Jibak Lee

Unified mode of centromeric protection by shugoshin in mammalian oocytes and somatic cells

Reductional chromosome segregation in germ cells, where sister chromatids are pulled to the same pole, accompanies the protection of cohesin at centromeres from separase cleavage. Here, we show that mammalian shugoshin Sgo2 is expressed in germ cells and is solely responsible for the centromeric localization of PP2A and the protection of cohesin Rec8 in oocytes, proving conservation of the mechanism from yeast to mammals. However, this role of Sgo2 contrasts with its mitotic role in protecting centromeric cohesin only from prophase dissociation, but never from anaphase cleavage. We demonstrate that, in somatic cells, shugoshin colocalizes with cohesin in prophase or prometaphase, but their localizations become separate when centromeres are pulled oppositely at metaphase. Remarkably, if tension is artificially removed from the centromeres at the metaphase–anaphase transition, cohesin at the centromeres can be protected from separase cleavage even in somatic cells, as in germ cells. These results argue for a unified view of centromeric protection by shugoshin in mitosis and meiosis.

Temporally and spatially selective loss of Rec8 protein from meiotic chromosomes during mammalian meiosis

Sister chromatid cohesion is maintained from DNA replication to metaphase-to-anaphase transition by multisubunit protein complexes called cohesin, which include at least four proteins, SMC1α, SMC3, Rad21 and either SA1 or SA2, in mammalian somatic cells. We report here the first evidence of the involvement of Rec8 protein, a mammalian homolog of yeast Rec8p, in meiosis-specific chromosome behavior in mammals. In immunoblotting and immunohistochemical analysis using specific antibodies against mouse Rec8, we found that Rec8 was expressed in the testis but not in the kidney or liver; more precisely, it was expressed in spermatocytes and spermatids but not in spermatogonia or other somatic cells. We also found that Rec8 is present in both phosphorylated and dephosphorylated states in vivo. Immunoprecipitation analyses revealed that Rec8 associates with other cohesin proteins, SMC1β (meiosis-specific protein) and SMC3 and with a component of synaptonemal complexes, SCP3, but not with SMC1α. In meiotic chromosome spreads, Rec8 was localized along the axial/lateral elements of the synaptonemal complexes in meiotic prophase from the leptotene to diplotene stages. At later stages, diakinesis and metaphase I, Rec8 was localized along the interstitial axes of chromosomes, including both centromere and arm regions of chromosomes. However, concomitantly with separation of homologous chromosomes in anaphase I, Rec8 was no longer detected along the arm regions, while it persisted on centromere regions up to metaphase II. In anaphase II, the centromeric signals were diminished. We propose from these results that mammalian Rec8 protein, in association with SMC3 and SMC1β but not SMC1α, is involved in meiosis-specific chromosome behavior, and that homologous chromosome separation is triggered by selective loss of Rec8 from chromosome arms in meiosis I, while sister chromatid cohesion is maintained until metaphase II/anaphase II transition by centromeric Rec8 during mammalian meiosis.

Spindle Formation and Dynamics of γ-Tubulin and Nuclear Mitotic Apparatus Protein Distribution During Meiosis in Pig and Mouse Oocytes

Abstract This work focuses on the assembly and transformation of the spindle during the progression through the meiotic cell cycle. For this purpose, immunofluorescent confocal microscopy was used in comparative studies to determine the spatial distribution of α- and γ-tubulin and nuclear mitotic apparatus protein (NuMA) from late G2 to the end of M phase in both meiosis and mitosis. In pig endothelial cells, consistent with previous reports, γ-tubulin was localized at the centrosomes in both interphase and M phase, and NuMA was localized in the interphase nucleus and at mitotic spindle poles. During meiotic progression in pig oocytes, γ-tubulin and NuMA were initially detected in a uniform distribution across the nucleus. In early diakinesis and just before germinal vesicle breakdown, microtubules were first detected around the periphery of the germinal vesicle and cell cortex. At late diakinesis, a mass of multi-arrayed microtubules was formed around chromosomes. In parallel, NuMA localization changed from an amorphous to a highly aggregated form in the vicinity of the chromosomes, but γ-tubulin localization remained in an amorphous form surrounding the chromosomes. Then the NuMA foci moved away from the condensed chromosomes and aligned at both poles of a barrel-shaped metaphase I spindle while γ-tubulin was localized along the spindle microtubules, suggesting that pig meiotic spindle poles are formed by the bundling of microtubules at the minus ends by NuMA. Interestingly, in mouse oocytes, the meiotic spindle pole was composed of several γ-tubulin foci rather than NuMA. Further, nocodazole, an inhibitor of microtubule polymerization, induced disappearance of the pole staining of NuMA in pig metaphase II oocytes, whereas the mouse meiotic spindle pole has been reported to be resistant to the treatment. These results suggest that the nature of the meiotic spindle differs between species. The axis of the pig meiotic spindle rotated from a perpendicular to a parallel position relative to the cell surface during telophase I. Further, in contrast to the stable localization of NuMA and γ-tubulin at the spindle poles in mitosis, NuMA and γ-tubulin became relocalized to the spindle midzone during anaphase I and telophase I in pig oocytes. We postulate that in the centrosome-free meiotic spindle, NuMA aggregates the spindle microtubules at the midzone during anaphase and telophase and that the polarity of meiotic spindle microtubules might become inverted during spindle elongation.

RAD21L, a novel cohesin subunit implicated in linking homologous chromosomes in mammalian meiosis

The meiosis-specific kleisin cohesin subunit, RAD21L, may participate in synapsis initiation and crossover recombination between homologous chromosomes.

Localisation of phosphorylated MAP kinase during the transition from meiosis I to meiosis II in pig oocytes.

Mitogen-activated protein kinase (MAPK) has been reported to be involved in oocyte maturation in all animals so far examined. In the present study we investigate the expression and localisation of active phosphorylated MAPKs (p44ERK1/p42ERK2) during maturation of pig oocytes. In immunoblot analysis using anti-p44ERK1 antibody which recognised both active and inactive forms of p44ERK1 and p42ERK2, we confirmed that MAPKs were phosphorylated around the time of germinal vesicle breakdown (GVBD) and the active phosphorylated MAPKs (pMAKs) were maintained until metaphase II, as has been reported. On immunofluorescent confocal microscopy using anti-pMAPK antibody which recognised only phosphorylated forms of MAPKs, pMAPK was localised at the spindle poles in pig mitotic cells. On the other hand, in pig oocytes, no signal was detected during GV stage. After GVBD, the area around condensed chromosomes was preferentially stained at metaphase I although whole cytoplasm was faintly stained. At early anaphase I, the polar regions of the meiotic spindle were prominently stained. However, during the progression of anaphase I and telophase I pMAPK was detected at the mid-zone of the elongated spindle, gradually becoming concentrated at the centre. Finally, at the time of emission of the first polar body, pMAPK was detected as a ring-like structure between the condensed chromosomes and the first polar body, and the staining was maintained even after the metaphase II spindle was formed. The inhibition of MAPK activity with the MAPK kinase inhibitor U0126 during the meiosis I/meiosis II transition suppressed chromosome separation, first polar body emission and formation of the metaphase II spindle. From these results, we propose that the spindle-associated pMAPKs play an important role in the events occurring during the meiosis I/meiosis II transition, such as chromosome separation, spindle elongation and cleavage furrow formation in pig oocytes.

Loss of Rec8 from chromosome arm and centromere region is required for homologous chromosome separation and sister chromatid separation, respectively, in mammalian meiosis.

Chromosome separation in meiosis I is different from those in mitosis and meiosis II inthat homologs separate from each other in the former while sisters do so in the latter. Weshow here that meiosis-specific cohesin subunit Rec8 in mouse oocytes showsessentially the same pattern of localization to those reported in yeasts1-3 and mammalianspermatocytes4,5; Rec8 along chromosome arm (armRec8) is lost at the metaphaseI-to-anaphase I transition, although centromeric Rec8 (cenRec8) is maintained until theonset of anaphase II. Suppression of the loss of armRec8 by microinjection of anti-Rec8antibody into the oocytes inhibits homolog separation but not the first polar bodyemission (cytokinesis). Similarly, the injection of anti-Rec8 antibody into metaphase IIoocytes prevents sister separation in anaphase II after oocyte activation. These datademonstrate that the loss of armRec8 and cenRec8 is required for separation ofhomologs and sisters, respectively, but both are not required for other late mitotic eventssuch as spindle elongation and cytokinesis in mouse oocytes. Further, we propose thatloss of armRec8 (homolog separation) and cytokinesis are suppressed until anaphase Iby Securin whose destruction is regulated by spindle checkpoint-proteasome pathway,and that Topoisomerase II is required for homolog separation independently from suchpathway.

Condensin confers the longitudinal rigidity of chromosomes

In addition to inter-chromatid cohesion, mitotic and meiotic chromatids must have three physical properties: compaction into ‘threads’ roughly co-linear with their DNA sequence, intra-chromatid cohesion determining their rigidity, and a mechanism to promote sister chromatid disentanglement. A fundamental issue in chromosome biology is whether a single molecular process accounts for all three features. There is universal agreement that a pair of Smc–kleisin complexes called condensin I and II facilitate sister chromatid disentanglement, but whether they also confer thread formation or longitudinal rigidity is either controversial or has never been directly addressed respectively. We show here that condensin II (beta-kleisin) has an essential role in all three processes during meiosis I in mouse oocytes and that its function overlaps with that of condensin I (gamma-kleisin), which is otherwise redundant. Pre-assembled meiotic bivalents unravel when condensin is inactivated by TEV cleavage, proving that it actually holds chromatin fibres together.

Specific regulation of CENP-E and kinetochores during meiosis I/meiosis II transition in pig oocytes

To understand the mechanisms which regulate meiosis‐specific cell cycle and chromosome distribution in mammalian oocytes, the level and the localization of CENP‐E and the kinetochore number and direction on a half bivalent were examined during pig oocyte maturation. CENP‐E is a kinetochore motor protein whose intracellular level and localization are strictly regulated in the somatic cell cycle. The localizations of CENP‐E on meiotic chromosomes from diakinesis stage to anaphase I and at the spindle midzone at telophase I were shown by immunofluorescent confocal microscopy to be similar to those in somatic cells of pig and other species. Further, ultrastructural analysis revealed the presence of CENP‐E on fibrous corona and outer plate of kinetochores of the meiotic chromosomes. However, unlike mitosis, CENP‐E staining was continuously detected either at the spindle midzone or on the kinetochores of segregated chromosomes during the first polar body emission. Consistent with this, immunoblot analysis revealed that CENP‐E level remained high during meiosis I/meiosis II (MI/MII) transition and that some of CENP‐E survived through the transition even in cycloheximide‐treated oocytes in which cyclin B1 was completely degraded. Furthermore, examinations of CENP‐E signals in confocal microscopy and kinetochores in electron microscopy in MI and MII oocytes provide the cytological evidence in mammalian oocytes which suggests that each sister chromatid in a pair has its own kinetochore which localizes side‐by‐side so that two sister chromatids on a half bivalent are oriented toward and connected to the same pole in MI. Mol. Reprod. Dev. 56:51–62, 2000.

Condensins I and II are essential for construction of bivalent chromosomes in mouse oocytes

In mouse oocytes, condensin I localizes around centromeric regions, whereas condensin II is concentrated onto chromatid axes of Meta-I bivalent chromosomes. Both condensins are required for many aspects of meiotic chromosome dynamics, including individualization, resolution, and segregation, as well as monopolar attachment of sister kinetochores.

Acquisition of meiotic competence in growing pig oocytes correlates with their ability to activate Cdc2 kinase and MAP kinase

Meiotic maturation of mammalian oocytes is under the control of cell cycle molecules Cdc2 kinase and MAP kinase (mitogen-activated protein kinase). In the present study, we investigated the relationship between the ability to activate Cdc2 kinase and MAP kinase and the acquisition of meiotic competence during pig oocyte growth. Growing and fully grown pig oocytes were collected from four groups of antral follicles of various diameters (A, 0.5-0.7 mm; B, 1.0-1.5 mm; C, 2.0-2.5 mm; D, 4.0-6.0 mm) and cultured in vitro. Fully grown oocytes from class D follicles, which have full competence to mature to metaphase II, had the ability to activate both Cdc2 kinase and MAP kinase. In contrast, growing oocytes from class A follicles, which have limited competence to resume meiosis, had no such ability. Cyclin B1 molecules did accumulate, however, with phosphorylated 35 and 36 kDa bands of p34cdc2 appearing in the cultured oocytes. Of the growing oocytes from class B follicles, 60% resumed meiosis but arrested at metaphase I. Some of the oocytes in this class were capable of activating Cdc2 kinase, although they did not appear to have established a MAP kinase-activating pathway or the ability to activate MEK. These results suggest that limited meiotic competence in growing oocytes from class A follicles is due to their inability to activate Cdc2 kinase and their incomplete MEK-MAP-kinase pathway, although the oocytes are capable of accumulating cyclin B1 molecules. During the final growth phase, pig oocytes acquire the ability to activate Cdc2 kinase and then establish the MEK-MAP-kinase pathway for full meiotic competence.