Force-producing ADP state of myosin bound to actin

Wulf, Sarah F.; Ropars, Virginie; Fujita‐Becker, Setsuko; Oster, Marco; Hofhaus, Götz; Trabuco, Leonardo G.; Pylypenko, Olena; Sweeney, H. Lee; Houdusse, Anne; Schröder, Rasmus R.

doi:10.1073/pnas.1516598113

Cited by 82 publications

(167 citation statements)

References 69 publications

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“…The first is a high-resolution (1.75Å) structure of myosin VI in a previously unseen state [5]. The second structure is an electron cryo-microscopy ( cryo-EM) structure of the actin-myosin-MgADP complex ( Strong ADP state ; see Figure 1, Key Figure) at 8Å [6]. A 4Å resolution cryo-EM structure of the actin-myosin interface at the end of the powerstroke ( Rigor state ) has also been provided [7].…”

Section: The Product Release Steps On Actinmentioning

confidence: 99%

How Myosin Generates Force on Actin Filaments

Houdusse

Sweeney

2016

Trends in Biochemical Sciences

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How myosin interacts with actin to generate force is a subject of considerable controversy. The major debate centers on understanding at what point in force generation the inorganic phosphate is released with respect to the lever arm swing, or powerstroke. Resolving the controversy is essential for understanding how force is produced as well as the mechanisms underlying disease-causing mutations in myosin. Recent structural insights on the powerstroke have come from a high-resolution structure of myosin in a previously unseen state and from an electron cryo-microscopy (cryo-EM) 3D reconstruction of the actin-myosin-MgADP complex. We argue that seemingly contradictory data from time-resolved Fluorescence Resonance Energy Transfer (FRET) studies can be reconciled and we put forward a model for myosin force generation on actin.

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Section: The Product Release Steps On Actinmentioning

confidence: 99%

How Myosin Generates Force on Actin Filaments

Houdusse

Sweeney

2016

Trends in Biochemical Sciences

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152

169

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“…A chemical reaction-coupled conformational change in the myosin head upon translation induces release of the head from the actin filament, and renders the translation irreversible. The system thereby uses a chemical trigger to rectify random thermal motion (7). The design principles of natural systems are today being used to develop a variety of molecular machines (8) and to achieve, experimentally, ratcheting of micrometer-sized particles (9), DNA (10), and cold atoms (11).…”

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confidence: 99%

Light-responsive organic flashing electron ratchet

Kedem

Lau

Ratner

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Ratchets are nonequilibrium devices that produce directional motion of particles from nondirectional forces without using a bias, and are responsible for many types of biological transport, which occur with high yield despite strongly damped and noisy environments. Ratchets operate by breaking time-reversal and spatial symmetries in the direction of transport through application of a time-dependent potential with repeating, asymmetric features. This work demonstrates the ratcheting of electrons within a highly scattering organic bulk-heterojunction layer, and within a device architecture that enables the application of arbitrarily shaped oscillating electric potentials. Light is used to modulate the carrier density, which modifies the current with a nonmonotonic response predicted by theory. This system is driven with a single unbiased sine wave source, enabling the future use of natural oscillation sources such as electromagnetic radiation.ratchet | nonequilibrium | charge transport | organic semiconductor B iological environments are noisy, chaotic, and highly damped (1). Transporting particles under those circumstances is a challenge, for which nature developed molecular motors, such as the myosin-actin system responsible for muscle contraction (2), the kinesin molecular walker (3), and ATP synthase (4). Such systems couple inherent structural asymmetries and relaxation with nondirectional sources of energy, like chemical energy, to obtain directional motion in the presence of strong damping and thermal noise through a mechanism called "ratcheting" (5, 6). For example, in the myosin-actin system, thermal fluctuations of the myosin head on an elastic tether lead to occasional binding of the head to an actin filament, at which point thermal energy is transduced to elastic energy, and the filaments translate relative to one another. A chemical reaction-coupled conformational change in the myosin head upon translation induces release of the head from the actin filament, and renders the translation irreversible. The system thereby uses a chemical trigger to rectify random thermal motion (7). The design principles of natural systems are today being used to develop a variety of molecular machines (8) and to achieve, experimentally, ratcheting of micrometer-sized particles (9), DNA (10), and cold atoms (11).The concept of an electron ratchet has been explored theoretically (12-14) and, in rare cases, experimentally (15-21). There are two major types of electron ratchets: "flashing," in which the electron moves along a periodic potential surface with locally asymmetric repeat units that oscillates between two states, while the source-drain bias along the direction of transport is constantly zero (5, 9); and "tilting," in which the shape of the potential surface remains constant, but the source-drain bias oscillates with a time average of zero (5). Fig. 1 shows a mechanism of transport in perhaps the simplest 1D flashing ratchet system, an "on/off" ratchet. Our interest lies in adapting the flashing ratchet mechanism t...

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“…Numerous experiments, including kinetics and thermodynamic studies (3), high-resolution structural studies (4), electron microscopy studies (5), atomic force microscopy (AFM), and singlemolecule experiments (2,6,7), have advanced our understanding of the action of the system. Although details about the dynamical nature of the myosin-V, along with a quantitative knowledge of the force-response, have been learned from single-molecule studies, the structural studies have provided us with an atomistic knowledge of the key conformational states involved during the cycle, namely, the lever-up (pre) and lever-down (post) states (Fig.…”

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Simulating the dynamics of the mechanochemical cycle of myosin-V

Mukherjee

Alhadeff

Warshel

2017

Proc. Natl. Acad. Sci. U.S.A.

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The detailed dynamics of the cycle of myosin-V are explored by simulation approaches, examining the nature of the energy-driven motion. Our study started with Langevin dynamics (LD) simulations on a very coarse landscape with a single rate-limiting barrier and reproduced the stall force and the hand-over-hand dynamics. We then considered a more realistic landscape and used timedependent Monte Carlo (MC) simulations that allowed trajectories long enough to reproduce the force/velocity characteristic sigmoidal correlation, while also reproducing the hand-over-hand motion. Overall, our study indicated that the notion of a downhill lever-up to lever-down process (popularly known as the powerstroke mechanism) is the result of the energetics of the complete myosin-V cycle and is not the source of directional motion or force generation on its own. The present work further emphasizes the need to use well-defined energy landscapes in studying molecular motors in general and myosin in particular.M yosin constitutes a superfamily of molecular motors comprising both the nonprocessive single-headed motors that are efficient in generating force on the actin filaments (e.g., myosin-II) and highly processive double-headed motors that can transport cellular load using tracks laid out by the cytoskeletal actin filaments (e.g., myosin-V, myosin-VI) (1, 2). The generation of force and unidirectional motion in each of the myosin molecules predominantly comprises tightly coupled events involving (i) binding and hydrolysis of ATP, followed by release of the products ADP and inorganic phosphate (P i ), occurring at the nucleotide-binding domain; (ii) binding and release of actin through the actin-binding domain; and (iii) a large conformational change of the lever arm that generates mechanical motion. Although the basic mechanochemical cycle is conserved in all members of the myosin superfamily, the exact nature of the coupling between the above steps in myosins, which decides the force-generating and load-bearing characteristics of different members, is unknown (SI Background).Numerous experiments, including kinetics and thermodynamic studies (3), high-resolution structural studies (4), electron microscopy studies (5), atomic force microscopy (AFM), and singlemolecule experiments (2, 6, 7), have advanced our understanding of the action of the system. Although details about the dynamical nature of the myosin-V, along with a quantitative knowledge of the force-response, have been learned from single-molecule studies, the structural studies have provided us with an atomistic knowledge of the key conformational states involved during the cycle, namely, the lever-up (pre) and lever-down (post) states (Fig. S1). In addition, crucial information has been gained on the kinetics of the chemical and ligand-binding/release steps that make up the complete cycle. Based on this experimental information, several theoretical modeling studies (8-17) explored the mechanochemical cycle, mostly using phenomenological modeling approaches, accompanied by s...

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Force-producing ADP state of myosin bound to actin

Cited by 82 publications

References 69 publications

How Myosin Generates Force on Actin Filaments

How Myosin Generates Force on Actin Filaments

Light-responsive organic flashing electron ratchet

Simulating the dynamics of the mechanochemical cycle of myosin-V

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