Force production by single kinesin motors

Mark J. Schnitzer; Koen Visscher; Steven M. Block

doi:10.1038/35036345

Force production by single kinesin motors

Mark J. Schnitzer, Koen Visscher, Steven M. Block

Research output: Contribution to journal › Article › peer-review

492 Scopus citations

Abstract

Motor proteins such as kinesin, myosin and polymerase convert chemical energy into work through a cycle that involves nucleotide hydrolysis. Kinetic rates in the cycle that depend upon load identify transitions at which structural changes, such as power strokes or diffusive motions, are likely to occur. Here we show, by modelling data obtained with a molecular force clamp, that kinesin mechanochemistry can be characterized by a mechanism in which a load-dependent isomerization follows ATP binding. This model quantitatively accounts for velocity data over a wide range of loads and ATP levels, and indicates that movement may be accomplished through two sequential 4-nm substeps. Similar considerations account for kinesin processivity, which is found to obey a load-dependent Michaelis-Menten relationship.

Original language	English (US)
Pages (from-to)	718-723
Number of pages	6
Journal	Nature Cell Biology
Volume	2
Issue number	10
DOIs	https://doi.org/10.1038/35036345
State	Published - Oct 2000

ASJC Scopus subject areas

Cell Biology

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10.1038/35036345

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title = "Force production by single kinesin motors",

abstract = "Motor proteins such as kinesin, myosin and polymerase convert chemical energy into work through a cycle that involves nucleotide hydrolysis. Kinetic rates in the cycle that depend upon load identify transitions at which structural changes, such as power strokes or diffusive motions, are likely to occur. Here we show, by modelling data obtained with a molecular force clamp, that kinesin mechanochemistry can be characterized by a mechanism in which a load-dependent isomerization follows ATP binding. This model quantitatively accounts for velocity data over a wide range of loads and ATP levels, and indicates that movement may be accomplished through two sequential 4-nm substeps. Similar considerations account for kinesin processivity, which is found to obey a load-dependent Michaelis-Menten relationship.",

author = "Schnitzer, {Mark J.} and Koen Visscher and Block, {Steven M.}",

note = "Funding Information: We thank T. Perkins and L. Satterwhite for helpful discussions, J. de Georgis for squid dissection, and D. Peoples for expert machining. Experiments were carried out at Princeton University and were supported by grants from the NIGMS, NSF and W.M. Keck Foundation (to S.M.B.), predoctoral fellowships from the American Heart Association, the Charlotte Elizabeth Proctor Fund and the Program in Mathematics and Molecular Biology Burroughs Wellcome Fund (to M.J.S.), and a postdoctoral fellowship from the Burroughs Wellcome Fund of the Life Sciences Research Foundation (to K.V.). Data analysis and modelling were also supported by Lucent Technologies. Correspondence and requests for materials should be addressed to K.V. or S.M.B.",

year = "2000",

month = oct,

doi = "10.1038/35036345",

language = "English (US)",

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AU - Schnitzer, Mark J.

AU - Visscher, Koen

AU - Block, Steven M.

N1 - Funding Information: We thank T. Perkins and L. Satterwhite for helpful discussions, J. de Georgis for squid dissection, and D. Peoples for expert machining. Experiments were carried out at Princeton University and were supported by grants from the NIGMS, NSF and W.M. Keck Foundation (to S.M.B.), predoctoral fellowships from the American Heart Association, the Charlotte Elizabeth Proctor Fund and the Program in Mathematics and Molecular Biology Burroughs Wellcome Fund (to M.J.S.), and a postdoctoral fellowship from the Burroughs Wellcome Fund of the Life Sciences Research Foundation (to K.V.). Data analysis and modelling were also supported by Lucent Technologies. Correspondence and requests for materials should be addressed to K.V. or S.M.B.

PY - 2000/10

Y1 - 2000/10

N2 - Motor proteins such as kinesin, myosin and polymerase convert chemical energy into work through a cycle that involves nucleotide hydrolysis. Kinetic rates in the cycle that depend upon load identify transitions at which structural changes, such as power strokes or diffusive motions, are likely to occur. Here we show, by modelling data obtained with a molecular force clamp, that kinesin mechanochemistry can be characterized by a mechanism in which a load-dependent isomerization follows ATP binding. This model quantitatively accounts for velocity data over a wide range of loads and ATP levels, and indicates that movement may be accomplished through two sequential 4-nm substeps. Similar considerations account for kinesin processivity, which is found to obey a load-dependent Michaelis-Menten relationship.

AB - Motor proteins such as kinesin, myosin and polymerase convert chemical energy into work through a cycle that involves nucleotide hydrolysis. Kinetic rates in the cycle that depend upon load identify transitions at which structural changes, such as power strokes or diffusive motions, are likely to occur. Here we show, by modelling data obtained with a molecular force clamp, that kinesin mechanochemistry can be characterized by a mechanism in which a load-dependent isomerization follows ATP binding. This model quantitatively accounts for velocity data over a wide range of loads and ATP levels, and indicates that movement may be accomplished through two sequential 4-nm substeps. Similar considerations account for kinesin processivity, which is found to obey a load-dependent Michaelis-Menten relationship.

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Force production by single kinesin motors

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