties are affected by the patterned substrates have yet to be studied. In this study, the effect of the substrate morphology on the biomechanical behavior of living cells was thoroughly investigated using indentation-based atomic force microscopy. The results showed that the cellular biomechanical behavior was affected by the substrate morphology significantly. The elasticity and viscosity of the cells on the patterned PDMS substrates were much lower compared to those cultured on flat PDMS. The poroelastic diffusion coefficient of the cells was higher on the patterned PDMS substrates, specifically on the substrate with 2D pitches. In addition, fluorescence images showed that the substrate topography directly affects the cell cytoskeleton morphology. Together, the results suggested that cell mechanical behavior and morphology can be controlled using substrates with properly designed topography. 

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3. Epithelial cells sense local stiffness via Piezo1 mediated cytoskeletal reorganization

   https://doi.org/10.3389/fcell.2023.1198109  

   Jetta, Deekshitha; Shireen, Tasnim; Hua, Susan Z. (May 2023, Frontiers in Cell and Developmental Biology)

   Local substrate stiffness is one of the major mechanical inputs for tissue organization during its development and remodeling. It is widely recognized that adherent cells use transmembrane proteins (integrins) at focal adhesions to translate ECM mechanical cues into intracellular bioprocess. Here we show that epithelial cells respond to substrate stiffening primarily via actin cytoskeleton organization, that requires activation of mechanosensitive Piezo1 channels. Piezo1 Knockdown cells eliminated the actin stress fibers that formed on stiff substrates, while it had minimal effect on cell morphology and spreading area. Inhibition of Piezo1 channels with GsMTx4 also significantly reduced stiffness-induced F-actin reorganization, suggesting Piezo1 mediated cation current plays a role. Activation of Piezo1 channels with specific agonist (Yoda1) resulted in thickening of F-actin fibers and enlargement of FAs on stiffer substrates, whereas it did not affect the formation of nascent FAs that facilitate spreading on the soft substrates. These results demonstrate that Piezo1 functions as a force sensor that couples with actin cytoskeleton to distinguish the substrate stiffness and facilitate epithelial adaptive remodeling. 

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4. Mechanical characterization of Xenopus laevis oocytes using atomic force microscopy

   https://doi.org/10.1016/j.jmbbm.2024.106648  

   Kardashina, Tatiana; Serrano, Elba E; Dawson, John A; Drach, Borys (September 2024, Journal of the Mechanical Behavior of Biomedical Materials)

   Mechanical properties are essential for the biological activities of cells, and they have been shown to be affected by diseases. Therefore, accurate mechanical characterization is important for studying the cell lifecycle, cell-cell interactions, and disease diagnosis. While the cytoskeleton and actin cortex are typically the primary structural stiffness contributors in most live cells, oocytes possess an additional extracellular layer known as the vitelline membrane (VM), or envelope, which can significantly impact their overall mechanical properties. In this study, we utilized nanoindentation via an atomic force microscope to measure the Young's modulus of Xenopus laevis oocytes at different force setpoints and explored the influence of the VM by conducting measurements on oocytes with the membrane removed. The findings revealed that the removal of VM led to a significant decrease in the apparent Young's modulus of the oocytes, highlighting the pivotal role of the VM as the main structural component responsible for the oocyte's shape and stiffness. Furthermore, the mechanical behavior of VM was investigated through finite element (FE) simulations of the nanoindentation process. FE simulations with the VM Young's modulus in the range 20–60 MPa resulted in force-displacement curves that closely resemble experimental in terms of shape and maximum force for a given indentation depth. 

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5. Actin Bundle Nanomechanics and Organization Are Modulated by Macromolecular Crowding and Electrostatic Interactions

   https://doi.org/10.3389/fmolb.2021.760950  

   Castaneda, Nicholas; Feuillie, Cecile; Molinari, Michael; Kang, Ellen Hyeran (November 2021, Frontiers in Molecular Biosciences)

   The structural and mechanical properties of actin bundles are essential to eukaryotic cells, aiding in cell motility and mechanical support of the plasma membrane. Bundle formation occurs in crowded intracellular environments composed of various ions and macromolecules. Although the roles of cations and macromolecular crowding in the mechanics and organization of actin bundles have been independently established, how changing both intracellular environmental conditions influence bundle mechanics at the nanoscale has yet to be established. Here we investigate how electrostatics and depletion interactions modulate the relative Young’s modulus and height of actin bundles using atomic force microscopy. Our results demonstrate that cation- and depletion-induced bundles display an overall reduction of relative Young’s modulus depending on either cation or crowding concentrations. Furthermore, we directly measure changes to cation- and depletion-induced bundle height, indicating that bundles experience alterations to filament packing supporting the reduction to relative Young’s modulus. Taken together, our work suggests that electrostatic and depletion interactions may act counteractively, impacting actin bundle nanomechanics and organization. 

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