Induction of temporary beating in paralyzed flagella of Chlamydomonas mutants by application of external force.

To help understand the mechanism by which the sliding movement of outer-doublet microtubules in cilia and flagella is converted into bending waves, we examined the effect of mechanical force imposed on the flagella of Chlamydomonas mutants lacking the central pair or multiple dyneins. These mutants were almost completely nonmotile under normal conditions. A bend was produced in a flagellum either by holding a cell with a micropipette and quickly moving it with a piezoelectric actuator; or by pushing a flagellum with a microneedle. After removal of the external force, mutants lacking the central pair (pf18 and pf19) displayed beating at irregular intervals of > 1 second for one to several cycles. Similarly, a double mutant (ida2ida4) lacking four species of inner-arm dynein displayed beating at intervals of > 0.1 second for up to 80 cycles. However, paralyzed flagella of double mutants that lack the outer dynein arm in addition to the central pair or the inner dynein arm did not show cyclical movements upon application of external force. These results indicate that the central pair and the inner dynein arm are important for both stable bend formation at the base and efficient bend propagation along the flagellar length. They also suggest that the outer dynein arm, and not the inner dynein arm, enables the flagellar axoneme to propagate bends independently of the central pair. We propose that the axoneme is equipped with two independent motor systems for oscillatory movements: an outer-arm system controlled by the axonemal mechanical state independently of the central pair/radial spoke system, and an inner-arm system controlled by both the axonemal mechanical state and the central pair/radial spokes.