A Bending Mode Analysis for Growing Microtubules: Evidence for a Velocity-Dependent Rigidity

doi:10.1529/biophysj.103.038877

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A Bending Mode Analysis for Growing Microtubules: Evidence for a Velocity-Dependent Rigidity

Marcel E. Janson and Marileen Dogterom

F.O.M. Institute for Atomic and Molecular Physics, Kruislaan 407, 1098 SJ, Amsterdam, The Netherlands

Correspondence: Address reprint requests to Marcel E. Janson, E-mail: mjanson{at}mail.med.upenn.edu.

Microtubules are dynamic protein polymers that continuouslyswitch between elongation and rapid shrinkage. They have anexceptional bending stiffness that contributes significantlyto the mechanical properties of eukaryotic cells. Measurementsof the persistence length of microtubules have been publishedsince 10 years but the reported values vary over an order ofmagnitude without an available explanation. To precisely measurethe rigidity of microtubules in their native growing state,we adapted a previously developed bending mode analysis of thermallydriven shape fluctuations to the case of an elongating filamentthat is clamped at one end. Microtubule shapes were quantifiedusing automated image processing, allowing for the characterizationof up to five bending modes. When taken together with threeother less precise measurements, our rigidity data suggest thatfast-growing microtubules are less stiff than slow-growing microtubules.This would imply that care should be taken in interpreting rigiditymeasurements on stabilized microtubules whose growth historyis not known. In addition, time analysis of bending modes showedthat higher order modes relax more slowly than expected fromsimple hydrodynamics, possibly by the effects of internal frictionwithin the microtubule.

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