Processivity and Velocity for Motors Stepping on Periodic Tracks

AbstractProcessive molecular motors enable cargo transportation by assembling into dimers capable of taking several consecutive steps along a cytoskeletal filament. In the well-accepted hand-over-hand stepping mechanism the trailing motor detaches from the track and binds the filament again in leading position. This requires fuel consumption in the form of ATP hydrolysis, and coordination of the catalytic cycles between the leading and the trailing heads. However, alternative stepping mechanisms exist, including inchworm-like movements, backward steps, and foot stomps. Whether all of these pathways are coupled to ATP hydrolysis remains to be determined. Here, in order to establish the principles governing the dynamics of processive movement, we present a theoretical framework which includes all of the alternative stepping mechanisms. Our theory bridges the gap between the elemental rates describing the biochemical and structural transitions in each head, and the experimentally measurable quantities, such as velocity, processivity, and probability of backward stepping. Our results, obtained under the assumption that the track is periodic and infinite, provide expressions which hold regardless of the topology of the network connecting the intermediate states, and are therefore capable of describing the function of any molecular motor. We apply the theory to myosin VI, a motor that takes frequent backward steps, and moves forward with a combination of hand-over-hand and inchworm-like steps. Our model reproduces quantitatively various observables of myosin VI motility measured experimentally from two groups. The theory is used to predict the gating mechanism, the pathway for backward stepping, and the energy consumption as a function of ATP concentration.Significance StatementMolecular motors harness the energy released by ATP hydrolysis to transport cargo along cytoskeletal filaments. The two identical heads in the motor step alternatively on the polar track by communicating with each other. Our goal is to elucidate how the coordination between the two heads emerges from the catalytic cycles. To do so, we created a theoretical framework that allows us to relate the measurable features of motility, such as motor velocity, with the biochemical rates in the leading and trailing heads, thereby connecting biochemical activity and motility. We illustrate the efficacy of the theory by analyzing experimental data for myosin VI, which takes frequent backward steps, and moves forward by a hand-over-hand and inchworm-like steps.

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Molecular motors: forty years of interdisciplinary research

Molecular Biology of the Cell ◽

10.1091/mbc.e11-05-0447 ◽

2011 ◽

Vol 22 (21) ◽

pp. 3936-3939 ◽

Cited By ~ 10

Author(s):

James A. Spudich

Keyword(s):

Single Molecule ◽

Molecular Motors ◽

Atp Hydrolysis ◽

Molecular Motor ◽

Single Molecule Level ◽

In Vitro Motility ◽

Nonmuscle Cell ◽

Nonmuscle Cells ◽

City Plan

A mere forty years ago it was unclear what motor molecules exist in cells that could be responsible for the variety of nonmuscle cell movements, including the “saltatory cytoplasmic particle movements” apparent by light microscopy. One wondered whether nonmuscle cells might have a myosin-like molecule, well known to investigators of muscle. Now we know that there are more than a hundred different molecular motors in eukaryotic cells that drive numerous biological processes and organize the cell's dynamic city plan. Furthermore, in vitro motility assays, taken to the single-molecule level using techniques of physics, have allowed detailed characterization of the processes by which motor molecules transduce the chemical energy of ATP hydrolysis into mechanical movement. Molecular motor research is now at an exciting threshold of being able to enter into the realm of clinical applications.

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Step-wise Hydration of Magnesium by Four Water Molecules Precedes Phosphate Release in a Myosin Motor

10.1101/817254 ◽

2019 ◽

Author(s):

M.L. Mugnai ◽

D. Thirumalai

Keyword(s):

Molecular Motors ◽

Atp Hydrolysis ◽

Structural Similarity ◽

Nucleotide Binding ◽

Binding Pocket ◽

Water Molecules ◽

Myosin Vi ◽

Phosphate Release ◽

Myosin Motors ◽

Dynamics Simulations

AbstractMolecular motors, such as myosin, kinesin, and dynein, convert the energy released by the hydrolysis of ATP into mechanical work, which allows them to undergo directional motion on cytoskeletal tracks. This process is achieved through synchronization between the catalytic activity of the motor and the associated changes in its conformation. A pivotal step in the chemomechanical transduction in myosin motors occurs after they bind to the actin filament, which triggers the release of phosphate (Pi, product of ATP hydrolysis) and the rotation of the lever arm. Here, we investigate the mechanism of phosphate release in myosin VI, which has been debated for over two decades, using extensive molecular dynamics simulations involving multiple trajectories each several μs long. Because the escape of phosphate is expected to occur on time-scales on the order of milliseconds in myosin VI, we observed Pi release only if the trajectories were initiated with a rotated phosphate inside the nucleotide binding pocket. The rotation provided the needed perturbation that enabled successful expulsions of Pi in several trajectories. Analyses of these trajectories lead to a robust mechanism of Pi release in the class of motors belonging to the myosin super family. We discovered that although Pi populates the traditional “back door” route, phosphate exits through various other gateways, thus establishing the heterogeneity in the escape routes. Remarkably, we observe that the release of phosphate is preceded by a step-wise hydration of the ADP-bound magnesium ion. In particular, the release of the anion occurred only after four water molecules hydrate the cation (Mg2+). By performing comparative structural analyses, we suggest that the hydration of magnesium is the key step in the phosphate release in a number of ATPases and GTPases that share a similar structure in the nucleotide binding pocket. Thus, nature may have evolved hydration of Mg2+ by discrete water molecules as a general molecular switch for Pi release, which is a universal step in the catalytic cycle of many machines which share little sequence or structural similarity.

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Temperature-Dependent Activity of Motor Proteins: Energetics and Their Implications for Collective Behavior

Frontiers in Cell and Developmental Biology ◽

10.3389/fcell.2021.610899 ◽

2021 ◽

Vol 9 ◽

Author(s):

Saumya Yadav ◽

Ambarish Kunwar

Keyword(s):

Single Molecule ◽

Molecular Motors ◽

Intracellular Transport ◽

Motor Proteins ◽

Atp Hydrolysis ◽

Molecular Motor ◽

Surrounding Medium ◽

Biochemical Properties ◽

Cellular Transport ◽

Temperature Dependent

Molecular motor proteins are an extremely important component of the cellular transport system that harness chemical energy derived from ATP hydrolysis to carry out directed mechanical motion inside the cells. Transport properties of these motors such as processivity, velocity, and their load dependence have been well established through single-molecule experiments. Temperature dependent biophysical properties of molecular motors are now being probed using single-molecule experiments. Additionally, the temperature dependent biochemical properties of motors (ATPase activity) are probed to understand the underlying mechanisms and their possible implications on the enzymatic activity of motor proteins. These experiments in turn have revealed their activation energies and how they compare with the thermal energy available from the surrounding medium. In this review, we summarize such temperature dependent biophysical and biochemical properties of linear and rotary motor proteins and their implications for collective function during intracellular transport and cellular movement, respectively.

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A model of processive walking and slipping of kinesin-8 molecular motors

Scientific Reports ◽

10.1038/s41598-021-87532-0 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Ping Xie

Keyword(s):

Single Molecule ◽

Molecular Motors ◽

External Load ◽

Molecular Motor ◽

Velocity Versus ◽

Stick Slip ◽

Load Dependence ◽

Chemomechanical Coupling ◽

Similarities And Differences ◽

Stick Slip Motion

AbstractKinesin-8 molecular motor can move with superprocessivity on microtubules towards the plus end by hydrolyzing ATP molecules, depolymerizing microtubules. The available single molecule data for yeast kinesin-8 (Kip3) motor showed that its superprocessive movement is frequently interrupted by brief stick–slip motion. Here, a model is presented for the chemomechanical coupling of the kinesin-8 motor. On the basis of the model, the dynamics of Kip3 motor is studied analytically. The analytical results reproduce quantitatively the available single molecule data on velocity without including the slip and that with including the slip versus external load at saturating ATP as well as slipping velocity versus external load at saturating ADP and no ATP. Predicted results on load dependence of stepping ratio at saturating ATP and load dependence of velocity at non-saturating ATP are provided. Similarities and differences between dynamics of kinesin-8 and that of kinesin-1 are discussed.

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A FRET-Based Sensor Reveals Large ATP Hydrolysis–Induced Conformational Changes and Three Distinct States of the Molecular Motor Myosin

Cell ◽

10.1016/s0092-8674(00)00090-8 ◽

2000 ◽

Vol 102 (5) ◽

pp. 683-694 ◽

Cited By ~ 105

Author(s):

William M Shih ◽

Zygmunt Gryczynski ◽

Joseph R Lakowicz ◽

James A Spudich

Keyword(s):

Conformational Changes ◽

Atp Hydrolysis ◽

Molecular Motor

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Molecular motors--a paradigm for mutant analysis

Journal of Cell Science ◽

10.1242/jcs.113.8.1311 ◽

2000 ◽

Vol 113 (8) ◽

pp. 1311-1318 ◽

Cited By ~ 1

Author(s):

S.A. Endow

Keyword(s):

Molecular Motors ◽

Protein Function ◽

Rational Design ◽

Atp Hydrolysis ◽

Unique Property ◽

Genetic Screens ◽

Nucleotide Hydrolysis ◽

Mutant Analysis ◽

Motor Activities ◽

Natural Variants

Molecular motors perform essential functions in the cell and have the potential to provide insights into the basis of many important processes. A unique property of molecular motors is their ability to convert energy from ATP hydrolysis into work, enabling the motors to bind to and move along cytoskeletal filaments. The mechanism of energy conversion by molecular motors is not yet understood and may lead to the discovery of new biophysical principles. Mutant analysis could provide valuable information, but it is not obvious how to obtain mutants that are informative for study. The analysis presented here points out several strategies for obtaining mutants by selection from molecular or genetic screens, or by rational design. Mutants that are expected to provide important information about the motor mechanism include ATPase mutants, which interfere with the nucleotide hydrolysis cycle, and uncoupling mutants, which unlink basic motor activities and reveal their interdependence. Natural variants can also be exploited to provide unexpected information about motor function. This general approach to uncovering protein function by analysis of informative mutants is applicable not only to molecular motors, but to other proteins of interest.

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Molecular Motors: Force and Movement Generated by Single Myosin II Molecules

Physiology ◽

10.1152/nips.01389.2002 ◽

2002 ◽

Vol 17 (5) ◽

pp. 213-218 ◽

Cited By ~ 3

Author(s):

Caspar Rüegg ◽

Claudia Veigel ◽

Justin E. Molloy ◽

Stephan Schmitz ◽

John C. Sparrow ◽

...

Keyword(s):

Optical Tweezers ◽

Single Molecule ◽

Molecular Motors ◽

Molecular Motor ◽

Myosin Ii ◽

Force Production ◽

Myosin Isoforms ◽

Single Molecule Level ◽

Recent Developments ◽

Muscle Myosin

Muscle myosin II is an ATP-driven, actin-based molecular motor. Recent developments in optical tweezers technology have made it possible to study movement and force production on the single-molecule level and to find out how different myosin isoforms may have adapted to their specific physiological roles.

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Molecular mechanisms for microtubule length regulation by kinesin-8 and XMAP215 proteins

Interface Focus ◽

10.1098/rsfs.2014.0031 ◽

2014 ◽

Vol 4 (6) ◽

pp. 20140031 ◽

Cited By ~ 16

Author(s):

Louis Reese ◽

Anna Melbinger ◽

Erwin Frey

Keyword(s):

Molecular Motors ◽

Molecular Mechanisms ◽

Molecular Motor ◽

Mutual Exclusion ◽

High Growth ◽

Dependent Manner ◽

Dynamic Regulation ◽

Filament Dynamics ◽

Length Regulation ◽

The Stability

The cytoskeleton is regulated by a plethora of enzymes that influence the stability and dynamics of cytoskeletal filaments. How microtubules (MTs) are controlled is of particular importance for mitosis, during which dynamic MTs are responsible for proper segregation of chromosomes. Molecular motors of the kinesin-8 protein family have been shown to depolymerize MTs in a length-dependent manner, and recent experimental and theoretical evidence suggests a possible role for kinesin-8 in the dynamic regulation of MTs. However, so far the detailed molecular mechanisms of how these molecular motors interact with the growing MT tip remain elusive. Here we show that two distinct scenarios for the interactions of kinesin-8 with the MT tip lead to qualitatively different MT dynamics, including accurate length control as well as intermittent dynamics. We give a comprehensive analysis of the regimes where length regulation is possible and characterize how the stationary length depends on the biochemical rates and the bulk concentrations of the various proteins. For a neutral scenario, where MTs grow irrespective of whether the MT tip is occupied by a molecular motor, length regulation is possible only for a narrow range of biochemical rates, and, in particular, limited to small polymerization rates. By contrast, for an inhibition scenario, where the presence of a motor at the MT tip inhibits MT growth, the regime where length regulation is possible is extremely broad and includes high growth rates. These results also apply to situations where a polymerizing enzyme like XMAP215 and kinesin-8 mutually exclude each other from the MT tip. Moreover, we characterize the differences in the stochastic length dynamics between the two scenarios. While for the neutral scenario length is tightly controlled, length dynamics is intermittent for the inhibition scenario and exhibits extended periods of MT growth and shrinkage. On a broader perspective, the set of models established in this work quite generally suggest that mutual exclusion of molecules at the ends of cytoskeletal filaments is an important factor for filament dynamics and regulation.

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Active and Unidirectional Acceleration of Biaryl Rotation by a Molecular Motor

10.26434/chemrxiv.10048871.v1 ◽

2019 ◽

Author(s):

Edgar Uhl ◽

Peter Mayer ◽

Henry Dube

Keyword(s):

Potential Energy ◽

Motor Unit ◽

Rate Constants ◽

Molecular Motors ◽

Molecular Motor ◽

Molecular Machine ◽

Single Bond ◽

Bond Rotation ◽

Immense Potential

Light driven molecular motors possess immense potential as central driving units for future nanotechnology. Integration into larger molecular setups and transduction of their mechanical motions represents the current frontier of research. Here we report on an integrated molecular machine setup allowing to transmit potential energy from a motor unit unto a remote receiving entity. The setup consists of a motor unit connected covalently to a distant and sterically strongly encumbered biaryl receiver. By action of the motor unit single bond rotation of the receiver is strongly accelerated and forced to proceed unidirectionally. The transmitted potential energy is directly measured as the extent to which energy degeneration is lifted in the thermal atropisomerization of this biaryl. Energy degeneracy is reduced by as much as 2.3 kcal/mol and rate accelerations up to 2x105 fold in terms of rate constants are achieved.

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Positional isomers of a non-nucleoside substrate differentially affect myosin function

10.1101/2019.12.17.879809 ◽

2019 ◽

Author(s):

M. Woodward ◽

E. Ostrander ◽

S.P. Jeong ◽

X. Liu ◽

B. Scott ◽

...

Keyword(s):

Energy Source ◽

Muscle Contraction ◽

Motor Function ◽

Molecular Motors ◽

Molecular Motor ◽

Vesicular Transport ◽

Gain Control ◽

Mechanical Work ◽

Chemical Energy ◽

Muscle Myosin

AbstractMolecular motors have evolved to transduce chemical energy from adenosine triphosphate into mechanical work to drive essential cellular processes, from muscle contraction to vesicular transport. Dysfunction of these motors is a root cause of many pathologies necessitating the need for intrinsic control over molecular motor function. Herein, we demonstrate that positional isomerism can be used as a simple and powerful tool to control the molecular motor of muscle, myosin. Using three isomers of a synthetic non-nucleoside triphosphate we demonstrate that myosin’s force and motion generating capacity can be dramatically altered at both the ensemble and single molecule levels. By correlating our experimental results with computation, we show that each isomer exerts intrinsic control by affecting distinct steps in myosin’s mechano-chemical cycle. Our studies demonstrate that subtle variations in the structure of an abiotic energy source can be used to control the force and motility of myosin without altering myosin’s structure.Statement of SignificanceMolecular motors transduce chemical energy from ATP into the mechanical work inside a cell, powering everything from muscle contraction to vesicular transport. While ATP is the preferred source of energy, there is growing interest in developing alternative sources of energy to gain control over molecular motors. We synthesized a series of synthetic compounds to serve as alternative energy sources for muscle myosin. Myosin was able to use this energy source to generate force and velocity. And by using different isomers of this compound we were able to modulate, and even inhibit, the activity of myosin. This suggests that changing the isomer of the substrate could provide a simple, yet powerful, approach to gain control over molecular motor function.

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