Force production by single kinesin motors

Force production by single kinesin motors

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 oc...

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Veröffentlicht in:Nature cell biology 2000-10, Vol.2 (10), p.718-723
Hauptverfasser: Schnitzer, Mark J., Visscher, Koen, Block, Steven M.
Format: Artikel
Sprache:eng
Schlagworte:
Adenosine Triphosphate - metabolism
ATP
Biomechanical Phenomena
Biomedical and Life Sciences
Cancer Research
Cell Biology
Developmental Biology
Hydrolysis
Kinesin
Kinesin - physiology
Life Sciences
Load distribution
Models, Theoretical
Molecular Motor Proteins - physiology
Molecular motors (Biochemistry)
Movement - physiology
Physics
Physiological aspects
RNA polymerase
Stem Cells
Thermal energy
Thermodynamics
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Zusammenfassung: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.
ISSN:1465-7392
1476-4679
DOI:10.1038/35036345