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1. Magttice: a lattice model for hard-magnetic soft materials

   https://doi.org/10.1039/D0SM01662D  

   Ye, Huilin; Li, Ying; Zhang, Teng (January 2021, Soft Matter)

   null (Ed.)

   Magnetic actuation has emerged as a powerful and versatile mechanism for diverse applications, ranging from soft robotics, biomedical devices to functional metamaterials. This highly interdisciplinary research calls for an easy to use and efficient modeling/simulation platform that can be leveraged by researchers with different backgrounds. Here we present a lattice model for hard-magnetic soft materials by partitioning the elastic deformation energy into lattice stretching and volumetric change, so-called ‘magttice’. Magnetic actuation is realized through prescribed nodal forces in magttice. We further implement the model into the framework of a large-scale atomic/molecular massively parallel simulator (LAMMPS) for highly efficient parallel simulations. The magttice is first validated by examining the deformation of ferromagnetic beam structures, and then applied to various smart structures, such as origami plates and magnetic robots. After investigating the static deformation and dynamic motion of a soft robot, the swimming of the magnetic robot in water, like jellyfish's locomotion, is further studied by coupling the magttice and lattice Boltzmann method (LBM). These examples indicate that the proposed magttice model can enable more efficient mechanical modeling and simulation for the rational design of magnetically driven smart structures. 

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2. Confocal microscopy observations of electrical pre-breakdown of bi-layer elastomer dielectrics

   https://doi.org/10.1016/j.eml.2021.101473  

   Charoen-Rajapark, Pavida; Clarke, David R. (November 2021, Extreme Mechanics Letters)

   At high electric fields, the electrical energy stored in a soft elastomer dielectric can be comparable to the mechanical deformation energy it produces. This has led to the development of a class of electrically controlled, large strain dielectric elastomer actuators for soft robotics and energy harvesting devices. At large electric fields, the electro-mechanically induced deformation can lead to pseudo-periodic surface morphological instabilities which then grow with increasing field into stable pre-breakdown defects prior to final, irreversible electrical breakdown. Under these extremes of combined large electrical and mechanical deformations, the morphological evolution of the prebreakdown defects has not hitherto been reported. In contrast to the filamentary breakdown of much stiffer dielectrics, fluorescence confocal microscopy reveals an array of defects that evolve through a complex, reversible series of morphologies, transitioning from axi-symmetric ‘‘pits’’ to ‘‘crack-like’’ shapes that can ‘‘twist’’ and deflect, and finally open to form an array of holes. The observations suggest that the transitions, from axi-symmetric pits to flat, slit-like defects and then to an array of holes, are geometric instabilities. The implications for using a soft elastomer layer to increase the dielectric breakdown of a stiffer dielectric are discussed. 

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3. pH-dependent 11° F1FO ATP synthase sub-steps reveal insight into the FO torque generating mechanism

   https://doi.org/10.7554/eLife.70016  

   Yanagisawa, Seiga; Frasch, Wayne D (December 2021, eLife)

   Most cellular ATP is made by rotary F 1 F O ATP synthases using proton translocation-generated clockwise torque on the F O c-ring rotor, while F 1 -ATP hydrolysis can force counterclockwise rotation and proton pumping. The F O torque-generating mechanism remains elusive even though the F O interface of stator subunit-a, which contains the transmembrane proton half-channels, and the c-ring is known from recent F 1 F O structures. Here, single-molecule F 1 F O rotation studies determined that the pKa values of the half-channels differ, show that mutations of residues in these channels change the pKa values of both half-channels, and reveal the ability of F O to undergo single c-subunit rotational stepping. These experiments provide evidence to support the hypothesis that proton translocation through F O operates via a Grotthuss mechanism involving a column of single water molecules in each half-channel linked by proton translocation-dependent c-ring rotation. We also observed pH-dependent 11° ATP synthase-direction sub-steps of the Escherichia coli c 10 -ring of F 1 F O against the torque of F 1 -ATPase-dependent rotation that result from H + transfer events from F O subunit-a groups with a low pKa to one c-subunit in the c-ring, and from an adjacent c-subunit to stator groups with a high pKa. These results support a mechanism in which alternating proton translocation-dependent 11° and 25° synthase-direction rotational sub-steps of the c 10 -ring occur to sustain F 1 F O ATP synthesis. 

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4. Nucleo-cytoskeletal coupling controls intracellular deformation partitioning during cell stretching

   https://doi.org/10.1098/rsos.250409  

   Chen, Jerry; Sloan, Iris; Bermudez, Alexandra; Choi, David; Tsai, Ming-Heng; Jin, Lihua; Hu, Jimmy K; Lin, Neil (July 2025, Royal Society Open Science)

   Cells sense and transduce mechanical forces to regulate diverse biological processes, yet the mechanical stimuli that initiate these processes remain poorly understood. In particular, how nuclear and cytoplasmic deformations respond to external forces is unclear. Here, we developed a microscopy-based technique to quantify the extensional uniaxial strains of the nucleus and cytoplasm during cell stretching, enabling direct measurement of their bulk mechanical responses. Using this approach, we identified a previously unrecognized inverse relationship between nuclear and cytoplasmic deformation in epithelial monolayers. We demonstrate that nucleo-cytoskeletal coupling, mediated by the Linker of Nucleoskeleton and Cytoskeleton (LINC) complex, regulates this anti-correlation (Pearson correlation coefficient approx. 0.3). Disrupting LINC abolished this relationship, revealing its fundamental role in intracellular deformation partitioning. Furthermore, we found that cytoplasmic deformation is directly correlated with stretch-induced nuclear shrinkage, suggesting a mechanotransduction pathway in which cytoplasmic mechanics influence nuclear responses. Lastly, multivariable analyses established that intracellular deformation can be inferred from cell morphology, providing a predictive framework for cellular mechanical behaviour. These findings refine our understanding of nucleo-cytoskeletal coupling in governing intracellular force transmission and mechanotransduction. 

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5. Viral packaging ATPases utilize a glutamate switch to couple ATPase activity and DNA translocation

   https://doi.org/10.1073/pnas.2024928118  

   Pajak, Joshua; Atz, Rockney; Hilbert, Brendan J.; Morais, Marc C.; Kelch, Brian A.; Jardine, Paul J.; Arya, Gaurav (April 2021, Proceedings of the National Academy of Sciences)

   Many viruses utilize ringed packaging ATPases to translocate double-stranded DNA into procapsids during replication. A critical step in the mechanochemical cycle of such ATPases is ATP binding, which causes a subunit within the motor to grip DNA tightly. Here, we probe the underlying molecular mechanism by which ATP binding is coupled to DNA gripping and show that a glutamate-switch residue found in AAA+ enzymes is central to this coupling in viral packaging ATPases. Using free-energy landscapes computed through molecular dynamics simulations, we determined the stable conformational state of the ATPase active site in ATP- and ADP-bound states. Our results show that the catalytic glutamate residue transitions from an active to an inactive pose upon ATP hydrolysis and that a residue assigned as the glutamate switch is necessary for regulating this transition. Furthermore, we identified via mutual information analyses the intramolecular signaling pathway mediated by the glutamate switch that is responsible for coupling ATP binding to conformational transitions of DNA-gripping motifs. We corroborated these predictions with both structural and functional experimental measurements. Specifically, we showed that the crystal structure of the ADP-bound P74-26 packaging ATPase is consistent with the structural coupling predicted from simulations, and we further showed that disrupting the predicted signaling pathway indeed decouples ATPase activity from DNA translocation activity in the φ29 DNA packaging motor. Our work thus establishes a signaling pathway that couples chemical and mechanical events in viral DNA packaging motors. 

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