Microtubule tracks can be detected in mouse oocytes with an antibody directed against a calcium transporter.

In metaphase II-arrested mouse oocytes, most microtubules are found in the meiotic spindle, a structure that remains stable for hours despite microtubule instability. Microtubule organizing centres (MTOCs) are present at the poles of the spindle and in the cytoplasm, but the latter nucleate very few microtubules. This particular organization of the microtubule network enabled us to observe the unexpected behaviour of a protein that can associate with microtubules. We compared the distribution of a mitosis-activated calcium transport system with that of the microtubule network, by immunofluorescence, using two monoclonal antibodies, one directed against a component of the calcium transport system (7/13), and the other against the common tyrosinated form of alpha-tubulin (YL1/2). The 7/13 staining was associated with the spindle microtubules and with the kinetochore area. In addition, we observed many asters in the cytoplasm, around the cytoplasmic MTOCs. The majority of these asters were not stained with the antitubulin antibody. Moreover, these 7/13 asters either disappeared after nocodazole treatment or were enlarged after taxol treatment. Using a confocal microscope, we observed single fibres that were stained with both antibodies: the extremity furthest from the MTOC (corresponding to the + end of the microtubule) being detected by the 7/13 antibody only. All these observations suggest that the 7/13 antigen is associated with microtubule tracks that persist a few minutes after microtubule depolymerization. The possible role of these tracks in microtubule regrowth is discussed.

The metaphase II arrest in mouse oocytes is controlled through microtubule-dependent destruction of cyclin B in the presence of CSF.

In unfertilized eggs from vertebrates, the cell cycle is arrested in metaphase of the second meiotic division (metaphase II) until fertilization or activation. Maintenance of the long-term meiotic metaphase arrest requires mechanisms preventing the destruction of the maturation promoting factor (MPF) and the migration of the chromosomes. In frog oocytes, arrest in metaphase II (M II) is achieved by cytostatic factor (CSF) that stabilizes MPF, a heterodimer formed of cdc2 kinase and cyclin. At the metaphase/anaphase transition, a rapid proteolysis of cyclin is associated with MPF inactivation. In Drosophila, oocytes are arrested in metaphase I (M I); however, only mechanical forces generated by the chiasmata seem to prevent chromosome separation. Thus, entirely different mechanisms may be involved in the meiotic arrests in various species. We report here that in mouse oocytes a CSF-like activity is involved in the M II arrest (as observed in hybrids composed of fragments of metaphase II-arrested oocytes and activated mitotic mouse oocytes) and that the high activity of MPF is maintained through a continuous equilibrium between cyclin B synthesis and degradation. In addition, the presence of an intact metaphase spindle is required for cyclin B degradation. Finally, MPF activity is preferentially associated with the spindle after bisection of the oocyte. Taken together, these observations suggest that the mechanism maintaining the metaphase arrest in mouse oocytes involves an equilibrium between cyclin synthesis and degradation, probably controlled by CSF, and which is also dependent upon the three-dimensional organization of the spindle.

MAP kinase becomes stably activated at metaphase and is associated with microtubule-organizing centers during meiotic maturation of mouse oocytes.

Using antisera generated against sequences conserved between the ERK1- and the ERK2-encoded species of mitogen-activated protein (MAP) kinases of the rat, species of approximate M(r) 42 and 44 kDa were identified in mouse oocytes. When oocytes underwent meiotic maturation, both species displayed a retarded electrophoretic mobility, consistent with modification by phosphorylation. The slow-migrating forms first appeared after the oocytes had entered metaphase, and their appearance was sensitive to inhibitors of protein synthesis or phosphorylation. These forms remained throughout maturation and in oocytes arrested at metaphase II. Following oocyte activation, which induces a transition to interphase, the slow-migrating forms were replaced by the fast-migrating forms observed in prophase oocytes. MAP kinase activity also increased after oocytes entered metaphase, and this increase required protein synthesis and phosphorylation. To investigate the intracellular distribution of the immunoreactive species, spindles were purified from metaphase II eggs. Both the 42- and the 44-kDa species were detected in immunoblots, and bright staining of the spindle poles was observed by immunofluorescence. When intact oocytes undergoing maturation were examined by immunofluorescence, foci of staining were initially detected on opposing sides of the condensing chromosomes and then became congregated at each pole of the first meiotic spindle. No localized staining was observed during the first meiotic division, but stained foci were present at the poles of the second meiotic spindle. In addition, several cytoplasmic foci of staining often could be seen. When oocytes were exposed to taxol, which permits nonspindle microtubule-organizing centers (MTOCs) present in the cytoplasm to nucleate microtubule assembly, the cytoplasmic foci labeled by the MAP kinase antibodies were found to contain tubulin. We conclude that mouse oocytes contain 42- and 44-kDa species of MAP kinase and that, after maturing oocytes enter metaphase, MAP kinase activity is stimulated by means of a process requiring protein synthesis and phosphorylation. MAP kinase is present in the spindle and is specifically associated with the MTOCs present at the spindle poles and in the cytoplasm. Evidence from cell-free systems suggests that the alterations in MTOC activity that normally occur at metaphase in oocytes may be regulated by MAP kinase. The association of MAP kinase with MTOCs provides a potential structural basis for this cell cycle-dependent change in MTOC activity.

Okadaic acid induces spindle lengthening and disrupts the interaction of microtubules with the kinetochores in metaphase II-arrested mouse oocytes.

The cell cycle is regulated by phosphorylation events via a cascade of protein kinases and phosphatases, but many of their substrates remain unknown. To study whether proteins of the metaphase II-arrested mouse oocyte meiotic spindle are substrates for phosphorylation events, we used okadaic acid (OA), a potent phosphatase inhibitor, upon fully mature spindles. Incubation of oocytes for 3 hr with 1 microM OA led to a dramatic lengthening of the spindle and a disorganization of the metaphase plate. Electron microscope studies revealed that this was due to a disruption of the interactions between the microtubules and the kinetochores. Biochemical analysis including MPM-2 immunoblotting and [32P]phosphate labeling of whole oocytes revealed several changes in the phosphorylation pattern following the OA treatment. Moreover, meiotic spindle purification or microtubule-associated proteins (MAPs) isolation showed that some of these phosphorylations occur on proteins associated with the microtubules or with structures closely related to the spindle. These results suggest that the changes occurring in the microtubule network during the cell cycle are partly due to the phosphorylation of some proteins associated with the microtubules.

Inhibition of protein kinases by 6-dimethylaminopurine accelerates the transition to interphase in activated mouse oocytes.

Mouse oocyte activation is followed by a peculiar period during which the interphase network of microtubules does not form and the chromosomes remain condensed despite the inactivation of MPF. To evaluate the role of protein phosphorylation during this period, we studied the effects of the protein kinase inhibitor 6-dimethylaminopurine (6-DMAP) on fertilization and/or parthenogenetic activation of metaphase II-arrested mouse oocytes. 6-DMAP by itself does not induce the inactivation of histone H1 kinase in metaphase II-arrested oocytes, and does not influence the dynamics of histone H1 kinase inactivation during oocyte activation. However, 6-DMAP inhibits protein phosphorylation after oocyte activation. In addition, the phosphorylated form of some proteins disappear earlier in oocytes activated in the presence of 6-DMAP than in the activated control oocytes. This is correlated with the acceleration of some post-fertilization morphological events, such as sperm chromatin decondensation and its transient recondensation, formation of the interphase network of microtubules and pronuclear formation. In addition, numerous abnormalities could be observed: (1) the spindle rotation and polar body extrusion are inhibited; (2) the exchange of protamines into histones seems to be impaired, as judged by the morphology of DNA fibrils by electron microscopy; (3) the formation of a new nuclear envelope around the sperm chromatin proceeds prematurely, while recondensation is not yet completed. These observations suggest that the 6-DMAP-sensitive kinase(s) is (are) involved in the control of post-fertilization events such as the formation of the interphase network of microtubules, the remodelling of sperm chromatin and pronucleus formation.

Cytoskeleton organization during oogenesis, fertilization and preimplantation development of the mouse.

The organization and role of the cytoskeletal networks (mainly microtubules and microfilaments) during oogenesis, fertilization and preimplantation development of the mouse are described given the importance of cell-cell interactions and of the subcellular organization in events leading to the formation of the first two lineages of the mouse embryo.

Post-translational modifications of tubulin and the dynamics of microtubules in mouse oocytes and zygotes.

The distribution of post-translationally modified forms of tubulin has been studied in mouse oocytes arrested in meiotic metaphase II and in interphase eggs after fertilisation. Tyrosinated and acetylated microtubules are present in the meiotic spindle but detyrosinated ones are not. Acetylation only occurs in the most stable subpopulation of microtubules in the spindles ("pole to kinetochore"). After fertilisation, many microtubules of the interphase array become acetylated, but detyrosination occurs only at a very low level.