IDEAS home Printed from https://ideas.repec.org/a/wly/jnlaaa/v2008y2008i1n241736.html

Stokes Efficiency of Molecular Motor‐Cargo Systems

Author

Listed:
  • Hongyun Wang
  • Hong Zhou

Abstract

A molecular motor utilizes chemical free energy to generate a unidirectional motion through the viscous fluid. In many experimental settings and biological settings, a molecular motor is elastically linked to a cargo. The stochastic motion of a molecular motor‐cargo system is governed by a set of Langevin equations, each corresponding to an individual chemical occupancy state. The change of chemical occupancy state is modeled by a continuous time discrete space Markov process. The probability density of a motor‐cargo system is governed by a two‐dimensional Fokker‐Planck equation. The operation of a molecular motor is dominated by high viscous friction and large thermal fluctuations from surrounding fluid. The instantaneous velocity of a molecular motor is highly stochastic: the past velocity is quickly damped by the viscous friction and the new velocity is quickly excited by bombardments of surrounding fluid molecules. Thus, the theory for macroscopic motors should not be applied directly to molecular motors without close examination. In particular, a molecular motor behaves differently working against a viscous drag than working against a conservative force. The Stokes efficiency was introduced to measure how efficiently a motor uses chemical free energy to drive against viscous drag. For a motor without cargo, it was proved that the Stokes efficiency is bounded by 100% [H. Wang and G. Oster, (2002)]. Here, we present a proof for the general motor‐cargo system.

Suggested Citation

  • Hongyun Wang & Hong Zhou, 2008. "Stokes Efficiency of Molecular Motor‐Cargo Systems," Abstract and Applied Analysis, John Wiley & Sons, vol. 2008(1).
  • Handle: RePEc:wly:jnlaaa:v:2008:y:2008:i:1:n:241736
    DOI: 10.1155/2008/241736
    as

    Download full text from publisher

    File URL: https://doi.org/10.1155/2008/241736
    Download Restriction: no

    File URL: https://libkey.io/10.1155/2008/241736?utm_source=ideas
    LibKey link: if access is restricted and if your library uses this service, LibKey will redirect you to where you can use your library subscription to access this item
    ---><---

    References listed on IDEAS

    as
    1. Hongyun Wang & George Oster, 1998. "Energy transduction in the F1 motor of ATP synthase," Nature, Nature, vol. 396(6708), pages 279-282, November.
    2. Koen Visscher & Mark J. Schnitzer & Steven M. Block, 1999. "Single kinesin molecules studied with a molecular force clamp," Nature, Nature, vol. 400(6740), pages 184-189, July.
    3. Timothy Elston & Hongyun Wang & George Oster, 1998. "Energy transduction in ATP synthase," Nature, Nature, vol. 391(6666), pages 510-513, January.
    Full references (including those not matched with items on IDEAS)

    Most related items

    These are the items that most often cite the same works as this one and are cited by the same works as this one.
    1. Carlos G. Rodellar & José M. Gisbert-Gonzalez & Francisco Sarabia & Beatriz Roldan Cuenya & Sebastian Z. Oener, 2024. "Ion solvation kinetics in bipolar membranes and at electrolyte–metal interfaces," Nature Energy, Nature, vol. 9(5), pages 548-558, May.
    2. Xuejiao Zhang & Jin Zeng & Jason C. White & Fangbai Li & Zhiqiang Xiong & Siyu Zhang & Yuze Xu & Jingjing Yang & Weihao Tang & Qing Zhao & Fengchang Wu & Baoshan Xing, 2025. "Mechanistic evaluation of enhanced graphene toxicity to Bacillus induced by humic acid adsorption," Nature Communications, Nature, vol. 16(1), pages 1-12, December.
    3. J. Kishikawa & A. Nakanishi & A. Nakano & S. Saeki & A. Furuta & T. Kato & K. Mistuoka & K. Yokoyama, 2022. "Structural snapshots of V/A-ATPase reveal the rotary catalytic mechanism of rotary ATPases," Nature Communications, Nature, vol. 13(1), pages 1-11, December.
    4. Hao, Qing-Yi & Jiang, Rui & Hu, Mao-Bin & Wu, Chao-Yun & Guo, Ning, 2022. "Analytical investigation on totally asymmetric simple exclusion process with Langmuir kinetics and a parallel update with two sub-steps," Chaos, Solitons & Fractals, Elsevier, vol. 160(C).
    5. Tyler H. Ogunmowo & Haoyuan Jing & Sumana Raychaudhuri & Grant F. Kusick & Yuuta Imoto & Shuo Li & Kie Itoh & Ye Ma & Haani Jafri & Matthew B. Dalva & Edwin R. Chapman & Taekjip Ha & Shigeki Watanabe , 2023. "Membrane compression by synaptic vesicle exocytosis triggers ultrafast endocytosis," Nature Communications, Nature, vol. 14(1), pages 1-16, December.
    6. Seth Lichter & Benjamin Rafferty & Zachary Flohr & Ashlie Martini, 2012. "Protein High-Force Pulling Simulations Yield Low-Force Results," PLOS ONE, Public Library of Science, vol. 7(4), pages 1-10, April.
    7. Lv, Wangyong & Wang, Huiqi & Lin, Lifeng & Wang, Fei & Zhong, Suchuan, 2015. "Transport properties of elastically coupled fractional Brownian motors," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 437(C), pages 149-161.
    8. Woochul Nam & Bogdan I Epureanu, 2016. "Effects of Obstacles on the Dynamics of Kinesins, Including Velocity and Run Length, Predicted by a Model of Two Dimensional Motion," PLOS ONE, Public Library of Science, vol. 11(1), pages 1-18, January.
    9. Lipowsky, Reinhard & Klumpp, Stefan, 2005. "‘Life is motion’: multiscale motility of molecular motors," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 352(1), pages 53-112.
    10. Chou, Y.C. & Hsiao, Yi-Feng & To, Kiwing, 2015. "Dynamic model of the force driving kinesin to move along microtubule—Simulation with a model system," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 433(C), pages 66-73.
    11. Bibi Najma & Minu Varghese & Lev Tsidilkovski & Linnea Lemma & Aparna Baskaran & Guillaume Duclos, 2022. "Competing instabilities reveal how to rationally design and control active crosslinked gels," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    12. Peter Keller & Sylvie Rœlly & Angelo Valleriani, 2015. "A Quasi Random Walk to Model a Biological Transport Process," Methodology and Computing in Applied Probability, Springer, vol. 17(1), pages 125-137, March.
    13. repec:plo:pone00:0043219 is not listed on IDEAS

    More about this item

    Statistics

    Access and download statistics

    Corrections

    All material on this site has been provided by the respective publishers and authors. You can help correct errors and omissions. When requesting a correction, please mention this item's handle: RePEc:wly:jnlaaa:v:2008:y:2008:i:1:n:241736. See general information about how to correct material in RePEc.

    If you have authored this item and are not yet registered with RePEc, we encourage you to do it here. This allows to link your profile to this item. It also allows you to accept potential citations to this item that we are uncertain about.

    If CitEc recognized a bibliographic reference but did not link an item in RePEc to it, you can help with this form .

    If you know of missing items citing this one, you can help us creating those links by adding the relevant references in the same way as above, for each refering item. If you are a registered author of this item, you may also want to check the "citations" tab in your RePEc Author Service profile, as there may be some citations waiting for confirmation.

    For technical questions regarding this item, or to correct its authors, title, abstract, bibliographic or download information, contact: Wiley Content Delivery (email available below). General contact details of provider: https://onlinelibrary.wiley.com/journal/4058 .

    Please note that corrections may take a couple of weeks to filter through the various RePEc services.

    IDEAS is a RePEc service. RePEc uses bibliographic data supplied by the respective publishers.