Chromatin organization during mouse oocyte growth

We investigated the changes in the organization of oocyte nuclear chromatin and nucleolar-associated chromatin throughout folliculogenesis. Zona-free oocytes were isolated from ovaries, grouped into seven classes according to size and chromatin organization, and analyzed after staining with Hoechst 33342. We show that oocyte differentiation from the dictyate stage to the conclusion of maturation is associated with either of two chromatin configurations. Initially, all oocytes are in the NSN configuration (nonsurrounded nucleolus oocytes; characterized by a Hoechst positive-chromatin pattern of small clumps forming a network on the nuclear surface, with a nucleolus nonsurrounded by chromatin). While growing, some of these NSN oocytes continue their development in the NSN configuration, whereas others shift (from class IV on) into the SN configuration (surrounded nucleolus oocytes; characterized by a threadlike chromatin organization that may partially surround the nucleolus or project towards the nuclear periphery). The percentage of SN oocytes increases both with increasing size of the oocyte (class I–III, 10–40 μm in diameter: 100% NSN vs. 0% SN; class VII 70–80 μm in diameter: 47.3% NSN vs. 52.3 SN, in 4–6-week-old females), and with aging (class VII: 94.1% NSN vs. 5.9% SN in 2-week-old females; 11.8% NSN vs. 8.2% SN in 56-week-old females). Further, we suggest as a working hypothesis that those oocytes that switch to the SN chromatin organization early in maturation may not be ovulated, even though this particular chromatin structure normally occurs just prior to ovulation. © 1995 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.     

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).     

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.     

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.     

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.     

Several signaling pathways are involved in the control of cattle oocyte maturation

The main limit of in vitro production of domestic mammal embryos comes from the low capacity of in vitro matured oocytes to develop after fertilization. As soon as they are separated from follicular environment, oocytes spontaneously resume meiosis without completion of their terminal differentiation. Roscovitine (ROS), an inhibitor of M-phase promoting factor (MPF) kinase activity reversibly blocks the meiotic resumption in vitro. However, in cattle maturing oocytes several cellular events such as protein synthesis and phosphorylation, chromatin condensation and nuclear envelope folding escape ROS inhibition suggesting the alternative pathways in oocyte maturation. We compared the level of synthesis and phosphorylation of several protein kinases during bovine cumulus oocyte complex (COC) maturation in vitro in the presence or not of epidermal growth factor (EGF) and ROS. We showed that during the EGF-stimulated maturation, ROS neither affected the decrease of EGF receptor (EGFR) nor did inhibit totally its phosphorylation in cumulus cells and also did not totally eliminate tyrosine phosphorylation in oocytes. However, ROS did inhibit the Phosphoinositide 3-kinase (PI3) activity when oocytes mature without EGF. Accumulation of Akt/PKB (protein kinase B), JNK1/2 (jun N-terminal kinases) and Aurora-A in oocytes during maturation was not affected by ROS. However, the phosphorylation of Akt but not JNKs was diminished in ROS-treated oocytes. Thus, PI3 kinase/Akt, JNK1/2 and Aurora-A are likely to be involved in the regulation of bovine oocyte maturation and some of these pathways seem to be independent to MPF activity and meiotic resumption. This complex regulation may explain the partial meiotic arrest of ROS-treated oocytes and the accelerated maturation observed after such treatment.     

腺嘌呤对体外小鼠卵母细胞减数分裂的抑制

本文研究了嘌呤类物质对小鼠卵母细胞减数分裂的影响。于卵母细胞的生发泡内显微注射腺嘌呤和腺嘌呤的类似物苄基腺嘌呤可显著抑制卵母细胞的分裂的重新启动。同时发现在腺嘌呤的作用过程中,腺苷酸环化酶的激活剂氟化钠可增强其对卵母细胞的抑制作用,表明cAMP途径在小鼠卵母细胞减数分裂成熟过程中起重要作用。腺嘌呤在不同培养液中的抑制效果不一,次黄嘌呤在DMEM和EMEM中对小鼠的卵丘细胞-卵母细胞复合体(COC)和无卵丘细胞的裸卵(DO)均具有明显的抑制效应。但腺嘌呤在DMEM比在EMEM中对COC的抑制效果更强,而且腺嘌呤在DMEM中与次黄嘌呤具有协同效应,这些差别可能是由于两种培养液中不同成分如谷氨酰胺造成卵母细胞对腺嘌呤吸收差异而引起的。     

Spontaneous calcium oscillations and nuclear PLC-beta1 in human GV oocytes

Our aim was to investigate if human oocytes, like mouse oocytes, exhibit spontaneous Ca(2+) oscillations and nuclear translocation of PLC-beta1 prior to germinal vesicle breakdown (GVBD), and to correlate these events with the evolution of chromatin configuration as a landmark for the meiosis resumption kinetics. Human germinal vesicle (GV) oocytes were either loaded with Fluo-3 probe to record Ca(2+) signals or fixed for subsequent fluorescent labeling of both chromatin and PLC-beta1, and immunogold labeling of PLC-beta1. Here for the first time, we show that human oocytes at the GV-stage exhibit spontaneous Ca(2+) oscillations. Interestingly, only oocytes with a large diameter and characterized by a compact chromatin surrounding the nucleolus of the GV could reveal these kind of oscillations. We also observed a translocation of PLC-beta1 from the cytoplasm towards the nucleus during in vitro maturation of human oocytes. Spontaneous calcium oscillations and nuclear translocation of PLC-beta1 may reflect some degree of oocyte maturity. The impact of our results may be very helpful to understand and resolve many enigmatic problems usually encountered during the in vitro meiotic maturation of human GV oocytes.     

Overexpression of cyclin A1 promotes meiotic resumption but induces premature chromosome separation in mouse oocyte

Mammalian cyclin A1 is prominently expressed in testis and essential for meiosis in the male mouse, however, it shows weak expression in ovary, especially during oocyte maturation. To understand why cyclin A1 behaves in this way in the oocyte, we investigated the effect of cyclin A1 overexpression on mouse oocyte meiotic maturation. Our results revealed that cyclin A1 overexpression triggered meiotic resumption even in the presence of germinal vesicle breakdown inhibitor, milrinone. Nevertheless, the cyclin A1-overexpressed oocytes failed to extrude the first polar body but were completely arrested at metaphase I. Consequently, cyclin A1 overexpression destroyed the spindle morphology and chromosome alignment by inducing premature separation of chromosomes and sister chromatids. Therefore, cyclin A1 overexpression will prevent oocyte maturation although it can promote meiotic resumption. All these results show that decreased expression of cyclin A1 in oocytes may have an evolutional significance to keep long-lasting prophase arrest and orderly chromosome separation during oocyte meiotic maturation.     

Knockdown of RBBP7 unveils a requirement of histone deacetylation for CPC function in mouse oocytes

During mouse oocyte maturation histones are deacetylated, and inhibiting this deacetylation leads to abnormal chromosome segregation and aneuploidy. RBBP7 is a component of several different complexes that contain histone deacetylases, and therefore could be implicated in histone deacetylation. We find that Rbbp7 is a dormant maternal mRNA that is recruited for translation during oocyte maturation to regulate the histone deacetylation. Importantly, we show that the maturation-associated decrease of histone acetylation is required for localization and function of the chromosomal passenger complex (CPC) during oocyte meiotic maturation. This finding can explain the phenotypes of oocytes where Rbbp7 is depleted by an siRNA/morpholino cocktail including severe chromosome misalignment, improper kinetochore–microtubule attachments, impaired SAC function, cytokinesis defects, and increased incidence of aneuploidy at metaphase II (Met II). These results implicate RBBP7 as a novel regulator of histone deacetylation during oocyte maturation and provide evidence that such deacetylation is required for proper chromosome segregation by regulating localized CPC function.