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1. Encapsulation of the cytoskeleton: towards mimicking the mechanics of a cell

   https://doi.org/10.1039/C9SM01669D  

   Bashirzadeh, Yashar; Liu, Allen P. (October 2019, Soft Matter)

   The cytoskeleton of a cell controls all the aspects of cell shape changes and motility from its physiological functions for survival to reproduction to death. The structure and dynamics of the cytoskeletal components: actin, microtubules, intermediate filaments, and septins – recently regarded as the fourth member of the cytoskeleton family – are conserved during evolution. Such conserved and effective control over the mechanics of the cell makes the cytoskeletal components great candidates for in vitro reconstitution and bottom-up synthetic biology studies. Here, we review the recent efforts in reconstitution of the cytoskeleton in and on membrane-enclosed biomimetic systems and argue that co-reconstitution and synergistic interplay between cytoskeletal filaments might be indispensable for efficient mechanical functionality of active minimal cells. Further, mechanical equilibrium in adherent eukaryotic cells is achieved by the formation of integrin-based focal contacts with extracellular matrix (ECM) and the transmission of stresses generated by actomyosin contraction to ECM. Therefore, a minimal mimic of such balance of forces and quasi-static kinetics of the cell by bottom-up reconstitution requires a careful construction of contractile machineries and their link with adhesive contacts. In this review, in addition to cytoskeletal crosstalk, we provide a perspective on reconstruction of cell mechanical equilibrium by reconstitution of cortical actomyosin networks in lipid membrane vesicles adhered on compliant substrates and also discuss future perspectives of this active research area. 

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2. Protocells Capable of Generating a Cytoskeleton‐Like Structure from Intracellular Membrane‐Active Artificial Organelles

   https://doi.org/10.1002/adfm.202306904  

   Wang, Dishi; Moreno, Silvia; Gao, Mengfei; Guo, Jiaqi; Xu, Bing; Voigt, Dagmar; Voit, Brigitte; Appelhans, Dietmar (December 2023, Advanced Functional Materials)

   Abstract The intricate nature of eukaryotic cells with intracellular compartments having differences in component concentration and viscosity in their lumen provides (membrane‐active) enzymes to trigger time‐ and concentration‐dependent processes in the intra‐/extracellular matrix. Herein, membrane‐active, enzyme‐loaded artificial organelles (AOs) are capitalized upon to develop fluidic and stable proteinaceous membrane‐based protocells. AOs in protocells induce the self‐assembly of oligopeptides into an artificial cytoskeleton that underlines their influence on the structure and functionality of protocells. A series of microscopical tools is used to validate the intracellular assembly and distribution of cytoskeleton, the changing protocells morphology, and AOs inclusion within cytoskeletal growth. Thus, the dynamics, diffusion, and viscosity of intracellular components in the presence of cytoskeleton are evaluated by fluorescence tools and enzymatic assay. Membrane‐active alkaline phosphatase in polymersomes as AOs fulfills the requirements of biomimetic eukaryotic cells to trigger intracellular environment, mobility, viscosity, diffusion, and enzymatic activity itself as well as high mechanical stability and high membrane fluidity of protocells. Thus membrane‐active AOs in protocells provide a variable reaction space in a changing intracellular environment and underline their regulatory role in the fabrication of complex protocell architectures and functions. This study contributes significantly to the effective biomimetics of cell‐like structures, shapes, and functions. 

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3. Emergent Surface Tension in Active Membranes Under Area Constraint

   https://doi.org/10.1115/1.4071531  

   Hassan, Rubayet; Vo, Anh; Farokhirad, Samaneh; Ahmadpoor, Fatemeh (March 2026, Journal of Applied Mechanics)

   Abstract Biological membranes operate far from equilibrium due to the continuous activity of embedded proteins that generate forces and curvature stresses. These nonequilibrium processes alter membrane mechanics, yet the connection between microscopic activity and emergent properties such as surface tension remains unclear. Here, we develop a combined theoretical and computational framework to study an active fluid membrane under a fixed projected area constraint. Using a statistical mechanical formulation based on Helfrich curvature elasticity, we derive the fluctuation spectrum of a membrane driven by temporally correlated active forces and determine the effective surface tension self-consistently from excess-area conservation. Two modes of activity are examined: direct normal forces and curvature-generating spontaneous curvature. Coarse-grained molecular dynamics simulations with a solvent-free membrane model validate the theoretical predictions. Activity enhances long-wavelength fluctuations and renormalizes membrane mechanics: direct forces significantly increase effective surface tension, while curvature-driven activity primarily redistributes excess area with smaller tension changes. Short-wavelength fluctuations remain bending dominated. These results quantitatively link microscopic protein activity to emergent membrane mechanics, providing insight into how active processes regulate membrane stability and morphology. 

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4. Renormalized Mechanics and Stochastic Thermodynamics of Growing Vesicles

   https://doi.org/10.1103/qxn3-xx5n  

   Shivers, Jordan L; Nguyen, Michael; Dinner, Aaron R; Vlahovska, Petia M; Vaikuntanathan, Suriyanarayanan (January 2026, PRX Life)

   Uncovering the rules governing the nonequilibrium dynamics of the membranes that define biological cells is of central importance to understanding the physics of living systems. We theoretically and computationally investigate the behavior of flexible quasispherical vesicles that exchange membrane constituents, internal volume, and heat with an external reservoir. The excess chemical potential and osmotic pressure difference imposed by the reservoir act as generalized thermodynamic driving forces that modulate vesicle morphology. We show that the renormalization of membrane mechanical properties by nonequilibrium driving gives rise to a morphological transition between a weakly driven regime, in which growing vesicles remain quasispherical, and a strongly driven regime, in which vesicles accommodate rapid membrane uptake by developing surface wrinkles. Additionally, we propose a minimal vesicle growth-shape law, derived using insights from stochastic thermodynamics, that robustly describes vesicle growth dynamics even in strongly driven, far-from-equilibrium regimes. 

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5. Myosin II tension sensors visualize force generation within the actin cytoskeleton in living cells

   https://doi.org/10.1242/jcs.262281  

   Hart, Ryan G; Kota, Divya; Li, Fangjia; Zhang, Mengdi; Ramallo, Diego; Price, Andrew J; Otterpohl, Karla L; Smith, Steve J; Dunn, Alexander R; Huising, Mark O; et al (October 2024, Journal of Cell Science)

   ABSTRACT Nonmuscle myosin II (NMII) generates cytoskeletal forces that drive cell division, embryogenesis, muscle contraction and many other cellular functions. However, at present there is no method that can directly measure the forces generated by myosins in living cells. Here, we describe a Förster resonance energy transfer (FRET)-based tension sensor that can detect myosin-associated force along the filamentous actin network. Fluorescence lifetime imaging microscopy (FLIM)-FRET measurements indicate that the forces generated by NMII isoform B (NMIIB) exhibit significant spatial and temporal heterogeneity as a function of donor lifetime and fluorophore energy exchange. These measurements provide a proxy for inferred forces that vary widely along the actin cytoskeleton. This initial report highlights the potential utility of myosin-based tension sensors in elucidating the roles of cytoskeletal contractility in a wide variety of contexts. 

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