Abstract
The spectacular extension of the acrosomal process in
Limulus sperm is effected by a bundle of actin-containing filaments with apparently no contribution from myosin. The bundle is coiled about the base of the sperm and, upon reaction, unwinds and extends out of the anterior end of the sperm with a screwing motion. We have analyzed the structure of the bundle in the coil and following its discharge. Optical diffraction studies of electron micrographs show a difference in the twist of the filaments in the two forms. The filaments in the coil have a twist of 0.23 ° per subunit more than that in the true discharge. As the signal to extend moves down the coil, the filaments change their twist and the bundle straightens. The coupling of these two movements produces the screwing motion. In the coil, the filaments wind around the axis of the bundle. As the filaments change their twist, the winding is undone. From freeze-fracture replicas we determined the hand of the winding of filaments in the coil and, in thin sections, we were able to determine the number of turns the filaments make for each loop of the coil. From these data we were able to predict the hand and amount of rotation during the discharge. From movie film sequences we could determine only the amount of rotation and found it to be 0.25 ° ± 0.05 ° per subunit discharged. This is in reasonable agreement with the expected value of 0.23 ° ± 0.05 ° per subunit. We propose that it is the change in twist of the actin filaments themselves that is responsible for the generation of force for the extension of the acrosomal process.