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1. Emergence of traveling waves and their stability in a free boundary model of cell motility

   https://doi.org/10.1090/tran/8824  

   Rybalko, Volodymyr; Berlyand, Leonid (March 2023, Transactions of the American Mathematical Society)

   We consider a 2D free boundary model of cell motility, inspired by the 1D contraction-driven cell motility model due to P. Recho, T. Putelat, and L. Truskinovsky [Phys. Rev. Lett. 111 (2013), p. 108102]. The key ingredients of the model are the Darcy law for overdamped motion of the acto-myosin network, coupled with the advection-diffusion equation for myosin density. These equations are supplemented with the Young-Laplace equation for the pressure and no-flux condition for the myosin density on the boundary, while evolution of the boundary is subject to the acto-myosin flow at the edge. The focus of the work is on stability analysis of stationary solutions and translationally moving traveling wave solutions. We study stability of radially symmetric stationary solutions and show that at some critical radius a pitchfork bifurcation occurs, resulting in emergence of a family of traveling wave solutions. We perform linear stability analysis of these latter solutions with small velocities and reveal the type of bifurcation (sub- or supercritical). The main result of this work is an explicit asymptotic formula for the stability determining eigenvalue in the limit of small traveling wave velocities. 

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2. On the role of myosin-induced actin depolymerization during cell migration

   https://doi.org/10.1091/mbc.E22-10-0494  

   Yao, Lingxing; Mori, Yoichiro; Sun, Sean X.; Li, Yizeng (May 2023, Molecular Biology of the Cell)

   Mogilner, Alex (Ed.)

   Mammalian cell migration in open spaces requires F-actin polymerization and myosin contraction. While many studies have focused on myosin’s coupling to focal adhesion and stress fibers, the indirect effect of myosin contraction on cell migration through actin depolymerization is not well studied. In this work, we quantified how cell velocity and effective power output are influenced by the rate of actin depolymerization, which is affected by myosin contraction. In addition, we derived scaling laws to provide physical insights into cell migration. Model analysis shows that the cell migration velocity displays a biphasic dependence on the rate of actin depolymerization and myosin contraction. Our model further predicts that the effective cell energy output depends not only on the cell velocity but also on myosin contractility. The work has implications on in vivo processes such as immune response and cancer metastasis, where cells overcome barriers imposed by the physical environment. 

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3. The structural and functional effects of myosin regulatory light chain phosphorylation are amplified by increases in sarcomere length and [Ca ²⁺ ]

   https://doi.org/10.1113/JP286802  

   Turner, Kyrah L; Vander_Top, Blake J; Kooiker, Kristina B; Mohran, Saffie; Mandrycky, Christian; McMillen, Tim; Regnier, Michael; Irving, Thomas C; Ma, Weikang; Tanner, Bertrand CW (October 2024, The Journal of Physiology)

   AbstractPrecise regulation of sarcomeric contraction is essential for normal cardiac function. The heart must generate sufficient force to pump blood throughout the body, but either inadequate or excessive force can lead to dysregulation and disease. Myosin regulatory light chain (RLC) is a thick‐filament protein that binds to the neck of the myosin heavy chain. Post‐translational phosphorylation of RLC (RLC‐P) by myosin light chain kinase is known to influence acto‐myosin interactions, thereby increasing force production and Ca²⁺‐sensitivity of contraction. Here, we investigated the role of RLC‐P on cardiac structure and function as sarcomere length and [Ca²⁺] were altered. We found that at low, non‐activating levels of Ca²⁺, RLC‐P contributed to myosin head disorder, though there were no effects on isometric stress production and viscoelastic stiffness. With increases in sarcomere length and Ca²⁺‐activation, the structural changes due to RLC‐P become greater, which translates into greater force production, greater viscoelastic stiffness, slowed myosin detachment rates and altered nucleotide handling. Altogether, these data suggest that RLC‐P may alter thick‐filament structure by releasing ordered, off‐state myosin. These more disordered myosin heads are available to bind actin, which could result in greater force production as Ca²⁺levels increase. However, prolonged cross‐bridge attachment duration due to slower ADP release could delay relaxation long enough to enable cross‐bridge rebinding. Together, this work further elucidates the effects of RLC‐P in regulating muscle function, thereby promoting a better understanding of thick‐filament regulatory contributions to cardiac function in health and disease.image Key pointsMyosin regulatory light chain (RLC) is a thick‐filament protein in the cardiac sarcomere that can be phosphorylated (RLC‐P), and changes in RLC‐P are associated with cardiac dysfunction and disease.This study assesses how RLC‐P alters cardiac muscle structure and function at different sarcomere lengths and calcium concentrations.At low, non‐activating levels of Ca²⁺, RLC‐P contributed to myofilament disorder, though there were no effects on isometric stress production and viscoelastic stiffness.With increases in sarcomere length and Ca²⁺‐activation, the structural changes due to RLC‐P become greater, which translates into greater force production, greater viscoelastic stiffness, slower myosin detachment rate and altered cross‐bridge nucleotide handling rates.This work elucidates the role of RLC‐P in regulating muscle function and facilitates understanding of thick‐filament regulatory protein contributions to cardiac function in health and disease. 

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4. 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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5. Cardiac myosin binding protein-C phosphorylation accelerates β-cardiac myosin detachment rate in mouse myocardium

   https://doi.org/10.1152/ajpheart.00673.2020  

   Tanner, Bertrand C.; Previs, Michael J.; Wang, Yuan; Robbins, Jeffrey; Palmer, Bradley M. (May 2021, American Journal of Physiology-Heart and Circulatory Physiology)

   null (Ed.)

   Cardiac myosin binding protein-C (cMyBP-C) is a thick filament protein that influences sarcomere stiffness and modulates cardiac contraction-relaxation through its phosphorylation. Phosphorylation of cMyBP-C and ablation of cMyBP-C have been shown to increase the rate of MgADP release in the acto-myosin cross-bridge cycle in the intact sarcomere. The influence of cMyBP-C on Pi-dependent myosin kinetics has not yet been examined. We investigated the effect of cMyBP-C, and its phosphorylation, on myosin kinetics in demembranated papillary muscle strips bearing the β-cardiac myosin isoform from nontransgenic and homozygous transgenic mice lacking cMyBP-C. We used quick stretch and stochastic length-perturbation analysis to characterize rates of myosin detachment and force development over 0–12 mM Pi and at maximal (pCa 4.8) and near-half maximal (pCa 5.75) Ca 2+ activation. Protein kinase A (PKA) treatment was applied to half the strips to probe the effect of cMyBP-C phosphorylation on Pi sensitivity of myosin kinetics. Increasing Pi increased myosin cross-bridge detachment rate similarly for muscles with and without cMyBP-C, although these rates were higher in muscle without cMyBP-C. Treating myocardial strips with PKA accelerated detachment rate when cMyBP-C was present over all Pi, but not when cMyBP-C was absent. The rate of force development increased with Pi in all muscles. However, Pi sensitivity of the rate force development was reduced when cMyBP-C was present versus absent, suggesting that cMyBP-C inhibits Pi-dependent reversal of the power stroke or stabilizes cross-bridge attachment to enhance the probability of completing the power stroke. These results support a functional role for cMyBP-C in slowing myosin detachment rate, possibly through a direct interaction with myosin or by altering strain-dependent myosin detachment via cMyBP-C-dependent stiffness of the thick filament and myofilament lattice. PKA treatment reduces the role for cMyBP-C to slow myosin detachment and thus effectively accelerates β-myosin detachment in the intact myofilament lattice. NEW & NOTEWORTHY Length perturbation analysis was used to demonstrate that β-cardiac myosin characteristic rates of detachment and recruitment in the intact myofilament lattice are accelerated by Pi, phosphorylation of cMyBP-C, and the absence of cMyBP-C. The results suggest that cMyBP-C normally slows myosin detachment, including Pi-dependent detachment, and that this inhibition is released with phosphorylation or absence of cMyBP-C. 

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