Anti-tubulin immunofluorescence microscopy of microtubules present during the pronuclear movements of sea urchin fertilization

Abstract

Anti-tubulin immunofluorescence microscopy is used here to demonstrate the configurations of the microtubule-containing structures which participate in the pronuclear movements of sea urchin fertilization. This technique shows that the egg is devoid of microtubules until after the fertilizing sperm is fully incorporated. All the microtubules which appear during the course of fertilization are organized around the base of the sperm head and the sperm aster thus formed behaves in a way that could account for the characteristic motions of the male and female pronuclei as documented by time-lapse video microscopy. Extension of astral microtubules appears to be responsible for the slow (ca. 2.5 μm min −1) movement of the sperm aster into the cytoplasm of the egg; the rapid (ca. 15 μm min −1) migration of the female pronucleus to the sperm aster seems to depend on connection of the female pronucleus to microtubules of the sperm aster. Continued extension of astral microtubules after the pronuclei are brought into conjunction can account for the centripetal motion of the paired (or fused) pronuclei and for the positioning of the zygote nucleus in the center of the egg. The behavior of astral microtubules during these motions suggests that they are capable of transmitting both pushing and pulling forces. All the pronuclear movements, and the assembly of detectable microtubules, are sensitive to the microtubule inhibitors griseofulvin and colchicine. Because of this sensitivity, and since all the observable microtubules within the egg during fertilization arise at the sperm aster, it is concluded that the pronuclear movements of fertilization result from the actions of the sperm aster. The pronuclear movements of sea urchin fertilization represent a simple but striking example of microtubule-mediated motility.