Dynamics of ‘immotile’ olfactory cilia in the silkmoth Antheraea

Abstract

Living olfactory sensory dendrites of the silkmoth Antheraea which are modified cilia lacking the central microtubule pair have been observed by means of video microscopy in sensilla from which the apical tips had been pinched off as well as in vitro after isolation. Dendrites project out of the opened hair tips cither spontaneously without manipulation or after application of basal pressure via a syringe connected to the haemolymph side. Spontaneously appearing dendrites can repeatedly project up to ca. 60 μm from, and retract back into, the hairs. They tend to remain straight, but curve if they project too far and bend on meeting an obstacle. The average elongation velocity of the dendrites is 0.4 μm/sec. After application of basal pressure, large numbers of dendrites immediately slide out of the apically opened hairs. These dendrites usually detach at their bases and float free in the solution until settling down at the bottom of the petri dish. They are able to make active movements, for example bending between points of attachment. Dendrites tend to adhere to other dendrites, sometimes making sliding movements against each other. The ciliary olfactory dendrites are backed by a large number of microtubules which appear to be interconnected by fine filaments, most probably microtubule-associated proteins (MAPs). The elongation and shortening of the dendrites is explained here by a sliding-filament mechanism similar to the one acting in ‘true motile’ cilia. As the cytoskcleton is not as highly organized as in the latter, the resulting movements are limited to elongation and contraction, bending being brought about only passively by apical resistance. Membrane beads have been observed to appear on, and move along, the dendrites. Their number increases with the age of the preparation.