Sliding Velocity Between Outer Doublet Microtubules of Sea-Urchin Sperm
Axonemes
The flagellar axonemes have a cylindrical form, which consists of nine doublet microtubules surrounding a central pair of single microtubules. Each doublet tubule has two parallel rows of projections, called outer and inner arms. Sliding movement between doublet microtubules was first reported by Summers and Gibbons, who observed that doublet tubules were extruded from trypsin-treated axonemes of sea-urchin sperm flagella on addition of ATP. Their observation indicated that the bending movement of flagella results basically from these active sliding movements between the adjacent doublet tubules in the axonemes. Experimental evidence suggests that the dynein arms projecting from the doublet tubules interact with the adjacent tubules and by hydrolysing ATP, produce the mechanical force to slide. According to Gibbons and Gibbons the outer arms were removed from the doublet tubules by extracting the demembranated sea-urchin sperm with 0.5 M KCl or NaCl, while the inner arms and other axonemal structures remained apparently intact. Although the form of their bending waves was not significantly altered, the KCl-extracted sperm had only about half the flagellar beat frequency of the demembranated sperm. The 21S latent ATPase activity form of dynein 1 restored up to 90% of the outer arms on the doublet tubules and increased the beat frequency of KCl-extracted sperm from 14 Hz to 25 Hz. We found that the NaCl-extracted axonemes of sea-urchin sperm had the ability to extrude outer doublet tubules on addition of ATP and trypsin, in a similar manner to that of the intact axonemes. We attempted to compare the sliding velocity of the outer doublet tubules in the arm-depleted axonemes and in the arm-recombined axonemes, with that in the intact axonemes, in order to find the relationship between the sliding velocity and the number of arms in these axonemes.