Nonequilibrium Fluctuations and Mechanochemical Couplings of a Molecular Motor

Lau, Andy T. Y.; Lacoste, David; Mallick, Kirone

doi:10.1103/physrevlett.99.158102

Cited by 97 publications

(173 citation statements)

References 30 publications

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“…Moreover, it goes beyond similar relations obtained for genuine diffusive spatial transport [9,10] since we require no Euclidean metric and hence the notion of a locally co-moving frame is not available. Our results will therefore be applicable not only to any discrete model for a molecular motor or ion pump (see, e.g., [11][12][13][14] and references therein) but also to driven (bio)chemical reaction networks and their response to changing chemical conditions [15,16]. As a simple illustration will show, a misguided rewriting of our additive relationship between mobility and dispersion in terms of a multiplicative "effective temperature" could easily lead even to negative values for the latter as found for various active biomolecular systems, see, e.g., [17,18].…”

Section: Institut Für Theoretische Physik Universität Stuttgartmentioning

confidence: 99%

“…As one example consider the observation made in [11] for a particular two state motor model that at stalling conditions, j = 0 at f = f s , the usual Einstein relation between mobility and diffusion constant holds true, even though idle chemical currents dissipate energy. Our expressions (6), (13) and (14) show that, in general, the validity of the Einstein relation requires not only that j = 0 but moreover that any link carrying a non-zero probability current K mn be not sensitive to the force f , i.e.…”

Section: Institut Für Theoretische Physik Universität Stuttgartmentioning

confidence: 99%

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Generalized Einstein or Green-Kubo Relations for Active Biomolecular Transport

Seifert

2010

Phys. Rev. Lett.

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For driven Markovian dynamics on a network of (biomolecular) states, the generalized mobilities, i.e., the response of any current to changes in an external parameter, are expressed by an integral over an appropriate current-current correlation function and thus related to the generalized diffusion constants. As only input, a local detailed balance condition is required typically even valid for biomolecular systems operating deep in the non-equilibrium regime.

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Section: Institut Für Theoretische Physik Universität Stuttgartmentioning

confidence: 99%

Section: Institut Für Theoretische Physik Universität Stuttgartmentioning

confidence: 99%

Generalized Einstein or Green-Kubo Relations for Active Biomolecular Transport

Seifert

2010

Phys. Rev. Lett.

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“…The model can be simplified by merging the states corresponding to a kinesin head strongly bound to the MT (states K and KT in Fig 11 -state KDP has a too short lifetime to be considered) and those where the kinesin head diffuses freely along the MT (state KD). This results into a two-state 6 model [181,276,219] that already captures important features of the stepping cycle.…”

Section: Mechanochemical Cycle Of Molecular Motorsmentioning

confidence: 99%

“…A theoretical frame for fluctuation analysis has been provided in [219]. Due to the generic non-equilibrium features of the motor dynamics, generalized fluctuation theorems have to be applied where the Einstein and Onsager relations are violated.…”

Section: Mechanochemical Cycle Of Molecular Motorsmentioning

confidence: 99%

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Intracellular transport driven by cytoskeletal motors: General mechanisms and defects

2015

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Cells are the elementary units of living organisms, which are able to carry out many vital functions. These functions rely on active processes on a microscopic scale. Therefore, they are strongly out-of-equilibrium systems, which are driven by continuous energy supply. The tasks that have to be performed in order to maintain the cell alive require transportation of various ingredients, some being small, others being large. Intracellular transport processes are able to induce concentration gradients and to carry objects to specific targets. These processes cannot be carried out only by diffusion, as cells may be crowded, and quite elongated on molecular scales. Therefore active transport has to be organized.The cytoskeleton, which is composed of three types of filaments (microtubules, actin and intermediate filaments), determines the shape of the cell, and plays a role in cell motion. It also serves as a road network for a special kind of vehicles, namely the cytoskeletal motors. These molecules can attach to a cytoskeletal filament, perform directed motion, possibly carrying along some cargo, and then detach.It is a central issue to understand how intracellular transport driven by molecular motors is regulated. The interest for this type of question was enhanced when it was discovered that intracellular transport breakdown is one of the signatures of some neuronal diseases like the Alzheimer.We give a survey of the current knowledge on microtubule based intracellular transport. Our review includes on the one hand an overview of biological facts, obtained from experiments, and on the other hand a presentation of some modeling attempts based on cellular automata. We present some background knowledge on the original and variants of the TASEP (Totally Asymmetric Simple Exclusion Process), before turning to more application oriented models. After addressing microtubule based transport in general, with a focus on in vitro experiments, and on cooperative effects in the transportation of large cargos by multiple motors, we concentrate on axonal transport, because of its relevance for neuronal diseases. Some important characteristics of axonal transport is that it takes place in a confined environment; Besides several types of motors are involved, that move in opposite directions. It is a challenge to understand how this bidirectional transport is organized. We review several features that could contribute to the efficiency of bidirectional transport in the axon, including in particular the role of motor-motor interactions and of the dynamics of the underlying microtubule network. Finally, we also discuss some open questions that may be relevant for future research in this field.

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Fluctuation Theorem, Nonequilibrium Work, and Molecular Machines

Gaspard

2010

From Non‐Covalent Assemblies to Molecular Machines

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Nonequilibrium Fluctuations and Mechanochemical Couplings of a Molecular Motor

Cited by 97 publications

References 30 publications

Generalized Einstein or Green-Kubo Relations for Active Biomolecular Transport

Generalized Einstein or Green-Kubo Relations for Active Biomolecular Transport

Intracellular transport driven by cytoskeletal motors: General mechanisms and defects

Fluctuation Theorem, Nonequilibrium Work, and Molecular Machines

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