Position of the nucleus in mouse germinal vesicle–stage oocytes with different chromatin configurations

The mammalian germinal vesicle–stage (GV) oocytes are divided into two major types, NSN (non-surrounded nucleolus) and SN (surrounded nucleolus), and at least one intermediate type, pSN (partly surrounded nucleolus), based on large-scale chromatin configuration. In mice, the SN oocytes are considered to be the most meiotically competent, which explains active study of their phenotypic characteristics necessary for improvement of human reproductive technologies. One of such characteristics is the position of the GV (nucleus) relative to the center of the oocyte. However, the current data on this issue are contradictory and even completely absent for pSN oocytes. In this work, we have studied the GV position in 187 mouse GV oocytes belonging to NSN, SN, and pSN types using different approaches known from the literature. Our results suggest that (1) the most abundant in all examined types of oocytes are central GVs (43–66%) and the least abundant are peripheral GVs (12–39%); the pSN oocytes are closer to SN oocytes rather than to NSN oocytes according to the GV position; (3) the position of the nucleus in mouse GV oocytes is an ambiguous marker of large-scale chromatin configuration and, correspondingly, maturation competence of the oocyte; (4) the diversity of the GV position in NSN, SN, and pSN oocytes most likely reflects the ability of GVs to migrate; and (5) assessment of the GV position according to three variants (central, peripheral, and intermediate) is more informative as compared with two variants (central and peripheral).     

Meiotic competence and acetylation pattern of UV light classified mouse antral oocytes after meiotic arrest with isobutylmethylxanthine

Chromatin transformation from a diffused or NSN configuration to a compacted or SN shape that forms a ring around the nucleolus is regarded as one of the modifications necessary for successful embryonic development. But the process of the transformation is poorly understood. In this study we cultured mouse antral oocytes under meiotic arrest with IBMX for periods between 3 and 24 hr. We observed the chromatin status of the oocytes before and after culture under UV illumination. We reported here that the NSN configured oocytes transformed temporally through an intermediate form into the SN configuration while under meiotic arrest in vitro. Meiotic rate was improved in the NSN oocytes after the meiotic arrest but decreased in the SN oocytes. We also reported that chromatin of both the NSN and SN oocytes was acetylated and the two groups underwent the same pattern of H4/K5 deacetylation during meiotic maturation. We hypothesized that the transformation of mouse oocyte from the NSN to SN type may be time rather than oocyte size specific and the abrupt deacetylation of NSN oocyte during spontaneous maturation may explain its poor meiotic and developmental competence.     

Competent mouse oocytes isolated from antral follicles exhibit different chromatin organization and follow different maturation dynamics

After labelling DNA with the specific vital fluorophore Hoechst 33342, oocytes, isolated by puncture from antral follicles in adult mice, have two essentially different configurations of their nuclear fluorescence images. These have been called SN (where the nucleolus is not surrounded by chromatin) and NSN (where the nucleolus is not surrounded by chromatin). Intermediate configurations are also found, although with a lower frequency. The proportion of each class is on the average equal and depends neither on the presence of cumulus cells nor on the age of the mouse. Electron microscopy confirms several ultrastructural differences between these two nuclear configurations, namely, the structure of the nucleolus, which is vacuolated in NSN-type and compact in SN-type oocytes. Using video-enhanced fluorescence microscopy at low level of excitation light, we could follow directly in vitro the meiotic maturation of both classes, without impairing their viability. We show that in germinal vessicle (GV) state, the chromatin does not change from one configuration into the other and that both classes are able to mature to metaphase II, although the maturation has slightly different characteristics. © 1993 Wiley-Liss, Inc.     

Analysis of aneuploidy rate in antral and ovulated mouse oocytes during female aging

Two forms of oocytes termed SN (surrounded nucleolus) and NSN (nonsurrounded nucleolus) differing for the spatial distribution of nuclear and nucleolar-associated chromatin have been described within the antral compartment of the ovary of a number of mammals. The biological significance of these two kind of oocytes is as yet not completely clear. In previous studies we have shown that prior to ovulation, mouse SN oocytes isolated from the antral compartment, matured and fertilized in vitro have a far better meiotic and developmental competence than NSN oocytes. Immediately after ovulation SN and NSN oocytes remaining in the antral compartment do not develop beyond the 2-cell stage. To further examine the correlation between chromatin distribution and meiotic competence of mouse antral oocytes, in the present study we have analyzed chromosome segregation at the first meiotic division in antral (SN and NSN) and in ovulated oocytes. SN and NSN oocytes were isolated before (48 h post PMSG injection) or after (15 h post–hCG injection) ovulation from ovaries of females of increasing age, they were cultured in vitro to metaphase II, and their aneuploidy rate was examined. Comparison of data obtained before and after ovulation highlights two main points: 1. Following ovulation a statistically significant increase of aneuploidy is observed in antral oocytes in most age groups and it is attributable to SN oocytes. 2. The aneuploidy rate of ovulated oocytes does not increase during female aging. We have found a correlation between chromatin distribution, hormonal status, and the incidence of aneuploidy during the oocyte first meiotic division. Mol. Reprod. Dev. 50 :305–312, 1998. © 1998 Wiley-Liss, Inc.     

Configurations of germinal vesicle (GV) chromatin in the goat differ from those of other species

Configuration of germinal vesicle (GV) chromatin has been studied and found correlated with the developmental competence of oocytes in several mammalian species. A common feature in the configuration of GV chromatin in the species studied so far is that the diffuse chromatin (the so called "NSN" pattern) condenses into a perinucleolar ring (the so called "SN" configuration) with follicular growth. However, no study has been published on the configuration of GV chromatin in the goat. Nor is it known whether the perinucleolar ring of condensed chromatin (CC) in an oocyte represents a step toward final maturation or atresia. Changes in configurations of GV chromatin and RNA synthesis during goat oocyte growth, atresia and maturation in vivo and in vitro were investigated in this study. Based on both the size of nucleoli and the degree of chromatin condensation, the GV chromatin of goat oocytes was classified into GV1 characterized by large nucleoli and diffuse chromatin, GV2 with medium-sized nucleoli and condensed net-like (GV2n) or clumped (GV2c) chromatin, GV3 with small nucleoli and net-like (GV3n) or clumped (GV3c) chromatin, and GV4 with no nucleolus but clumped chromatin. The results showed that (i) the configurations of GV chromatin in the goat differ from those of other species in that the chromatin did not condense into a perinucleolar ring; (ii) most of the goat oocytes are synchronized at the GV3n configuration before GVBD; (iii) the GVn pattern might represent a healthy state, but the GVc an atretic state; (iv) in both goats and mice, the GC-specific (Chromomycin A3, CMA3) and the AT-specific (Hoechst 33342) fluorochromes followed the same pattern of distribution in GV chromatin; (v) the nucleolar size decreased significantly with oocyte growth and maturation in vivo and in vitro; and (vi) goat oocytes began GVBD at 8 hr and had completed it by 20 hr after onset of estrus. The peculiar configuration of GV chromatin of goat oocytes can be a useful model for studies of morphological and functional changes of different nuclear compartments during the cell cycle and cell differentiation, and the functional differentiation between GV3n and GV3c might be used for reference to the question whether the "SN" configuration in other species inclines toward ovulation or atresia.     

The analysis of chromatin organisation allows selection of mouse antral oocytes competent for development to blastocyst

Mouse antral oocytes can be classified in two different types termed SN or NSN oocytes, depending on the presence or absence, respectively, of a ring of Hoechst 33342-positive chromatin surrounding the nucleolus. The aim of the present study was to test the developmental competence to blastocyst of the two types of oocytes. Here we show that following isolation, classification and culture of cumulus-free antral oocytes, 14.7% and 74.5% of NSN and SN oocytes, respectively, reached the metaphase II stage. When fertilised and further cultured none of the metaphase II NSN oocytes developed beyond the 2-cell stage whilst 47.4% of the metaphase II SN oocytes reached the 4-cell stage and 18.4% developed to blastocyst. The findings reported in this paper may contribute to improved procedures of female gamete selection for in vitro fertilisation of humans and farm animals. Furthermore, the selection of oocytes with better developmental potential may be of interest for studies on nuclear/cytoplasm interaction, particularly in nuclear-transfer experiments.     

The spatial relationship between heterochromatin protein 1 alpha and histone modifications during mouse oocyte meiosis

Heterochromatin protein 1 (HP1) is closely associated with diverse chromatin organization and function in mitosis. However, we almost know nothing about HP1 in mammalian oocyte. Here, we investigated the subcellular distribution of HP1α and its spatial relationship to histone modifications during mouse oocyte maturation. Dynamic migration of HP1α was observed in germinal vesicle with non-surrounded nucleolus (NSN) to surrounded nucleolus (SN) oocytes, which may be essential for the transition of chromatin conformation during the development of antral oocytes. In meiosis, HP1α was clearly detectable at the periphery of chromosomes from pre-metaphase I stage to anaphase-telophase I stage. Spatial correlation between HP1α and histone modifications is highly variable around the time of meiotic resumption. In germinal vesicle oocytes, HP1α almost colocalized with all histone modifications examined in this study except for phosphorylation of serine 28 on histone H3. However, with the breakdown of germinal vesicle, HP1α was detected mostly in the chromosomal domains with strong phosphorylation of serine 10 and 28 on histone H3, and they also partially associated with methylated histones. These results presented the functional implication of histone modifications in the regulation of HP1α during oocyte maturation. In addition, we also showed that blocking the function of HP1α by microinjecting anti-HP1α antibody caused the delay of GVBD, however, this effect may not be achieved through modifying histones.     

Aging changes the chromatin configuration and histone methylation of mouse oocytes at germinal vesicle stage

Aging decreases the fertility of mammalian females. In old oocytes at metaphase II stage (MII) there are alterations of the chromatin configuration and chromatin modifications such as histone acetylation. Recent data indicate that alterations of histone acetylation at MII initially arise at germinal vesicle stage (GV). Therefore, we hypothesized that the chromatin configuration and histone methylation could also change in old GV oocytes. In agreement with our hypothesis, young GV oocytes had non-surrounded nucleolus (NSN) and surrounded nucleolus (SN) chromatin configurations, while old GV oocytes also had chromatin configurations that could not be classified as NSN or SN. Regarding histone methylation, young GV and MII oocytes showed dimethylation of lysines 4, 9, 36 and 79 in histone 3 (H3K4me2, H3K9me2, H3K36me2, H3K79me2), lysine 20 in histone H4 (H4K20me2) and trimethylation of lysine 9 in histone 3 (H3K9me3) while a significant percentage of old GV and MII oocytes lacked H3K9me3, H3K36me2, H3K79me2 and H4K20me2. The percentage of old oocytes lacking histone methylation was similar at GV and MII suggesting that alterations of histone methylation in old MII oocytes initially arise at GV. Besides, the expression of the histone methylation-related factors Cbx1 and Sirt1 was also found to change in old GV oocytes. In conclusion, our study reports changes of chromatin configuration and histone methylation in old GV oocytes, which could be very useful for further understanding of human infertility caused by aging.     

Aging changes the chromatin configuration and histone methylation of mouse oocytes at germinal vesicle stage

Aging decreases the fertility of mammalian females. In old oocytes at metaphase II stage (MII) there are alterations of the chromatin configuration and chromatin modifications such as histone acetylation. Recent data indicate that alterations of histone acetylation at MII initially arise at germinal vesicle stage (GV). Therefore, we hypothesized that the chromatin configuration and histone methylation could also change in old GV oocytes. In agreement with our hypothesis, young GV oocytes had non-surrounded nucleolus (NSN) and surrounded nucleolus (SN) chromatin configurations, while old GV oocytes also had chromatin configurations that could not be classified as NSN or SN. Regarding histone methylation, young GV and MII oocytes showed dimethylation of lysines 4, 9, 36 and 79 in histone 3 (H3K4me2, H3K9me2, H3K36me2, H3K79me2), lysine 20 in histone H4 (H4K20me2) and trimethylation of lysine 9 in histone 3 (H3K9me3) while a significant percentage of old GV and MII oocytes lacked H3K9me3, H3K36me2, H3K79me2 and H4K20me2. The percentage of old oocytes lacking histone methylation was similar at GV and MII suggesting that alterations of histone methylation in old MII oocytes initially arise at GV. Besides, the expression of the histone methylation-related factors Cbx1 and Sirt1 was also found to change in old GV oocytes. In conclusion, our study reports changes of chromatin configuration and histone methylation in old GV oocytes, which could be very useful for further understanding of human infertility caused by aging.     

Changes in germinal vesicle (GV) chromatin configurations during growth and maturation of porcine oocytes

Changes in germinal vesicle (GV) chromatin configurations during growth and maturation of porcine oocytes were studied using a new method that allows a clearer visualization of both nucleolus and chromatin after Hoechst staining. The GV chromatin of porcine oocytes was classified into five configurations, based on the degree of chromatin condensation, and on nucleolus and nuclear membrane disappearance. While the GV1 to 4 configurations were similar to those reported by previous studies, the GV0 configuration was distinct by the diffuse, filamentous pattern of chromatin in the whole nuclear area. Most of the oocytes were at the GV0 stage in the <1 and 1-1.9 mm follicles, but the GV0 pattern disappeared completely in the 2-2.9 and 3-6 mm follicles. As follicles grew, the number of oocytes with GV1 configurations increased and reached a maximum in the preovulatory follicles 4 hr post-hCG injection. During maturation in vivo, the number of GV1 oocytes decreased while oocytes undergoing GVBD increased. The percentage of oocytes with GV3 and GV4 configurations was constant during oocyte growth except at the 2-2.9 mm follicle stage, but these configurations disappeared completely after hCG injection. On the contrary, the in vitro maturing oocytes showed a large proportion of GV3 and GV4 configurations. There was no significant difference in distribution of chromatin configurations between the nonatretic and atretic follicles, and between oocytes with more than two layers of cumulus cells and those with less than one layer or no cumulus cells. Overall, our results suggested that (i) the GV0 configuration in porcine oocytes corresponded to the "nonsurrounded nucleolus" pattern in mice and other species; (ii) all the oocytes were synchronized at the GV1 stage before GVBD and this pattern might, therefore, represent a nonatretic state; (iii) the GV3 and GV4 configurations might represent stages toward atresia, or transient events prior to GVBD that could be switched toward either ovulation or atresia, depending upon circumstances; (iv) the in vitro systems currently used were not favorable for oocytes to switch toward ovulation (or final maturation); (v) the number of cumulus cells was not correlated with the chromatin configuration of oocytes, indicating that the beneficial effect of cumulus cells on oocyte maturation and development may simply be attributed to their presence during in vitro culture.     

Chromatin, microtubules, and kinases activities during meiotic resumption in bitch oocytes

In contrast to the majority of mammals, canine oocytes are ovulated at immature germinal vesicle (GV) stage and complete meiotic maturation to metaphase II during 48-72 hr within the oviducts. This study aims to characterize meiotic maturation process in bitch oocytes, with both morphological and biochemical approaches. The follow-up of chromatin and microtubules during maturation was described, and MPF and MAP kinase activities were quantified at different stages of maturation. Since bitch oocyte cytoplasm is darkly pigmented, the first step was to setup an appropriate staining method for DNA. We thus compared the efficiency of two visualization techniques and demonstrated that propidium iodide coupled to confocal microscopy was a better method than Hoechst/fluorescence microscopy for nuclear stage observation (determination rates: 98.6 vs. 69.5%, respectively; P < 0.01, n = 1622 oocytes). Microtubule organization, evaluated by tubulin immunodetection, revealed subcortical and perinuclear alpha-tubulin and asters in GV oocytes and a clear network of microtubules in GVBD oocytes. In MI and MII oocytes, a symmetrical, barrel-shaped, and radially located spindle was observed. MPF and MAP kinase activities were assayed concomitantly using histone H1 and MBP as substrates. Kinase activities were detected at low levels in oocytes at GV and GVBD stages and were significantly higher at MI and MII stages. In conclusion, despite the particular pattern of meiotic resumption in canine oocytes (ovulated at GV stage), cytoskeleton/chromatin organization and kinase activities follow a similar pattern to those observed in other mammalian species.