1. How Does Cilium Length Affect Beating?
- Author
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Susan K. Dutcher, Kyle A. Thomas, Mathieu Bottier, and Philip V. Bayly
- Subjects
Physics ,0303 health sciences ,Periodicity ,Future studies ,Oscillation ,Cilium ,Dynamics (mechanics) ,Biophysics ,Video microscopy ,Articles ,Models, Theoretical ,Critical length ,Image frame ,03 medical and health sciences ,Motion ,0302 clinical medicine ,Torque ,Waveform ,Cilia ,030217 neurology & neurosurgery ,Chlamydomonas reinhardtii ,030304 developmental biology - Abstract
The effects of cilium length on the dynamics of cilia motion were investigated by high-speed video microscopy of uniciliate mutants of the swimming alga,Chlamydomonas reinhardtii.Cells with short cilia were obtained by deciliating cells via pH shock and allowing cilia to reassemble for limited times. The frequency of cilia beating was estimated from motion of the cell body and of the cilium. Key features of the ciliary waveform were quantified from polynomial curves fitted to the cilium in each image frame. Most notably, periodic beating did not emerge until the cilium reached a critical length between 2-4 µm. Surprisingly, in cells that exhibited periodic beating, the frequency of beating was similar for all lengths with only a slight decrease in frequency as length increased from 4 µm to the normal length of 10-12 µm. The waveform average curvature (rad/µm) was also conserved as the cilium grew. The mechanical metrics of ciliary propulsion: force, torque, and power all increased in proportion to length. Mechanical efficiency of beating appeared to be maximal at the normal wild-type length of 10-12 μm. These quantitative features of ciliary behavior illuminate the biophysics of cilia motion and, in future studies, may help distinguish competing hypotheses of the underlying mechanism of oscillation.
- Published
- 2018