Cytoplasmic microtubular dynamics and chromatin organization during mammalian oogenesis and oocyte maturation (original) (raw)
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Centrosome and microtubule dynamics during early stages of meiosis in mouse oocytes
Molecular Human Reproduction, 2003
Centrosomes, major regulatory sites for the microtubule (MT) nucleation, are regulated in a dynamic manner throughout the process of meiotic maturation. Recently, centrosome orientation in mouse oocytes has been demonstrated in metaphase I through metaphase II. However, centrosomal protein expression in concordance with MT polymerization in earlier stages of oocyte maturation from germinal vesicle stage (GV) to prometaphase I still remains unclear. The present study aims to assess the centrosome±microtubule remodelling during the onset of meiosis based on strict criteria of nuclear maturation. Six consecutive stages were determined for scoring the oocytes as unrimmed nucleolus (UR), partially rimmed nucleolus (PR), fully rimmed nucleolus (FR), nuclear lamina dissolution (NLD), disappearance of nucleolus (DON), and chromatin condensation (CC). A centrosomal protein, pericentrin, was found tightly localized adjacent to nuclear lamina in UR, lacking any MT nucleation activity. In concordance with the competency to resume meiosis, an increase in the amount and nucleation capacity of pericentrin is noted. In FR, cytoplasmic MT almost disappeared while de-novo microtubule polymerization was found in small aggregates of pericentrin localized around the nucleus. Towards the end of DON and CC, a sudden burst of pericentrin was noted with an extreme MT nucleation activity in an organized fashion that is essential for the rapid formation of ®rst meiotic spindle. The results show that centrosomes display precisely controlled spatio-temporal changes during the onset of meiotic maturation. Accumulation of centrosomal proteins to a single locus followed by a sequestration to several spots might be evidence of a mechanism by which the proper distribution of centrosomal material during nuclear breakdown and subsequently formation of spindle are regulated in concordance with the nuclear maturation.
Theriogenology, 2012
A nonhuman primate model was applied to investigate the relationships between variations in the organization of microtubules, microfilaments, and chromatin in metaphase I and metaphase II oocytes. Marmoset oocytes were subjected to in vitro maturation and coincubation with sperm. Oocytes which failed to cleave were investigated for chromatin, tubulin, and actin using Hoechst 33258, fluorescein isothiocyanate (FITC)-labeled alpha-tubulin antibody and rhodamine-labeled phalloidin, respectively. Spindles were categorized according to size, shape and microtubule organization: normal, large, multipolar, disorganized, absent spindle, and spindles with broad poles. Actin caps were categorized as: normal, small, split, and disorganized. Chromosomal condensation and alignment were described as normal or abnormal. Improper chromosomal condensation was associated with both abnormal microfilament and microtubule arrangement. This was further associated with abnormal actin organization, disorientation and late stabilization of microtubules, but not related to abnormal organization of spindle poles. Chromosomal misalignment was associated with disorientation and late stabilization of tubulin, but not to broad spindle pole. Additionally, abnormal actin polarization appeared not to be related to abnormal spindle poles. The model system presented in this study could be used as an experimental platform for studying the contribution of different factors to the exactness of late meiotic events in primate oocytes. The present study provides basic information on spindle, chromosome, and actin normal and abnormal organization, which can be observed in in vitro matured, but failed to cleave primate oocytes.
Biology of Reproduction, 1997
The cytoskeletal components of hamster oocytes, zygotes, and spontaneously activated parthogenotes were examined after immunocytochemical labeling. Microtubules were found only in the anastral, tangentially arranged second meiotic spindle of unfertilized oocytes. Taxol treatment of unfertilized oocytes greatly augmented astral microtubules in both the metaphase II spindle and the cortex. Disruption of the meiotic spindle microtubules with nocodazole resulted in cortical chromosomal scattering. During hamster sperm incorporation and pronuclear formation, no sperm aster was detected in association with the male DNA. Instead, a large overlapping array of microtubules assembled in the cortex. By mitosis, this interphase array disassembled and an anastral metaphase spindle formed. Microtubule and chromatin configurations were also imaged in hamster oocytes injected with human sperm. Astral microtubules were absent from the sperm centrosome. The implications of these results are discussed in relation to the hamster oocyte penetration assay, a test commonly used by in vitro fertilization clinics to demonstrate the fertilizing ability of human sperm. We conclude that since hamsters and humans follow different methods of centrosome inheritance, maternal and paternal, respectively, the hamster may be an inappropriate model for exploring microtubule and centrosomal defects in humans or for assaying postinsemination forms of human male fertility defects.
Biology of Reproduction, 2003
To better understand the differences in cytoskeletal organization between in vivo (IVO) and in vitro (IVM) matured oocytes, we analyzed remodeling of the centrosome-microtubule complex in IVO and IVM mouse oocytes. Fluorescence imaging revealed dramatic differences in meiotic spindle assembly and organization between these two populations. Metaphase spindles at both meiosis I (M-I) and meiosis II (M-II) in IVO oocytes were compact, displayed focused spindle poles with distinct ␥tubulin foci, and were composed of acetylated microtubules. In contrast, IVM oocytes exhibited barrel-shaped spindles with fewer acetylated microtubules and ␥-tubulin diffusely distributed throughout the spindle proper. With respect to meiotic progression, IVO oocytes were more synchronous in the rate and extent of anaphase to telophase of M-I and first polar body emission than were IVM counterparts. Furthermore, IVO oocytes showed a twofold increase in cytoplasmic microtubule organizing centers (MTOCs), and constitutive MTOC proteins (␥-tubulin and pericentrin) were excluded from the first polar body. Inclusion of MTOC constitutive proteins in the polar body and diminished number of cytoplasmic MTOCs was observed in IVM oocytes. These findings were corroborated in IVO oocytes obtained from naturally ovulated and spontaneously cycling mice and highlight a fundamental distinction in the spatial and temporal regulation of microtubule dynamics between IVO and IVM oocytes assisted reproductive technology, meiosis, oocyte development
Biology of Reproduction, 2003
To better understand the differences in cytoskeletal organization between in vivo (IVO) and in vitro (IVM) matured oocytes, we analyzed remodeling of the centrosome-microtubule complex in IVO and IVM mouse oocytes. Fluorescence imaging revealed dramatic differences in meiotic spindle assembly and organization between these two populations. Metaphase spindles at both meiosis I (M-I) and meiosis II (M-II) in IVO oocytes were compact, displayed focused spindle poles with distinct ␥tubulin foci, and were composed of acetylated microtubules. In contrast, IVM oocytes exhibited barrel-shaped spindles with fewer acetylated microtubules and ␥-tubulin diffusely distributed throughout the spindle proper. With respect to meiotic progression, IVO oocytes were more synchronous in the rate and extent of anaphase to telophase of M-I and first polar body emission than were IVM counterparts. Furthermore, IVO oocytes showed a twofold increase in cytoplasmic microtubule organizing centers (MTOCs), and constitutive MTOC proteins (␥-tubulin and pericentrin) were excluded from the first polar body. Inclusion of MTOC constitutive proteins in the polar body and diminished number of cytoplasmic MTOCs was observed in IVM oocytes. These findings were corroborated in IVO oocytes obtained from naturally ovulated and spontaneously cycling mice and highlight a fundamental distinction in the spatial and temporal regulation of microtubule dynamics between IVO and IVM oocytes assisted reproductive technology, meiosis, oocyte development
Human Reproduction, 2003
BACKGROUND: While a complete failure of meiotic maturation following hCG administration is rare during IVF cycles, cases arise in which patients repeatedly display a high incidence of failure to complete maturation to metaphase II (MII) in vivo. For the immature oocytes of such patients, our objectives were (i) to ask whether progression to MII could be supported in vitro, and (ii) to de®ne their microtubule/chromatin properties following in-vitro maturation (IVM). Together, these studies were aimed at augmenting our understanding of factors underlying meiotic arrest in the human. METHODS: Cases are presented here for two patients (A and B) producing oocytes that recurrently showed the inability to mature to metaphase II in vivo. Following IVM attempts, chromatin and microtubule characteristics were identi®ed in those oocytes that remained arrested during meiosis I. RESULTS: In patient A, meiotically arrested oocytes exhibited clear defects in spindle and chromatin arrangements. In contrast, the majority of oocytes from patient B displayed normal MI and MII spindles with aligned chromosomes, although some oocytes exhibited indications for possible defects in cell cycle control. CONCLUSIONS: Together, these analyses illustrate two cases with oocytes exhibiting a common gross defect, that is meiotic maturation arrest, but revealing different aetiologies or manifestations as evidenced by the presence or absence of abnormal spindle/chromatin organization. This work reinforces the existence of intrinsic defects in oocytes of some patients, the molecular and cellular bases of which merit further investigation.
Centrosome dynamics during the meiotic progression in the mouse oocyte
European journal of clinical chemistry and clinical biochemistry: journal of the Forum of European Clinical Chemistry Societies
The centrosome is the most important microtubule organizing centre and a major point for microtubule growth within the cell. Because of their microtubule nucleating capacity, centrosomes are responsible for many functions, such as the organization of the interphase cytoskeleton and cytoplasm and the formation of the mitotic spindle. Centrosomes are known to participate in the location of the cleavage furrow during cytokinesis (1). In this context, it is useful to note that several types of proteins including motor molecules such as kinesin and dynein , microtubule-associated proteins such as the microtubule associated protein MAPI (4), Ca/calmodulin kinase II (5), centractin and centrin (6) are associated with centrosomes.
Proceedings of the National Academy of Sciences, 1985
Microtubules forming within the mouse egg during fertilization are required for the movements leading to the union of the sperm and egg nuclei (male and female pronuclei, respectively). In the unfertilized oocyte, microtubules are predominantly found in the arrested meiotic spindle. At the time for sperm incorporation, a dozen cytoplasmic asters assemble, often associated with the pronuclei. As the pronuclei move to the egg center, these asters enlarge into a dense array. At the end of first interphase, the dense array disassembles and is replaced by sheaths of microtubules surrounding the adjacent pronuclei. Syngamy (pronuclear fusion) is not observed; rather the adjacent paternal and maternal chromosome sets first meet at metaphase. The mitotic apparatus emerges from these perinuclear microtubules and is barrelshaped and anastral, reminiscent of plant cell spindles; the sperm centriole does not nucleate mitotic microtubules. After cleavage, monasters extend from each blastomere nucleus. The second division mitotic spindles also have broad poles, though by third and later diisions the spindles are typical for higher animals, with narrow mitotic poles and fusiform shapes. Colcemid, griseofulvin, and nocodazole inhibit the microtubule formation and prevent the movements leading to pronuclear union; the meiotic spindle is disassembled, and the maternal chromosomes are scattered throughout the oocyte cortex. These results indicate that microtubules forming within fertilized mouse oocytes are required for the union of the sperm and egg nuclei and raise questions about the paternal inheritance of centrioles in mammals.
Levels of microtubules during the meiotic maturation of the Xenopus oocyte
Journal of cell science, 1987
The total level of tubulin and the ratio of polymeric tubulin to tubulin dimer were measured by a colchicine filter-binding assay during meiotic maturation of the Xenopus oocyte. Although the total level of tubulin remains unchanged (0.12 +/- 0.03 micrograms/oocyte), the level of polymeric tubulin decreases during maturation (25% in prophase oocytes versus 20% in metaphase oocytes). The percentage of polymerized tubulin was estimated after drug (nocodazole and taxol) treatments and cold treatment in prophase and progesterone-matured oocytes; in all cases the microtubules present in mature oocyte are less stable than prophase microtubules. The presence of the nucleus modifies neither the level nor the stability of prophase microtubules. Our quantitative results as well as cytological arguments suggest that full-grown Xenopus oocytes may contain a cortical microtubular array.