Chemically enucleated mouse oocytes: ultrastructure and kinetics of histone H1 kinase activity.

The objective of the study was to characterize the ultrastructure changes and biochemical mechanisms underlying the expulsion of the entire chromosome complement in chemically enucleated mouse oocytes. The ultrastructural studies demonstrated that the morphology of cytoplasts produced by etoposide-cycloheximide treatment were indistinguishable from intact metaphase I and II oocytes. Moreover, polar bodies formed by chemical enucleation were in almost all cases completely separated from the parent cytoplast and differed from normal polar bodies only in their chromatin content morphology and because they contained a slightly higher number of cytoplasmic organelles. The mode of polar body formation, however, in normal and chemically enucleated oocytes differs substantially: spindle involvement is important for normal polar body extrusion but plays no part in the protracted expulsion of chromosomes during chemical enucleation. After etoposide-cycloheximide treatment, histone H1 kinase activity remains high for the ensuing 6-8 h before declining gradually to basal levels 14 h after treatment. The expulsion of the polar body occurred only after the slowly declining H1 kinase activity reached basal levels. The activity of this kinase rose sharply to reach maximal levels within 4 h when the enucleated oocytes were removed from the inhibitor-supplemented medium and placed in normal medium. The findings in this paper indicate that cytoplasts produced by chemical enucleation are morphologically normal, thus suggesting that these enucleated cells are suitable for cloning studies. Although effective in mouse oocytes, we postulate that certain modifications to the enucleation technology are necessary before a reliable non-invasive protocol for ungulate oocytes will be available.