Cytoplasmic Maturity Revealed by the Structural Changes in Incorporated Spermatozoon during the Course of Starfish Oocyte Maturation

Abstract

Immature oocytes of the starfish, A. pectinifera, are polyspermic. Spermatozoa can enter immature oocytes upon insemination, but the changes associated with the fertilization process in oocytes matured with 1-methyladenine (1-MeAde), such as the formation of aster and pronucleus, were not observed. After immature oocytes, previously inseminated, were matured with 1-MeAde, the formation of the sperm monaster was observed during germinal vesicle breakdown (GVBD). Amphiasters and pronuclei were formed after the formation of the 2nd polar body. The acquisition by oocytes of the capacity to undergo the normal process of fertilization occurs during the course of oocyte maturation. After injection of the cytoplasm of maturing oocytes into inseminated immature oocytes, the formation of aster and pronucleus was observed, suggesting that maturation-promoting factor (MPF) may be involved in establishing the cytoplasmic conditions (cytoplasmic maturity) necessary for the fertilization process to occur. When enucleated, inseminated halves of immature oocytes were treated with 1-MeAde, only monasters were formed; in the nucleated halves both amphiasters and sperm pronuclei were formed. Germinal vesicle material is required for the formation of amphiaster and sperm pronucleus but not for the formation of monaster. The amount of MPF produced in enucleated halves probably was sufficient only for the formation of the monaster but not for the formation of the amphiaster and pronucleus, since it was previously established that germinal vesicle material is necessary for the amplification of MPF. The formation of the monaster in the enucleated halves at a time corresponding to GVBD in nucleated controls suggests that the amount of MPF needed for this event is rather small. For the induction of subsequent fertilization process, large amounts of MPF may be required to establish the necessary cytoplasmic conditions, although other possible roles of nuclear material are not excluded.