Allocation of Gamma-Tubulin Between Oocyte Cortex and Meiotic Spindle Influences Asymmetric Cytokinesis in the Mouse Oocyte1

In oocytes, asymmetric cytokinesis represents a conserved strategy for karyokinesis during meiosis to retain ooplasmic maternal factors needed after fertilization. Given the role of gamma-tubulin in cell cycle progression and microtubule dynamics, this study focused on gamma-tubulin as a key regulator of asymmetric cytokinesis in mouse oocytes. Gamma-tubulin properties were studied using multiple-label digital imaging, Western blots, quantitative RT-PCR, and microinjection strategies in mouse oocytes matured in vivo (IVO) or in vitro (IVM). Quantitative image analysis established that IVO oocytes extrude smaller first polar bodies (PBs), contain smaller spindles, and have more cytoplasmic microtubule organizing centers (MTOCs) relative to IVM oocytes. Maturation in culture was shown to alter gamma-tubulin distribution, as evidenced by incorporation throughout the meiotic spindle and within the first PB. Western blot analysis confirmed that total gamma-tubulin content remained elevated in IVM oocytes compared with IVO oocytes. Analysis of gamma-tubulin mRNA during maturation revealed fluctuations in IVO oocytes, whereas IVM oocytes maintained relatively stable at lower levels for the time points examined (0-16 h). Selective reduction of gamma-tubulin mRNA by injection of siRNA diminished both spindle and PB size, whereas overexpression of enhanced green fluorescent protein gamma-tubulin had the opposite effect. Together, these studies reinforce the notion that limiting gamma-tubulin availability during meiotic maturation ensures coordination of karyokinesis and cytokinesis and conservation of gamma-tubulin as an embryonic reserve.

Localized activation of Src-family protein kinases in the mouse egg

Recent studies in species that fertilize externally have demonstrated that fertilization triggers localized activation of Src-family protein kinases in the egg cortex. However, the requirement for Src-family kinases in activation of the mammalian egg is different from lower species and the objective of this study was to characterize changes in the distribution and activity of Src-family protein tyrosine kinases (PTKs) during zygotic development in the mouse. Immunofluorescence analysis of mouse oocytes and zygotes with an anti-phosphotyrosine antibody revealed that fertilization stimulated accumulation of P-Tyr-containing proteins in the egg cortex and that their abundance was elevated in the region overlying the MII spindle. In addition, the poles of the MII spindle exhibited elevated P-Tyr levels. As polar body extrusion progressed, P-Tyr-containing proteins were especially concentrated in the region of cortex adjacent to the maternal chromatin and the forming polar body. In contrast, P-Tyr labeling of the spindle poles eventually disappeared as meiosis II progressed to anaphase II. In approximately 24% of cases, the fertilizing sperm nucleus was associated with increased P-Tyr labeling in the overlying cortex and oolemma. To determine whether Src-family protein tyrosine kinases could be responsible for the observed changes in the distribution of P-Tyr containing proteins, an antibody to the activated form of Src-family PTKs was used to localize activated Src, Fyn or Yes. Activated Src-family kinases were found to be strongly associated with the meiotic spindle at all stages of meiosis II; however, no concentration of labeling was evident at the egg cortex. The absence of cortical Src-family PTK activity continued until the blastocyst stage when strong cortical activity became evident. At the pronuclear stage, activated Src-family PTKs became concentrated around the pronuclei in close association with the nuclear envelope. This pattern was unique to the earliest stages of development and disappeared by the eight cell stage. Functional studies using chemical inhibitors and a dominant-negative Fyn construct demonstrated that Src-family PTKs play an essential role in completion of meiosis II following fertilization and progression from the pronuclear stage into mitosis. These data suggest that while Src-family PTKs are not required for fertilization-induced calcium oscillations, they do play a critical role in development of the zygote. Furthermore, activation of these kinases in the mouse egg is limited to distinct regions and occurs at specific times after fertilization.

Germline stem cells and neo-oogenesis in the adult human ovary

It remains unclear whether neo-oogenesis occurs in postnatal ovaries of mammals, based on studies in mice. We thought to test whether adult human ovaries contain germline stem cells (GSCs) and undergo neo-oogenesis. Rather than using genetic manipulation which is unethical in humans, we took the approach of analyzing the expression of meiotic marker genes and genes for germ cell proliferation, which are required for neo-oogenesis, in adult human ovaries covering an age range from 28 to 53 years old, compared to testis and fetal ovaries served as positive controls. We show that active meiosis, neo-oogenesis and GSCs are unlikely to exist in normal, adult, human ovaries. No early meiotic-specific or oogenesis-associated mRNAs for SPO11, PRDM9, SCP1, TERT and NOBOX were detectable in adult human ovaries using RT-PCR, compared to fetal ovary and adult testis controls. These findings are further corroborated by the absence of early meiocytes and proliferating germ cells in adult human ovarian cortex probed with markers for meiosis (SCP3), oogonium (OCT3/4, c-KIT), and cell cycle progression (Ki-67, PCNA), in contrast to fetal ovary controls. If postnatal oogenesis is confirmed in mice, then this species would represent an exception to the rule that neo-oogenesis does not occur in adults.

Clinical applications and limitations of current ovarian stem cell research: a review

The publication of a report in Nature in 2004 by the Tilly group suggesting that mouse ovaries are capable of generating oocytes de novo post-natally, has sparked interest in a problem long thought to have been resolved from classical studies in a variety of mammalian species. Within a nearly two year time period, laboratories around the world have taken up the challenge to dogma raised by this initial report, either to test this concept in an experimental basic science setting or give direction to clinical applications that could result, were the original premises of this work in the mouse valid for extrapolation to humans. This review provides a status report for this promising area of research, (1) to summarize recent findings in the literature with respect to the validity of the original hypothesis proffered by the Tilly group, and, (2) to gauge the potential utility of ovarian stem cells as a treatment for certain forms of human infertility.

Fate of centrosomes following somatic cell nuclear transfer (SCNT) in bovine oocytes

Cloning mammalians by somatic cell nuclear transfer (SCNT) remains inefficient. A majority of clones produced by SCNT fail to develop properly and of those which do survive, some exhibit early aging, premature death, tumors, and other pathologies associated with aneuploidy. Alterations of centrosomes are linked to aberrant cell cycle progression, aneuploidy, and tumorigenesis in many cell types. It remains to be determined how centrosomes are remodeled in cloned bovine embryos. We show that abnormalities in either distribution and/or number of centrosomes were evident in approximately 50% of reconstructed embryos following SCNT. Moreover, centrosome abnormalities and failed ‘pronuclear’ migration which manifested during the first cell cycle coincided with errors in spindle morphogenesis, chromosome alignment, and cytokinesis. By contrast, nuclear mitotic apparatus protein (NuMA) exhibited normal expression patterns at metaphase spindle poles and in ‘pronucleus’ during interphase. The defects in centrosome remodeling and ‘pronuclear’ migration could lead to chromosome instability and developmental failures associated with embryo production by SCNT. Addressing these fundamental problems may enhance production of normal clones.

Genetic strain variations in the metaphase-II phenotype of mouse oocytes matured in vivo or in vitro

The interplay between genetic and epigenetic factors plays a central role in mammalian embryo production strategies that superimposeex vivoorin vivomanipulations upon strain background characteristics. In this study, we examined the relationship between genetic background and the phenotypic properties of mouse metaphase-II (M-II) oocytes that were matured underin vivo(IVO) orin vitroconditions, either in a basal (IVM) or a supplemented (IVM + ) medium. Differences existed amongst inbred (C57BL/6), outbred (CF-1, Black Swiss, NU/NU) and hybrid lines (B6D2F1) induced to superovulate with regard to cytoplasmic microtubule organizing center (MTOC) number but not spindle size or shape, except for larger and asymmetrical spindles in Black Swiss oocytes. When oocytes were matured in culture, meiotic spindle and cytoplasmic phenotypic properties of M-II oocytes were affected relative toin vivoconditions and between strains. Specifically, measures of meiotic spindle size, shape, polar pericentrin distribution and cytoplasmic MTOC number all revealed characteristic variations. Interestingly, the overall reduction in cytoplasmic MTOC number noted upon IVM was concomitant with an overall increase in spindle and polar body size. Maturation under IVM + conditions resulted in a further decrease in cytoplasmic MTOC number, but spindle and polar body characteristics were intermediate between IVO and IVM. How these oocyte phenotypic properties of maternal origin may be linked to predictive assessments of fecundity remains to be established.

In vitro maturation of human oocytes and cumulus cells using a co-culture three-dimensional collagen gel system

BACKGROUND

Deficiencies remain in the ability of in vitro-matured human oocytes to acquire full developmental competence and give rise to a healthy pregnancy. A clear deficiency of current systems utilizing human oocytes has been the absence of cumulus cells. In the present study, a three-dimensional (3D) co-culture system exploiting an extracellular matrix was developed and compared to conventional methods for its ability to support maturation of human oocytes.

METHODS AND RESULTS

Cumulus cells were embedded into a 3D collagen gel matrix with individual oocytes added to each gel. Oocytes from the same patient cultured in the gel matrix matured to metaphase II at rates similar to those of cumulus-free oocytes cultured in individual microdrops. Following maturation of oocytes and fixation of intact gels, chromatin and cytoskeletal elements were assessed in oocytes and cumulus cells. The activities of the key cell cycle kinases, maturation-promoting factor (MPF) and mitogen-activated protein kinase (MAPK), were compared in oocytes matured under the two culture conditions. Compared with denuded oocytes, co-cultured oocytes exhibited increased MAPK activity, but no difference in MPF levels.

CONCLUSIONS

This work characterizes a novel and efficacious culture system that takes advantage of the unique properties of the extracellular matrix, a 3D microenvironment, and the presence of cumulus cells for maturing human oocytes in vitro.

Hormonal control of somatic cell oocyte interactions during ovarian follicle development

In the mammalian ovarian follicle, paracrine signaling between the oocyte and somatic granulosa cells is bidirectional but the structural basis and physiological regulations of communication between gametic and somatic compartments remain unknown. The present experiments were designed to test the hypothesis that follicle stimulating hormone (FSH) regulates the ability of granulosa cells to make connections with the oocyte. We show that in prepubertal unprimed mice and mice carrying a targeted deletion of the FSHbeta subunit gene, granulosa cells exhibit orientation towards the oocyte manifest by the elaboration of transzonal projections (TZPs) and "apical" centrosome positioning at sites of granulosa-zona contact. In vivo FSH treatment results in a retraction of TZPs. Coincident with TZP retraction induced by FSH are changes in oocyte transcriptional activity and meiotic competence, which suggests one means by which the oocyte-granulosa cell dialogue may be modulated during development of ovarian follicles.

The developmental origins of mammalian oocyte polarity

Drosophila has been an excellent model system to study the cell and molecular determinants of oocyte axis specification, a problem which is little known in mammalian species. Recent evidence supports the notion that mammalian oocytes utilize axis-orienting properties during the course of oogenesis. Among these, axis specification in relation to the oocyte cortex, germinal vesicle (GV) position, anchoring of GV and spindle, and patterning of follicle cell/oocyte attachments are proposed as conserved features of oogenesis in mammals that may be important to the survival and development of the preimplantation embryo.

Effect of genetic background and activating stimulus on the timing of meiotic cell cycle progression in parthenogenetically activated mouse oocytes

With the aim of investigating the effects of oocyte genotype and activating stimulus on the timing of nuclear events after activation, oocytes collected from hybrid B6D2F1, inbred C57BL/6 and outbred CF-1 and immunodeficient nude (NU/+) females were activated using ethanol or strontium and fixed at various time-points. Meiotic status, spindle rotation and second polar body (PB2) extrusion were monitored by fluorescence microscopy using DNA-, microtubule- and microfilament-selective probes. Although activation efficiency was similar in all groups of oocytes, a significant percentage of CF-1 and NU/+ oocytes treated with ethanol and of C57BL/6 oocytes treated either with ethanol or strontium failed to complete activation and became arrested at a new metaphase stage (MIII) after PB2 extrusion. C57BL/6 oocytes also showed slower release from MII arrest but faster progression to telophase (TII) after ethanol exposure, and they exhibited the most rapid exit from TII under both activation treatments. Strontium caused delayed meiotic resumption, spindle rotation and PB2 extrusion, but rapid TII exit, in B6D2F1, CF-1 and NU/+ oocytes when compared with ethanol. Compared with all other strains, NU/+ oocytes were significantly slower in completing spindle rotation and PB2 extrusion, irrespective of the activating stimulus, and a significant decrease in activation rates and pace of meiotic progression was observed after strontium exposure. Thus, our findings demonstrated that the kinetics of meiosis resumption and completion, spindle rotation and PB2 extrusion following parthenogenetic activation depends on both genotype-specific factors and on the activation treatment applied.

Activated bovine cytoplasts prepared by demecolcine-induced enucleation support development of nuclear transfer embryos in vitro

Demecolcine-induced enucleation (IE) of mouse oocytes has been shown to improve development to term of cloned mice. In this study, we characterized the kinetics and morphological progression of bovine oocytes subjected to IE, and evaluated their ability to support embryo development to the blastocyst stage after nuclear transfer (NT). In vitro matured bovine oocytes were parthenogenetically activated and subsequently exposed to demecolcine at various times post-activation. Onset and duration of demecolcine treatment significantly altered activation and IE frequencies, which varied from 7.1% to 100% and 33.3% to 91.7%, respectively, at 5 hr post-activation. A significant decrease in IE frequencies was observed at 17 hr post-activation (3.4%-46.1%), possibly due to reincorporation of chromosomes into the oocyte after incomplete second polar body (PB) extrusion. Oocytes were reconstructed by NT before (treatment 1) or after (treatment 2) activation and demecolcine treatment, and cultured in vitro. Cleavage (48.1%-54.2%) and blastocyst rates (15.7%-19%) were equivalent for the two treatments, as well as the total cell number in NT blastocysts. Furthermore, most of the blastocysts were completely diploid (treatment 2) or heteroploid but with a majority of diploid nuclei (treatment 1). Our results demonstrate that the IE method can be successfully used to produce enucleated bovine cytoplasts that are competent to support development to the blastocyst stage after NT. This technically simple approach may provide a more efficient method to enhance the success rate of NT procedures. Further studies are needed to improve the in vitro development efficiency and to expand our understanding of the mechanism(s) involved in demecolcine-induced enucleation.

Meiotic spindle morphogenesis in in vivo and in vitro matured mouse oocytes: insights into the relationship between nuclear and cytoplasmic quality

BACKGROUND

This work addresses the hypothesis that events occurring within the follicle soon after the LH surge are essential for coordinating morphogenesis of the spindle and cytoplasm in mouse oocytes matured in vivo (IVO); we further tested whether in vitro maturation (IVM) fails to support these events.

METHODS

Oocytes collected at 1, 2, 3, 4 and 5 h post-hCG or after IVM were analyzed for chromatin, nuclear lamina, microtubules (MTs) and centrosomal proteins by conventional fluorescence and confocal microscopy. In addition, these parameters were monitored in oocytes maintained in 50 microM roscovitine, followed by IVM, or in oocytes retrieved at 1.5 and 5 h post-hCG in vivo and cultured up to 16 h.

RESULTS

A G2/M delay was observed in IVO oocytes based upon persistence of cytoplasmic MTs, nuclear lamina and centrosomes at the cortex; rapid meiotic progression in IVM oocytes was related to loss of these markers, indicating that a global activation of MPF occurred in culture. Also, maturating-promoting factor (MPF) inactivation resulted in cultured oocytes that exhibited IVO characteristics after drug removal. IVO-like characteristics were also exhibited by oocytes retrieved at 5 but not at 1.5 h after hCG treatment, even though these oocytes were subsequently cultured.

CONCLUSIONS

The results emphasize the importance of coupling MT remodeling and cell cycle components during oocyte maturation to achieve a balanced coordination of nuclear and cytoplasmic maturation that under physiological conditions occurs within the first 5 h of LH stimulation.

Distinctions in meiotic spindle structure and assembly during in vitro and in vivo maturation of mouse oocytes

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 gamma-tubulin foci, and were composed of acetylated microtubules. In contrast, IVM oocytes exhibited barrel-shaped spindles with fewer acetylated microtubules and gamma-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 (gamma-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

Distinct microtubule and chromatin characteristics of human oocytes after failed in-vivo and in-vitro meiotic maturation

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 define 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 identified 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.

Origins and manifestations of oocyte maturation competencies

Mammalian oocytes acquire a series of competencies during follicular development that play critical roles at fertilization and subsequent stages of preimplantation embryonic development. These competencies involve remodelling of chromatin and the cytoskeleton in the oocyte at critical stages of folliculogenesis when gametes and somatic cells communicate by paracrine and junctional mechanisms. While the detailed steps involved in bi-directional signalling between oocytes and granulosa cells remain unknown, studies from mice bearing targeted deletions in essential 'communication' genes reveal selective disturbances in oocyte maturation competencies that compromise the oocyte's developmental potential. Recent data are reviewed that illustrate the general principle that competencies acquired at sequential stages of oogenesis are manifest during oocyte growth, maturation, or following fertilization. The recognition that oocyte-specific genes are called into play at key developmental transitions in mammalian embryogenesis emphasizes the importance of monitoring genetic and epigenetic determinants when using current assisted reproductive technologies manipulations.

Demecolcine-induced oocyte enucleation for somatic cell cloning: coordination between cell-cycle egress, kinetics of cortical cytoskeletal interactions, and second polar body extrusion

Studies were designed to further explore the use of pharmacological agents to produce developmentally competent enucleated mouse oocytes for animal cloning by somatic cell nuclear transfer. Metaphase II oocytes from CF-1 and B6D2F1 strains were activated with ethanol and subsequently exposed to demecolcine at various times postactivation. Chromosome segregation, spindle dynamics, and polar body (PB) extrusion were monitored by fluorescence microscopy using DNA-, microtubule-, and microfilament-selective probes. Exposure to demecolcine did not affect rates of oocyte activation induced by ethanol but did disrupt the coordination of cytokinesis and karyokinesis, suppressing the extent and completion of spindle rotation and second PB extrusion in a strain-dependent manner. Moreover, strain- and treatment-specific variations in the rate of oocyte enucleation were also detected. In particular, CF1 oocytes were more efficiently enucleated relative to B6D2F1 oocytes, and demecolcine treatments initiated early after activation resulted in higher enucleation rates than when treatment was delayed. The observed strain differences are possibly caused by a combination of factors, such as the time course of meiotic cell-cycle progression after ethanol activation, the degree of spindle rotation, and the extent of second PB extrusion. These results suggest that developmentally competent cytoplasts can be produced by timely exposure of activated oocytes to agents that disrupt spindle microtubules. However, the utility of the demecolcine-induced enucleation protocol will require further investigation into factors linking karyokinesis to cytokinesis at the levels of cell-cycle control and oocyte cytoskeletal remodeling following artificial or natural means of egg activation.

Assessment of oocyte quality following repeated gonadotropin stimulation in the mouse

The present study assessed the effects of repeated ovarian stimulation on oocyte quality. Female mice were stimulated with eCG and hCG at 1-wk intervals for 4 wk. Germinal vesicle (GV)-stage oocytes were evaluated in relation to size, somatic cell association, and chromatin organization after each week of stimulation. In addition, ATP content and expression of meiotic competence were monitored in GV and in vivo (IVO) or in vitro (IVM)-matured oocytes. The developmental competence of ovulated oocytes was determined after in vitro fertilization and embryo culture, and reproductive outcome was evaluated after mating following repeated cycles of stimulation. In GV oocytes, the degree of somatic cell association, size, and timing of transcriptional repression were altered when comparing repeated with single cycle(s) of stimulation. Meiotic competence expression was unaffected for IVO oocytes while IVM oocytes exhibited a progressive decrease in meiotic competence with repeated stimulation. The ATP content of immature and IVO oocytes decreased with repeated stimulation. Although after one cycle of stimulation ATP content was lower in IVM than IVO oocytes, IVM oocytes exhibited stable levels of ATP across cycles of stimulation. Last, the in vitro developmental competence of IVO oocytes retrieved after repeated stimulation was not significantly different, and in vivo, similar implantation and resorption rates were observed following mating of animals subjected to repeated stimulation. Therefore, despite measurable consequences of repeated stimulation on specific parameters of follicular oocyte quality, compensatory mechanisms may exist in vivo to optimize the developmental competence of ovulated oocytes in the mouse.

Oocyte-somatic cell communication

The physical interface between the female germ line and enveloping somatic cells is dynamically modified throughout the course of folliculogenesis. How selective pathways for communication between the oocyte and granulosa cell are established and regulated remains to be determined, but insights into the structural basis for this communication are emerging. This review summarizes the available evidence that supports the notion that the integration of oogenesis with folliculogenesis is achieved by regulated cell interactions between oocytes and granulosa cells.

Assessment of nuclear and cytoplasmic maturation in in-vitro matured human oocytes

BACKGROUND

With improved prospects for the use of human oocyte in-vitro maturation in assisted reproductive technologies, the need to define more clearly the coordination of nuclear and cytoplasmic maturation has arisen.

METHODS

Immunofluorescence and confocal microscopy were used to evaluate cell cycle-dependent modifications in chromatin and microtubules in human germinal vesicle oocytes (n = 455) undergoing in-vitro maturation.

RESULTS

Four distinct classes of germinal vesicle stage oocytes were identified based on the expression of G2/interphase characteristics, but, of these, only one class of oocytes was competent to complete meiotic progression to metaphase-II in vitro. The majority of germinal vesicle stage oocytes resumed meiosis within 6 h (88.9%) of culture and exhibited an accelerated pace of progression to metaphase-II (66.7%) over 24 h, but in general were unable to maintain meiotic arrest and defaulted into interphase within 24 h of polar body emission. Characterization of microtubule dynamics and chromatin phosphorylation demonstrates specific cell cycle deficiencies in in-vitro matured human oocytes.

CONCLUSION

This work forms a basis for future studies aimed at optimizing nuclear and cytoplasmic maturation during in-vitro maturation.

Microtubule patterning during meiotic maturation in mouse oocytes is determined by cell cycle-specific sorting and redistribution of gamma-tubulin

The topography of microtubule assembly events during meiotic maturation of animal oocytes demands tight spatial control and temporal precision. To better understand what regulates the timing and location of microtubule assembly, synchronously maturing mouse oocytes were evaluated with respect to gamma-tubulin, pericentrin, and total tubulin polymer fractions at specific stages of meiotic progression. gamma-Tubulin remained associated with cytoplasmic centrosomes through diakinesis of meiosis-1. Following chromatin condensation and perinuclear centrosome aggregation, gamma-tubulin relocated to a nuclear lamina-bounded compartment in which meiosis-1 spindle assembly occurred. gamma-Tubulin was stably associated with the meiotic spindle from prometaphase-1 through to anaphase-2, but also exhibited cell cycle-specific relocalization to cytoplasmic centrosomes. Specifically, anaphase onset of both meiosis-1 and -2 was characterized by the concomitant appearance of gamma-tubulin and microtubule nucleation in subcortical centrosomes. Brief pulses of taxol applied at specific cell cycle stages enhanced detection of gamma-tubulin compartmentalization, consistent with a gamma-tubulin localization-dependent spatial restriction of microtubule assembly during meiotic progression. In addition, a taxol pulse during meiotic resumption impaired subsequent gamma-tubulin sorting, resulting in monopolar spindle formation and cell cycle arrest in meiosis-1; despite cell cycle arrest, polar body extrusion occurred roughly on schedule. Therefore, sorting of gamma-tubulin is involved in both the timing of location of meiotic spindle assembly as well as the coordination of karyokinesis and cytokinesis in mouse oocytes.

A novel system for in vitro maturation of human oocytes

OBJECTIVE

To compare in vitro maturation of cumulus-free oocytes in glucose-free medium (P1) and standard medium (TC199).

DESIGN

Prospective, cohort study.

SETTING

Assisted reproductive technology program.

PATIENT(S)

One hundred eight patients undergoing ICSI.

INTERVENTION(S)

Germinal vesicle-stage or metaphase I--stage oocytes were allocated to culture with P1 or TC199. Metaphase II oocytes were fixed for immunofluorescence analysis or fluorescence in situ hybridization at 24 or 48 hours (or both). Media were compared by performing conditional logistic regression analysis that controlled for egg-specific factors.

MAIN OUTCOME MEASURE(S)

Proportion of mature oocytes and appearance of normal spindle-chromosome cytoarchitecture.

RESULT(S)

At 24 hours, more P1 oocytes than TC199 oocytes reached metaphase II (59.7% vs. 44.9%). At 48 hours, 71.7% of P1 oocytes and 61.0% of TC199 oocytes reached metaphase II, but this difference was not significant. Metaphase II oocytes in P1 were 34.3% more likely than those in TC199 to have a bipolar spindle with aligned chromosomes. Compared with oocytes at the germinal vesicle stage at 0 hour, those at metaphase I at 0 hour were more likely to progress to metaphase II (72.6% vs. 46.1% at 24 hours; 84.1% vs. 60.6% at 48 hours).

CONCLUSION(S)

P1 is superior to TC199 for in vitro maturation of granulosa-free human oocytes.

Cellular basis for paracrine regulation of ovarian follicle development

Paracrine factors secreted by oocytes and somatic cells regulate many important aspects of early ovarian follicle development in mammals. From activation of dormant primordial follicles to selection of secondary follicles, locally acting factors have been identified that appear to exert important effects on the growth and differentiation of oocytes and granulosa cells. This article summarizes evidence to support a model for bi-directional paracrine communication that is based on developmental regulation of the delivery and reception of paracrine factors at the oocyte-granulosa cell interface. Transzonal projections that originate from granulosa cells and terminate at the oocyte plasma membrane provide a polarized means to orient the secretory organelles of somatic cells. Characterization of transzonal projections in follicles from normal and genetically modified mice reveals dynamic changes in the density and stability of transzonal projections. On the basis of new data analysing the orientation and cytoskeletal content of transzonal projections in mammalian oocytes, a model is proposed for regulation of paracrine growth factor secretion by follicle-stimulating hormone. These findings have immediate implications for ovarian hyperstimulation protocols and follicle culture models as related to the production of mammalian embryos by assisted reproductive technologies.

Oocyte-granulosa cell heterologous gap junctions are required for the coordination of nuclear and cytoplasmic meiotic competence

Homologous gap junctions are generally recognized as a means of coordinating cellular behavior under developmental and homeostatic conditions. In the mammalian ovary, heterologous gap junctions between the oocyte and the granulosa cells have been widely implicated in the regulation of meiotic maturation late in oogenesis. However, the role of oocyte-granulosa cell gap junctions at earlier stages of oogenesis is poorly understood. Stage-specific defects in both oocyte and follicle development have been identified in juvenile mice deficient in heterologous oocyte-granulosa cell gap junctions due to targeted deletion of Gja4, the gene encoding connexin-37. Follicle development arrests at the type 4 preantral stage and although oocytes commence growth, oocyte growth ceases at a diameter of 52 microm (74.3% of control size). Analysis of cell cycle and cytoskeletal markers indicates that oocytes arrest in a G(2) state based on uniform decondensed GV chromatin, interphase microtubule arrays, and nonphosphorylated cytoplasmic centrosomes. Functional assays of meiotic competence confirm that oocytes from connexin-37-deficient mice are unable to enter M phase (initiate meiotic maturation) unless treated with the phosphatase inhibitor okadaic acid (OA). Unlike growing oocytes from heterozygous control animals, OA-treated oocytes from connexin-37-deficient mice respond acutely and progress rapidly to the circular bivalent stage of meiosis I and upon removal from OA rapidly revert to an interphase state. In contrast, OA-treated control incompetent oocytes are slow to respond, exhibit a lower proportion of chromosomal bivalent stage oocytes, but remain in and progress into meiotic M phase upon removal from OA. This study demonstrates that heterologous gap-junctional communication is required for the completion of oocyte growth and the acquisition of cytoplasmic meiotic competence.

Centrosome-specific perturbations during in vitro maturation of mouse oocytes exposed to cocaine

Previous studies indicating that cocaine may perturb meiotic chromosome segregation in mammalian oocytes prompted an analysis of the effects of cocaine on mouse oocytes matured in vitro under defined exposure conditions. Cumulus-enclosed mouse oocytes were matured in vitro in the continuous presence of cocaine and assessed for meiotic cell cycle progression and centrosome-microtubule organization using a combination of cytogenetic and fluorescence microscopic techniques. Both of these approaches demonstrated that cocaine had little effect on meiotic cell cycle progression to metaphase of meiosis-2 except at the highest dose tested (1000 microg/ml) where progression from metaphase-1 to metaphase-2 was inhibited. Cytogenetic analyses further showed that bivalent segregation was moderately affected and the incidence of premature centromere separation was significantly decreased following cocaine treatment. Under conditions of cocaine exposure, striking changes in meiotic spindle structure and cytoplasmic centrosome organization were observed. A 36% reduction in spindle length was associated with a loss of nonacetylated microtubules and fragmentation of spindle pole centrosomes. Moreover, in oocytes exposed to cocaine during maturation, a doubling in cytoplasmic centrosome number was observed. These results are discussed with respect to the relative roles of chromosomes and centrosomes in establishing and maintaining functional microtubule organization during meiosis in oocytes.

Sorting and reorganization of centrosomes during oocyte maturation in the mouse

In animal oocytes, the centrosome exists as an acentriolar aggregate of centrosomal material that is regulated in a dynamic manner throughout the process of meiotic maturation. Recently, it has been demonstrated that in female meiotic systems spindle assembly is likely regulated by chromosomal and microtubule/microtubule-associated influences. The purpose of this study was to analyze the distribution of the integral centrosomal protein, pericentrin, during the course of meiotic maturation. The function of the centrosome during meiotic progression was evaluated by exposing oocytes to pharmacological agents that perturb cytoplasmic homeostasis (cycloheximide, nocodazole, cytochalasin D, taxol, and vanadate). Pericentrin was localized to the spindle poles during metaphase of meiosis-I as O- and C-shaped structures. At anaphase, these structures fragment, become displaced from the spindle poles, and associate with the lateral spindle margin. The metaphase spindle at meiosis-II had incomplete pericentrin rings at both spindle poles. Vanadate treatment, a known inhibitor of dynein-ATPase, resulted in meiotic arrest, constriction of the spindle pole, and an aggregation of pericentrin at the spindle poles. After taxol exposure, pericentrin incorporation into both spindle poles and cytoplasmic centrosomes was increased. Treatment of oocytes with cycloheximide, nocodazole, and cytochalasin D, influenced early events associated with chromosome capture and spindle assembly and altered the number and distribution of cytoplasmic centrosomes. Thus, although pericentrin incorporation is not required for meiotic spindle formation, the dynamic reorganization of pericentrin and changes in centrosome microtubule nucleating capacity are involved in critical cell cycle transitions during meiotic maturation.

Taxol-induced meiotic maturation delay, spindle defects, and aneuploidy in mouse oocytes and zygotes

To increase our understanding about the potential risks of chemically-induced aneuploidy, more information about the various mechanisms of aneuploidy induction is needed, particularly in germ cells. Most chemicals that induce aneuploidy inhibit microtubule polymerization. However, taxol alters microtubule dynamics by enhancing polymerization and stabilizing the polymer fraction. We tested the hypothesis that taxol induces meiotic delay, spindle defects, and aneuploidy in mouse oocytes and zygotes. Super-ovulated ICR mice received 0 (control), 2.5, 5.0, and 7.5 mg/kg taxol intraperitoneally immediately after HCG. Females were paired (1:1) with males for 17 h after taxol treatment. Mated females were given colchicine 25 h after taxol and their one-cell zygotes were collected 16 h later. Ovulated oocytes from non-mated females were collected 17 h after taxol. Chromosomes were C-banded for cytogenetic analyses. Oocytes were also collected from another group of similarly treated females for in situ chromatin and microtubule analyses. Taxol significantly (p<0.01) enhanced the proportion of oocytes exhibiting parthenogenetic activation, chromosomes displaced from the meiotic spindle, and sister-chromatid separation. Moreover, 7.5 mg/kg taxol significantly (p<0.01) increased the proportions of metaphase I and diploid oocytes and polyploid zygotes. A significant (p<0.01) dose response for taxol-induced hyperploidy in oocytes and zygotes was found. These results support the hypothesis that taxol-induced meiotic delay and spindle defects contribute to aneuploid mouse oocytes and zygotes.

Characterization of oocyte and follicle development in growth differentiation factor-9-deficient mice

Female mice null for the oocyte-specific gene product, growth differentiation factor-9 (GDF-9), a member of the transforming growth factor-beta superfamily, exhibit primary infertility due to failed ovarian follicular development. The purpose of this study is to characterize oocyte and follicular differentiation as a function of animal age using cell culture and fluorescence, confocal, and electron microscopy. Analysis of follicles from GDF-9 homozygous mutant mice indicates that GDF-9-deficient oocytes grow more rapidly than control oocytes and that follicle growth ceases at the type 3b stage. Based on germinal vesicle (GV) chromatin patterns, fully grown oocytes isolated from GDF-9-deficient mice progress to advanced stages of differentiation equivalent to those found in antral follicles of control (heterozygous) mice. In vitro maturation of oocytes from homozygous mutant mice revealed that most oocytes are capable of resuming meiosis, with the ability to achieve meiotic completion reaching the highest levels in 6-week-old mice. Among the characteristic ultrastructural features of oocytes from homozygous mutant mice are perinuclear organelle aggregation, unusual peripheral Golgi complexes, and a failure to form cortical granules. Modified interconnections between granulosa cells and oocytes were also observed by ultrastructural (EM) and fluorescence microscopic analysis of follicles from GDF-9-deficient mice. These modifications included a decrease in the number of actin-based transzonal processes and modifications of microtubule-based projections that over time gave rise to invasion of the perivitelline space with eventual loss of oocyte viability. These cell-cell aberrations suggest a critical role for GDF-9 in the regulation of growth in preantral follicles through a mechanism involving bidirectional somatic cell-germ cell interactions.

Comparative aspects of meiotic cell cycle control in mammals

This review examines the mechanisms of cell cycle control in mammalian germ cells with respect to species-specific variations in reproductive strategies. While sex-specific variants are evidenced at the level of checkpoint controls, the timing of meiotic progression, and the modulation of meiosis by hormonal cues, local somatic cell influences impose a hierarchical order to both the initiation and completion of gametogenesis. In the particular case of meiosis in females the rules governing entry into meiotic prophase during gonadal development are generally conserved. In contrast, the regulation of meiotic arrest in developing ovarian follicles, the reinitiation of meiosis at ovulation, and the completion of meiosis upon fertilization involves changes in both the cell cycle machinery and execution of external cues. The overall efficiency of meiotic progression is determined by inputs, mediated by cell contact and/or growth factor, which coordinate oogenesis with folliculogenesis and ensure appropriate and species-specific ovulatory outputs (monovular or polyovular). How mechanisms of meiotic cell cycle control can be exploited to improve gamete quality or interfere with fertility is discussed.

Stage specific effects of carbendazim (MBC) on meiotic cell cycle progression in mouse oocytes

The effects of the pesticide carbendazim (MBC) on the in vitro meiotic maturation of mouse oocytes were evaluated using conventional and confocal fluorescence microscopy. The response of oocytes exposed to 0, 3, 10, or 30 microM MBC during meiotic maturation was analyzed with respect to chromosome organization, meiotic spindle microtubules, and cortical actin using fluorescent labels for each of these structures. Continuous exposure to MBC during the resumption of meiosis resulted in a dose-dependent inhibition of meiotic cell cycle progression at metaphase of meiosis-1. Drug exposure at the metaphase-anaphase transition of meiosis-1 did not interfere with cell cycle progression to metaphase-2 except at high concentrations (30 microM). At the level of spindle microtubule organization, MBC caused a loss of nonacetylated microtubules and a decrease in spindle size at 3 or 10 microM concentrations. Thirty microM MBC prevented spindle assembly when added at the beginning of meiotic maturation or caused spindle pole disruption and fragmentation when added to preformed spindles. Spindle disruption involved a loss of phosphoprotein epitopes, as monitored by MPM-2 staining, and resulted in the appearance of dispersed chromosomes that retained a metaphase-plate location on spindle fragments associated with the oocyte cortex. Polar body extrusion was impaired by MBC, and abnormal polar bodies were observed in most treated oocytes. The results suggest that MBC disrupts cell cycle progression in mouse oocytes by altering meiotic spindle microtubule stability and spindle pole integrity.

M-phase specific centrosome-microtubule alterations induced by the fungicide MBC in human granulosa cells

The mitostatic action of the commonly used fungicide methyl 2-benzimidazolecarbamate (MBC) was evaluated in primary cultures of human ovarian granulosa cells with respect to the organization and stability of spindle microtubules and mitotic centrosomes. MBC caused metaphase arrest and abnormal chromosome organization following a 3-15 h treatment at a concentration of 30 microM. While microtubules were retained in MBC-treated cells, alterations in spindle shape and microtubule composition were noted. Exposure to MBC resulted in an increased number of spindle poles associated with chromosomes displaced from the metaphase plate. A gradual increase from tri- to multipolar spindles was noted with prolonged treatment although a relatively constant fraction (50%) of bipolar spindles was maintained. In non-dividing cells, MBC had no effect on microtubule organization. Analysis of mitotic figures by immunofluorescence microscopy showed a reduction in interpolar and astral microtubules in response to MBC treatment while acetylated kinetochore microtubules were retained and their plus-ends were attached to metaphase chromosomes. In multipolar spindles, analysis of microtubule organizing centers (MTOCs) with antisera to stable centrosomal markers (SPJ and 5051) revealed that only poles associated with displaced chromosomes retained these markers. In contrast, transient centrosome markers (NuMA and centrophilin) were localized to all poles of multipolar spindles. Since MBC alters centrosome organization during mitosis, the results suggest that one mechanism of action of this agent is impairment of spindle microtubule dynamics at the centrosome.

Growth differentiation factor-9 is required during early ovarian folliculogenesis

Growth factors synthesized by ovarian somatic cells directly affect oocyte growth and function, but it is unclear whether oocyte-secreted factors play a reciprocal role in modulating somatic cell functions in vivo. During the functional analysis of members of the transforming growth factor-beta superfamily in mouse development, we have uncovered a new family member, growth differentiation factor-9 (GDF-9), which is required for ovarian folliculogenesis. GDF-9 messenger RNA is synthesized only in the oocyte from the primary one-layer follicle stage until after ovulation. Here we analyse ovaries from GDF-9-deficient female mice and demonstrate that primordial and primary one-layer follicles can be formed, but there is a block in follicular development beyond the primary one-layer follicle stage which leads to complete infertility. Oocyte growth and zona pellucida formation proceed normally, but other aspects of oocyte differentiation are compromised. Thus, GDF-9 is the first oocyte-derived growth factor required for somatic cell function in vivo.

Cryobiology of non-human primate oocytes

The responses to various stresses involved with cryopreservation protocols were investigated using non-human primate oocytes. Fluorescence microscopy was used to assess the status of the F-actin microfilament system of rhesus monkey oocytes after exposure to different concentrations of glycerol. The F-actin organization around the cortex and in the transzonal processes was modified by exposure to 1.0 ot 2.0 M glycerol at ambient temperature. These effects were reduced significantly when exposure to glycerol was combined with cooling to O degrees C. Cynomolgus monkey oocytes were also subjected to hyperosmotic stress and observed for morphological changes. An irregular shrinkage phenomenon was observed with germinal vesicle or metaphase I but not metaphase II (MII) oocytes. The irregular shrinkage became uniform and spherical when the oocytes were pretreated with ethyleneglycol-bis-(beta-aminoethyl ether)N,N,N'N' tetraacetic acid (EGTA) before exposure to hypertonic solution. Also, in-vitro-matured MII oocytes from cynomolgus monkeys were used to determine crucial biophysical parameters for freezing primate oocytes. The permeability of oocyte plasma membrane to water, Lpg, and its activation energy, ELp, were determined between 0 and -12 degrees C in the absence of cryoprotective additives. The Lpg was found to be 3.8x10(-14) m3N/s and the ELp was 141.5 kJ/mol. the pre-exponential kinetic and exponential thermodynamic parameters of intracellular ice formation were determined to be 8x108 m2/S and 2. 2x10(9) K5 respectively. By combining models of water transport and intracellular ice formation, the cumulative fraction of oocytes with intracellular ice as a function of the cooling rate was also predicted, and it was shown to correlate reasonably with experimental observations.

Chromatin organization, meiotic status and meiotic competence acquisition in mouse oocytes from cultured ovarian follicles

Changes in chromatin organization, meiotic status and the development of meiotic competence in oocytes retained within mouse ovarian follicles from day 0 to day 6 in culture were examined. The effects of exposure for 24 h to human luteinizing hormone (hLH) during the last day in culture was also determined. Preantral follicles from 22- to 24-day-old (prepubertal) mice develop antra and undergo significant growth from day 0 to day 4 in culture, after which the growth rates slow. The statistical significance of meiotic progression was examined using exact logistical regression analysis, which is particularly useful when the data are sparse and unbalanced. The transition from rimmed to unrimmed germinal vesicle stages was found to occur between day 2 and day 4 of follicle culture and was not influenced by exposure to hLH. Treatment with hLH caused a significant increase in the proportion of intrafollicular oocytes resuming meiosis. Assays of meiotic competence performed in vitro in oocytes retrieved from cultured follicles demonstrated that the transition from an unrimmed to a rimmed state is closely coincident with the acquisition and expression of meiotic competence. Forty-six per cent of competent oocytes from follicle cultures at day 3 progressed to metaphase II. These results indicate that the follicle culture system used in these studies supports the transformation of enclosed oocytes from a precompetent to a competent state and can maintain meiotic arrest for up to 6 days in culture. However, an increasing proportion of oocytes exhibit abnormal meiotic progression with continued follicle culture beyond 4 days.

Unusual cytoskeletal and chromatin configurations in mouse oocytes that are atypical in meiotic progression

Meiotic maturation progresses atypically in oocytes of strain LT/Sv and I/LnJ mice. LT/Sv occytes show a high frequency of metaphase I-arrest and parthenogenetic activation. I/LnJ oocytes display retarded kinetics of meiotic maturation and a high frequency of metaphase I-arrest. Some I/LnJ oocytes fail to resume meiosis. Changes in the configuration of chromatin, microtubules, and centrosomes are associated with specific stages of meiotic progression. In this study, the configuration of these subcellular components was examined in LT/Sv, I/LnJ, and C57BL/6J (control) oocytes either freshly isolated from large antral follicles or after culture for 15 hr to allow progression of spontaneous meiotic maturation. Differences were found in the organization of chromatin, microtubules, and centrosomes in LT/Sv and I/LnJ oocytes compared to control oocytes. For example, rather than exhibiting multiple cytoplasmic and nuclear centrosomes as in the normal germinal vesicle-stage oocytes, LT/Sv oocytes typically contain a single large centrosome. In contrast, I/LnJ oocytes displayed many small centrosomes. The microtubules of normal germinal vesicle-stage oocytes were organized as arrays or asters, but microtubules were shorter in LT/Sv oocytes and absent from I/LnJ oocytes. After a 15-hr culture, centrosomal material of normal metaphase II oocytes was organized at both spindle poles. In contrast, metaphase I-arrested LT/Sv oocytes exhibited an elongated spindle with centrosomal material appearing more organized at one pole of the spindle. Both control and LT/Sv oocytes displayed cytoplasmic centrosomes.(ABSTRACT TRUNCATED AT 250 WORDS)

Hormonal regulation of meiotic maturation in the hamster oocyte involves a cytoskeleton-mediated process

Maturation of the mammalian oocyte involves hormone-induced meiotic cell cycle progression from prophase I to metaphase II and extrusion of the first polar body (PB). In this study, the effects of gonadotrophins on meiotic cell cycle progression in cultured hamster oocytes were analyzed with respect to changes in cumulus cell-oocyte interactions and the oocyte cytoskeleton. Cumulus-oocyte complexes were obtained from large antral follicles (> or = 700 microns in diameter) of eCG-primed animals and were cultured in the presence or absence of gonadotropins alone (FSH, hCG, LH) or in combination (FSH + hCG or FSH + LH). Oocytes were analyzed using conventional, digital, and confocal fluorescence microscopy to monitor chromatin, actin, and tubulin organization under different culture conditions. Most oocytes (83%) cultured with FSH alone progressed to and arrested at metaphase II and extruded the first PB; in contrast, meiotic progression and PB extrusion were impaired (45-85%) in all other groups. The presence of cumulus cells associated with the oocyte was found necessary for progression to metaphase I and for first PB emission. Completion of meiotic maturation in the presence of FSH alone was correlated with enhanced cortical actin polymerization in the oocyte and the retraction of actin-containing transzonal cumulus processes. The results demonstrate that gonadotropins exert specific effects on meiotic progression, PB emission, cumulus-oocyte interactions, and oocyte cytoskeletal organization during in vitro maturation of hamster oocytes, indicating that the hormonal control of meiosis involves cytoskeletal changes in both the somatic and germ cells.

Patterns of intercellular connectivity in the mammalian cumulus-oocyte complex

Electron and fluorescence microscopic techniques have been used in a complementary fashion to study the patterns of follicle cell-oocyte interactions within cumulus-oocyte-complexes of various mammals. The principal findings are: (1) two distinct types of transzonal processes exist that are distinguishable on the basis of cytoskeletal composition; (2) in some of the species examined (pig, goat, primate), corkscrew-shaped processes rich in tubulin, traverse the zona pellucida and are invaginated into the oocyte cortex; (3) actin-rich processes either ramify as a network at the outer surface of the zona pellucida or penetrate the zona and make contact with the oolemma in a species specific manner. These results are discussed with respect both to the need to employ complementary optical methods in assessing connectivity patterns within COC and to the possible role that extracellular matrix-cell interactions play in the homeostatic control of oocyte growth and maturation.

Meiotic maturation in cultured bovine oocytes is accompanied by remodeling of the cumulus cell cytoskeleton

Mammalian oocyte maturation and cumulus expansion are hormone-induced contemporaneous processes that involve changes in cumulus cell shape and in the interactions between cumulus cells and the oocyte. Laser scanning confocal and conventional fluorescence microscopy have been used to study the relationship between reorganization of the cumulus cell cytoskeleton and meiotic progression in bovine cumulus oocyte complexes (COCs) matured in vitro. Inclusion of hormone supplements (FSH, LH, E2) in the maturation media was required for meiotic progression to metaphase 2 and maximal cumulus expansion. Under these conditions, stage-specific changes in the cytoskeletal content and organization of cumulus cell transzonal processes was observed. Specifically, abundant, actin-filled transzonal processes were observed in GV stage COCs. In stages intermediate in the maturation process (10 hr culture), fewer actin-filled transzonal processes were seen and microtubule-filled transzonal processes became apparent. At the end of maturation (24 hr culture), numerous, elongate microtubule rich transzonal processes were evident and actin-filled processes were rarely observed. Additionally, a spatial relationship between microtubule rich transzonal processes and oocyte chromatin was consistently observed in all stages of oocytes examined. These results indicate that bovine oocyte maturation in culture involves modifications of the cumulus cell cytoskeleton that may regulate the onset, progression, and completion of oocyte maturation.

Cytoplasmic microtubular dynamics and chromatin organization during mammalian oogenesis and oocyte maturation

A chronological series of coordinated alterations in oocyte chromosome and microtubule disposition occur during oogenesis and oocyte maturation in the mammal. Timely transitions in meiotic spindle and cytoplasmic microtubules, due to modifications in both the assembly competence of the tubulin pool and nucleation capacity of centrosomes, underscore key nuclear events during the progressive stages of meiosis I and II. The regulation of these transitional states during meiosis is discussed with respect to hormonal influences imparted to the oocyte within the follicular microenvironment, and the possible ways in which environmental perturbations may result in defective chromosomal partitioning during meiosis.

Protein synthesis requirements during resumption of meiosis in the hamster oocyte: early nuclear and microtubule configurations

The organization of chromatin and cytoplasmic microtubules changes abruptly at M-phase entry in both mitotic and meiotic cell cycles. To determine whether the early nuclear and cytoplasmic events associated with meiotic resumption are dependent on protein synthesis, cumulus-enclosed hamster oocytes were cultured in the presence of 100 micrograms/ml puromycin or cycloheximide for 5 hr. Both control (untreated) and treated oocytes were analyzed by fluorescence microscopy after staining with Hoechst 33258 and tubulin antibodies. Freshly isolated oocytes exhibit prominent nucleoli and diffuse chromatin within the germinal vesicle as well as an interphase network of cytoplasmic microtubules. After 4-4.5 hr in culture, most oocytes were in prometaphase I of meiosis as characterized by a prominent spindle with fully condensed chromosomes and numerous cytoplasmic asters. After 5-5.5 hr in culture, microtubule asters are no longer detected in most cells, and the spindle is the only tubulin-positive structure. Incubation for 5 hr in the presence of inhibitors does not impair germinal vesicle breakdown, chromatin condensation, kinetochore microtubule assembly, or cytoplasmic aster formation in the majority of oocytes examined; however, under these conditions, a population of oocytes retains a germinal vesicle, exhibiting variable degrees of chromatin condensation and cytoplasmic aster formation. Meiotic spindle formation is inhibited in all oocytes. These effects are fully reversible upon culture of treated oocytes in drug-free medium for 5 hr. The data indicate that meiotic spindle assembly is dependent on ongoing protein synthesis in the cumulus-enclosed hamster oocyte; in contrast, chromatin condensation and aster formation are not as sensitive to protein synthesis inhibitors during meiotic resumption.

Centrosome phosphorylation and the developmental expression of meiotic competence in mouse oocytes

Previous studies suggested that the transition from an incompetent to a competent meiotic state during the course of oogenesis in the mouse involved a G2/M-like cell cycle transition (Wickramasinghe et al, 1991. Dev. Biol. 143, 162). The present studies tested the hypothesis that centrosome phosphorylation, an event normally induced by MPF, is required for this developmental transition and the expression of meiotic competence in cultured growing mouse oocytes. Multiple fluorescence labeling techniques were used to evaluate centrosome number, phosphorylation status, and microtubule nucleating capacity in competent and incompetent oocytes. Experimental conditions were established for reversibly altering the phosphorylation status of the centrosomes and the effects of these treatments on meiotic resumption were examined. Phosphorylated centrosomes nucleating short microtubules were observed in competent oocytes, whereas nonphosphorylated centrosomes and interphase microtubule arrays were found in incompetent oocytes. Upon recovery from nocodazole-induced microtubule depolymerization, short microtubules formed from centrosomes in competent oocytes, whereas long microtubules reappear in the cytoplasm of incompetent oocytes. Perturbation of the phosphorylation state of oocytes with activators of protein kinase A or protein kinase C resulted in the formation of long interphase microtubules in competent oocytes while centrosome phosphorylation was maintained. Treatment of competent oocytes with the phosphorylation inhibitor 6-dimethylaminopurine also led to formation of long microtubules, although under these conditions centrosomes were dephosphorylated. When competent oocytes were treated simultaneously with puromycin and the phosphodiesterase inhibitor isobutyl methylxanthine (IBMX) for 6 hr, centrosomes became dephosphorylated; centrosomes were rephosphorylated when competent oocytes were further cultured in IBMX without puromycin. Conditions that induced centrosome dephosphorylation in competent oocytes resulted in the loss of the ability to express meiotic competence in culture, whereas maintenance of centrosome phosphorylation in these oocytes was correlated with the ability to resume meiosis. These results suggest that the G2/M transition that occurs when mouse oocytes progress from an incompetent to a competent state in vivo involves the phosphorylation of centrosomes and that the maintenance of centrosome phosphorylation is required for the in vitro expression of meiotic competence.

Regulation of meiotic maturation in the mammalian oocyte: interplay between exogenous cues and the microtubule cytoskeleton

Mammalian oocytes exhibit a series of cell cycle transitions that coordinate the penultimate events of meiosis with the onset of embryogenesis at fertilization. The execution of these cell cycle transitions, at G2/M of meiosis-I and metaphase/anaphase of meiosis I and II, involve both biosynthetic and post-translational modifications that directly modulate centrosome and microtubule behavior. Specifically, somatic cells alter the signal transduction pathways in the oocyte and influence the expression of maturation promoting factor (MPF) and cytostatic factor (CSF) activity through a microtubule-dependent mechanism. The regulation of the oocytes' cell cycle machinery by hormone-mediated somatic cell signals, involving both positive and negative stimuli, ensures that meiotic cell cycle progression is synchronized with the earliest pivotal events of mammalian reproduction.

Centrosome and microtubule dynamics during meiotic progression in the mouse oocyte

The disposition, function and fate of centrosomes were analysed in mouse oocytes undergoing in vitro meiotic maturation, using multiple-label fluorescence microscopy. Oocytes fixed at various points during meiotic progression were double labeled with either human centrosome-specific antibody, 5051, and anti-tubulin antibodies or 5051 and MPM-2 antibodies in order to evaluate the microtubule nucleation capacity and phosphorylation status of centrosomes during this process. Double labeling with anti-tubulin antibodies revealed two populations of centrosomes that undergo stage-specific changes in number, location and microtubule nucleation capacity in relation to spindle assembly and cytoplasmic events. Specifically, one population was consistently associated with chromatin throughout meiotic maturation whereas a second population of cytoplasmic centrosomes exhibited maximal numbers and nucleation capacity at prometaphase and anaphase of meiosis-I. Quantitative evaluation of cytoplasmic centrosomes indicated increased numbers during the transition from diakinesis to prometaphase and metaphase to anaphase and total disappearance during telophase. Colocalization studies with MPM-2 revealed that centrosomes were always phosphorylated. However, at metaphase of meiosis I and II the microtubule nucleation capacity of centrosomes was diminished. These results suggest the existence of two discrete populations of centrosomes in the mouse oocyte that are coordinately regulated to subserve aspects of microtubule organization relative to both nuclear and cytoplasmic events.

Quality of oocytes from superovulated rhesus monkeys

The parameters, serum oestradiol (E2) response, follicle size and cumulus morphology, which are commonly used to determine in-vivo oocyte maturation in human in-vitro fertilization and embryo transfer (IVF-ET) programmes, were shown to be unreliable predictors of maturation of rhesus oocytes. In two groups of rhesus, one stimulated with pregnant mares' serum gonadotrophin (PMSG) and human chorionic gonadotrophin (HCG) and the other with human menopausal gonadotrophin (HMG) and HCG, the three parameters varied widely within and between protocols. Triple fluorochrome staining (TFS) for chromatin, microtubules and filamentous actin (f-actin) in oocytes at the time of collection and following 24 h in culture showed major differences in their maturation both in vivo and in vitro following priming with PMSG and HMG. In evaluating IVF protocols, TFS provides a valuable assay for the meiotic status of fixed oocytes of non-human primates.

Oogenesis: chromatin and microtubule dynamics during meiotic prophase

Changes in the organization of germinal vesicle chromatin in mouse oocytes have been analyzed by fluorescence microscopy with respect to progressive stages of follicular development and the disposition of oocyte cytoplasmic microtubules. Four discrete patterns of chromatin organization exist in germinal vesicle (GV)-stage oocytes isolated from the ovaries of 21-25-day-old gonadotropin-primed mice. Analysis of ovarian cryosections stained with the DNA-binding fluorochrome Hoechst 33258 indicates that sequential changes in GV chromatin occur during folliculogenesis that result in the formation of a continuous perinucleolar chromatin sheath at the time of antrum formation. Specific alterations in the cytoplasmic microtubule complex of GV-stage oocytes were observed that correlate with chromatin patterns. The extensive cytoplasmic microtubule complex seen in oocytes of preantral follicles initially localizes to perinuclear areas of the ooplasm. This is followed by a progressive reduction in cytoplasmic microtubules and the appearance of prominent microtubule-organizing centers at the nuclear periphery. Coordinated nuclear and microtubular alterations also occur under in vitro conditions prior to progression of meiosis to prometaphase-1. The results are discussed with respect to the ongoing differentiation of the oocyte nucleus and the microtubule cytoskeleton during folliculogenesis in preparation for the resumption of meiosis.

Transitions in trophectoderm cellular shape and cytoskeletal organization in the elongating pig blastocyst

Changes in cellular shape and filamentous actin (f-actin) organization within the trophectoderm of pig embryos have been studied by fluorescence microscopy during the transitions from spherical to filamentous blastocysts. Cells comprising the trophectoderm of spherical, ovoid, tubular, and filamentous blastocysts are distinctive in their shape, size, and organization of membrane-associated f-actin. Trophectodermal cells of spherical and ovoid embryos are both generally circular in shape. However, as the spherical embryo acquires an ovoid shape, uniformally distributed apical cell surface microvilli relocate to the apical intercellular margins of adjoining trophectodermal cells. Transitional modifications in cellular shape and f-actin organization are observed in tubular blastocysts when apical cell surface microvilli reappear. In elongating filamentous blastocysts, trophectodermal cells assume a spindle-shaped morphology. The f-actin associated with the apical surface is diminished whereas the associated with the basolateral membrane predominates, especially in constricted regions of the blastocyst. These observations, in conjunction with morphometric parameters of trophectodermal cells and whole blastocysts, are discussed in relation to the role of the actin cytoskeleton in processes that modify trophectodermal cell shape and function in the elongating pig blastocyst.

Quantitative studies of changes in cortical granule number and distribution in the mouse oocyte during meiotic maturation

Cortical granules (CGs) undergo a substantial change in distribution in the mouse oocyte cortex during meiotic maturation. In order to determine the mechanism of their change in distribution near the time of ovulation, CG density, total number per oocyte, and domain areas were quantitated. CGs were visualized microscopically by Lens culinaris agglutinin-biotin and Texas red-strepavidin fluorescence as well as by electron microscopy. Immature germinal vesicle stage (GV) oocytes from adult mice had a continuous cortical localization with some interior granules. Mature oocytes had an asymmetric cortical distribution with a CG-free domain, overlying the meiosis II metaphase spindle, occupying 40% of the cortex. The mean CG densities of the granule-occupied cortex of mature oocytes and the entire cortex of GV oocytes were 43 and 34 CGs/100 micron 2, respectively. The mean total numbers of CGs/oocyte were 4127 (mature) and 7440 (GV), and staining was absent in fertilized oocytes with two pronuclei. Calcium ionophore (A23187)-activated mature oocytes had a mean total number of 1235 CGs, some of which may have been in the process of exocytosis. The first polar body had few CGs, and thus was unlikely to account for the difference in CG number between GV and mature oocytes. The smaller total number and higher density of CGs in mature mouse oocytes suggests that both exocytosis and redistribution are plausible mechanisms for the development of the CG-free domain. Prefertilization exocytosis could account for the locus of sperm penetration which others have reported to occur in the hemisphere opposite the meiotic spindle in the mouse.

Changes in the organization of the actin cytoskeleton during preimplantation development of the pig embryo

The organization of the actin cytoskeleton was studied in unfertilized porcine oocytes and preimplantation stage embryos from Day 1 through Day 8 of development. Fixed and detergent-extracted oocytes and embryos were analyzed by fluorescence microscopy after staining with either rhodamine-phalloidin to localize filamentous actin or with affinity-purified anti-actin antibodies to localize the total immunodetectable actin. Whereas unfertilized oocytes contain immunoreactive cytoplasmic actin, rhodamine-phalloidin binding is not detected until fertilization when a prominent cortical staining pattern becomes apparent. In early cleavage stage embryos, filamentous actin is concentrated in the cell cortex of blastomeres especially at sites of cell-cell contact. Compacting morulae exhibit a marked accumulation of actin at the margins of blastomeres where numerous interdigitating cell processes are located. The predominantly pericellular distribution of actin becomes a distinguishing feature of trophectodermal cells in the expanding blastocyst at Day 6 of development; these cells form a prominent actin-limited zone circumscribing the inner cell mass. In Day 8 blastocysts, three cell types are present that are readily distinguishable based upon their actin displays among other cytological features. Trophectodermal cells exhibit continuous actin-rich lateral borders and stress fibers along their basal surface. Inner cell mass cells contain a discontinuous actin boundary and prominent foci of actin along their blastocoelic surface. Lining the blastocoel are patches of endodermal cells in which the actin is exclusively cortical. The data are discussed with respect to differences between species and the chronology of actin rearrangements during preimplantation development of the porcine embryo.

Cytoplasmic reorganization during the resumption of meiosis in cultured preovulatory rat oocytes

Changes in organelle topography and microtubule configuration have been studied during the resumption and progression of meiosis in cultured preovulatory rat oocytes. Germinal vesicle breakdown (GVBD) was reversibly inhibited by dibutyryl cAMP (DcAMP) or nocodazole, a microtubule-disrupting agent. The microtubule stabilizing agent taxol did not inhibit GVBD, but did impair further maturation. The migration of acidic organelles and chromatin in living oocytes was analyzed using the vital stains acridine orange and Hoechst 33258, respectively. Germinal vesicle stage oocytes undergo perinuclear aggregation of acidic organelles during GVBD and these organelles subsequently disperse into the cell cortex as the first meiotic spindle migrates to the oocyte periphery. DcAMP and nocodazole block the perinuclear aggregation of acidic organelles, whereas, in taxol-treated oocytes, organelle aggregation and GVBD occur but the dispersion of acidic organelles was arrested. Dose-response studies on the effects of nocodazole showed that GVBD was generally retarded and that a 50% inhibition of GVBD was achieved at concentrations in excess of 1.0 microM. Concentrations of taxol at 10 microM or above effectively inhibited both chromatin condensation and meiotic spindle formation. Indirect immunofluorescence microscopy with anti-tubulin antibodies revealed dissolution of microtubules with 1.0 microM nocodazole. Taxol had little effect on microtubule organization in germinal vesicle or chromatin condensation stage oocytes; however, when oocytes that had formed first meiotic spindles were treated with taxol, numerous microtubule asters appeared which were preferentially associated with the oocyte cortex. The changes in organelle topography, microtubule configuration, and drug sensitivity are discussed with respect to the regulation of cytoplasmic reorganization during the meiotic maturation of rat preovulatory oocytes.