Presence and dynamic redistribution of type I inositol 1,4,5-trisphosphate receptors in human oocytes and embryos during in-vitro maturation, fertilization and early cleavage divisions.

We studied the presence and distribution of the intracellular calcium channel regulating type I inositol 1,4,5-trisphosphate receptors (IP3R) in human immature and mature oocytes, pronuclear zygotes and cleaved embryos using a specific antibody. Two approaches were used: (i) fluorescence immunocytochemistry using a confocal laser scanning microscope (CLSM) and (ii) Western blotting. With confocal microscopy, the receptors were found in the oocytes, fertilized zygotes as well as cleaved embryos at all stages studied. The pattern and distribution of the receptor staining in the oocytes changed gradually from a diffuse granular patchy one at the germinal vesicle (GV) stage to a reticular and predominantly peripheral one through the metaphase I and metaphase II (MII) stages. After fertilization, the distribution changed gradually to both, peripheral and central in the zygotes and early 2-4-cell embryos and predominantly perinuclear in the 6-8-cell embryos. Furthermore, an overall increase in the staining intensity was observed from GV to MII stage oocytes and from zygotes to 6-8-cell embryos. We also studied the spatial distribution of the receptor in detail by constructing three-dimensional images from the serial optical sections obtained on the CLSM. Peculiar peripheral aggregates of receptor clusters were noted in the MII stage oocytes, zygotes and some blastomeres from early cleaved embryos. Finally, Western blots performed on the extracts of 72 in-vitro matured oocytes and 50 spare cleavage stage embryos showed positive bands at approximately 260 kDa. These findings coincide with and thus possibly represent the dynamic changes occurring in the cellular Ca2+ release systems through oocyte maturation, fertilization and early embryogenesis. Thus, type I IP3R are likely to play a role during these stages of early development in the human.     

In-vitro development of mouse zygotes following reconstruction by sequential transfer of germinal vesicles and haploid pronuclei

We evaluated whether mouse oocytes reconstructed by germinal vesicle (GV) transfer can develop to blastocyst stage. The oocytes were artificially activated with sequential treatment of A23187 and anisomycin; fertilization was then established by transfer or exchange of pronuclei with those of zygotes fertilized in vivo. Type 1 zygotes were constructed by placing the male haploid pronucleus from a zygote into the cytoplasm of an oocyte that underwent GV transfer, in-vitro maturation and activation; for type 2 zygotes, the female pronucleus was removed from a zygote and replaced with the female pronucleus of an oocyte subjected to GV transfer, in-vitro maturation and activation. Karyotypes of activated oocytes and type 2 zygotes were also subjected to analysis. When cultured in human tubal fluid (HTF) medium, reconstructed oocytes matured and, following artificial activation, consistently developed a pronucleus with a haploid karyotype; the activation rate for this medium was two- to three-fold higher than that of oocytes cultured in M199 (87% versus 30% respectively). Following transfer of a male pronucleus, only 47% of the type 1 zygotes developed to morula or blastocyst stage and embryo morphology was poor. In contrast, 73% of the type 2 zygotes developed to morula or blastocyst stage, many even hatching, with few morphological anomalies. Normal karyotypes were observed in 88% of the type 2 zygotes analysed. These observations demonstrate that the nucleus of a mouse oocyte subjected to sequential nuclear transfer at GV and pronucleus stages is, nonetheless, capable of maturing meiotically, activating normally and supporting embryonic development to hatching blastocyst stage. In contrast, the developmental potential of the cytoplasm of such oocytes appears to be compromised by these procedures.     

NuMA和γ-tubulin在核移植克隆胚胎中的动态变化和作用

核有丝分裂器蛋白(NuMA)和γ-微管蛋白(γ-tubulin)在卵母细胞成熟、受精和核移植胚胎早期发育过程中起重要作用。供体细胞γ-tubulin和NuMA参与了核移植克隆胚有丝分裂纺锤体的组装,NuMA主要参与了纺锤体极的装配和维持,而供体中心体调节核移植胚最初纺锤体的形成。核移植重构胚中心体结构异常经常伴随染色体异常排列、纺锤体结构异常,而中心体分布异常经常伴随异常卵裂。     

Reconstruction of mouse oocytes by germinal vesicle transfer: maturity of host oocyte cytoplasm determines meiosis.

We evaluated the maturational competence of mouse oocytes reconstructed by the transfer and electrofusion of germinal vesicles (GV) into anuclear cytoplasts of GV stage oocytes (both auto- and hetero-transfers), metaphase II stage oocytes or zygotes. Following in-vitro culture, the maturation rates of the reconstructed oocytes to metaphase II did not significantly differ between auto- and hetero-transfers (40/70 versus 95/144 respectively); these rates also did not differ from those of control oocytes (57/97) which were matured in vitro without micromanipulation and electrofusion. In contrast, when a GV was transferred into an enucleated metaphase II oocyte or a zygote, only a few reconstructed oocytes underwent germinal vesicle breakdown (5/30 and 2/21 respectively); moreover, none reached metaphase II stage. Cytogenetic and immunofluorescence analyses were conducted on hetero-GV oocytes that extruded a first polar body. Each oocyte showed two groups of chromosomes, one in the cytoplast and one in the polar body, as well as a bipolar spindle with twenty univalent chromosomes. Our findings suggest that oocytes reconstructed by GV transfer into a cytoplast of the same developmental stage mature normally in vitro through metaphase II. Such oocytes may be a useful research model to elucidate the cytoplasmic and nuclear mechanisms regulating meiosis and the relationships between meiotic errors and age-related changes in the oocyte.     

Nucleocytoplasmic ratio of fully grown germinal vesicle oocytes is essential for mouse meiotic chromosome segregation and alignment, spindle shape and early embryonic development

BACKGROUND: This study examined the effect of nucleocytoplasmic ratio of fully grown germinal vesicle (GV) oocytes on meiotic chromosome segregation and alignment, spindle shape, Ca(2+) oscillations and capacity of early embryonic development in mouse. METHODS: GV oocytes with reduced volume (equal to 1/5 to 4/5 of an intact oocyte) were made by micromanipulation to remove different amounts of cytoplasm, and then matured and fertilized in vitro. RESULTS: When >1/2 of GV oocyte cytoplasm was removed, the time-course of GV breakdown (GVBD) was delayed and oocyte maturation rate decreased significantly. Abnormal chromosome segregation rate increased if >1/2 of the cytoplasm was removed from the oocyte. Length and structure of meiotic spindle and chromosome alignment were also impaired by the reduction of cytoplasmic volume. Once matured in vitro, the oocytes could undergo Sr(2+)-induced Ca(2+) oscillations and form pronuclei in a manner independent of nucleocytoplasmic ratio, but their ability to develop to 2-cell embryos was affected if >1/2 of their cytoplasm was removed from the GV oocytes. CONCLUSIONS: These results suggest that nucleocytoplasmic ratio is essential for normal meiotic chromosome segregation, spindle formation and chromosome alignment over the metaphase spindle, and development to 2-cell stage, for which 1/2 of the volume of the GV oocyte appears to be a threshold.     

A confocal microscopy analysis of the spindle and chromosome configurations of human oocytes cryopreserved at the germinal vesicle and metaphase II stage

BACKGROUND: Routine oocyte cryopreservation remains an elusive technique in the wide range of assisted reproductive technologies available. This study examines the effect of a cryopreservation protocol on the spindle and chromosome configurations of human oocytes cryopreserved at the germinal vesicle (GV) and metaphase II (MII) stage. METHODS: GV oocytes were randomly assigned to one of three groups: (i) control oocytes matured in vitro to MII stage (n = 156); (ii) oocytes cryopreserved at the GV stage and then matured in vitro (n = 90); (iii) oocytes cryopreserved at the MII stage (n = 147). Following cryopreservation and in-vitro maturation, immunostaining of tubulin and chromatin was performed, before visualization using confocal microscopy. RESULTS: A statistically significant increase was observed in the survival rate in group 2 (73.3%, 66/90) compared to group 3 (55.7%, 82/147) (P < 0.007). Exposure of oocytes to the cryoprotective solutions without freezing had no effect on the structure of their second meiotic spindle. However, statistically significant differences were observed on both spindle and chromosome configurations of oocytes from group 2 (5.2 and 5.2% respectively) and group 3 (16.2 and 18.8% respectively) compared with group 1 oocytes (71.6 and 82.0% respectively) (P < 0.001 in all cases). CONCLUSIONS: The protocol followed results in high rates of survival and potential for in-vitro maturation, but has a deleterious effect on the organization of the meiotic spindle of human oocytes cryopreserved at both the GV and MII stages.     

Calcium-binding proteins and calcium-release channels in human maturing oocytes,pronuclear zygotes and early preimplantation embryos

BACKGROUND: The study aim was to investigate the presence and localization of Ca2+-binding proteins and Ca2+-release receptor channels in human maturing oocytes, pronuclear zygotes and preimplantation embryos. METHODS: Immunocytochemical analysis, using specific antibodies against the proteins being studied, followed with confocal laser microscopy, was performed on human oocytes and embryos. RESULTS: Calreticulin and calsequestrin (the two major calcium storage proteins of somatic cells), two types of calcium release receptors, the inositol trisphosphate and ryanodine receptors (InsP(3)R-2, RyRs-1,2,3), and the molecular chaperone, calnexin, were identified in all investigated cell types. Calreticulin was predominant in the cell cortex and in the nuclear envelope, while calsequestrin was distributed throughout the entire cytoplasm. Generally, localization of the InsP(3)R-2 and RyRs was similar to that of calreticulin and calsequestrin respectively. Both types of receptor were enriched in the subplasmalemmal region of meiotic oocytes. In addition, the InsP(3)R was detected in the nuclear structures of oocytes and blastomeres. Calnexin distribution overlapped with that of calreticulin but appeared to be present in distinct subcompartments. CONCLUSIONS: Human oocytes and embryos express the calcium sequestration and release proteins in highly organized and developmentally regulated patterns. Fine-tuning of these proteins may play a crucial role in regulation of Ca2+ transience during oocyte maturation, fertilization and early embryo development.     

Developmental competence of human in vitro aged oocytes as host cells for nuclear transfer

BACKGROUND: Improving human nuclear transfer (NT) efficiencies is paramount for the development of patient-specific stem cell lines, although the opportunities remain limited owing to difficulties in obtaining fresh mature oocytes. METHODS: Therefore, the developmental competence of aged, failed-to-fertilize human oocytes as an alternate cytoplasmic source for NT was assessed and compared with use of fresh, ovulation-induced oocytes. To further characterize the developmental potential of aged oocytes, parthenogenetic activation, immunocytochemical analysis of essential microtubule proteins involved in meiotic and mitotic division, and RT-PCR in single oocytes (n = 6) was performed to determine expression of oocyte-specific genes [oocyte-specific histone 1 (H1FOO), growth differentiation factor 9 (GDF9), bone morphogenetic protein 15 (BMP15), zygote arrest 1 (ZAR1)] and microtubule markers [nuclear mitotic arrest (NuMA), minus-end directed motor protein HSET and the microtubule kinesin motor protein EG5]. RESULTS: For NT, enucleation and fusion rates of aged oocytes were significantly lower compared with fresh oocytes (P < 0.05). Cleavage rates and subsequent development were poor. In addition, parthenote cleavage was low. Immunocytochemical analysis revealed that many oocytes displayed aberrant expression of NuMA and EG5, had disrupted meiotic spindles and tetrapolar spindles. One of the six oocytes misexpressed GDF9, BMP15 and ZAR1. Two oocytes expressed EG5 messenger RNA (mRNA), and HSET and NuMA were not detectable. RT-PCR of mRNA for oocyte specific genes and microtubule markers in single aged oocytes. CONCLUSIONS: Thus, aneuploidy and spindle defects may contribute to poor parthenogenetic development and developmental outcomes following NT.     

Microtubular spindle dynamics and chromosome complements from somatic cell nuclei haploidization in mature mouse oocytes and developmental potential of the derived embryos

BACKGROUND: The aim of this study was to investigate haploidization of somatic cell nuclei in non-enucleated mature oocytes regarding spindle formation, chromosomes and developmental potential. METHODS: Mouse cumulus cells were injected into metaphase II oocytes. Some injected oocytes were examined for morphological changes of chromosomes and the spindle immediately, and at 30 min, 1 h or 2 h after the injections. The remaining oocytes were activated by Sr(2+) after various incubation periods and observed for formation of a second polar body and pseudo-polar body. Cytogenetic analysis was performed for some of the resulting zygotes. The progress to blastocysts in vitro and the possibility of conception in vivo were assessed. RESULTS: Immediately after injection, the cumulus cell nucleus was still in interphase without spindle formation. The occurrence of premature chromosome condensation (PCC) and spindle formation increased as the incubation time increased. The percentages of activated oocytes increased with the incubation time after nuclear transfer, but the difference was not significant between 1 (58%) and 2 h (62%). The incidence of chromosomal aberrations was high for the derived embryos. Development in vitro was poor, and no procreation of pups occurred after transfer of the 324 embryos. CONCLUSIONS: The PCC and spindle formation induced by cumulus cell nuclei in mature oocytes was time dependent, as was the chance for successful activation. The chromosomal abnormalities from segregation errors presented one obvious cause, apart from the potential epigenetic defects, of developmental failure of the semi-cloned embryos.     

小鼠生发泡完整卵母细胞一个特异基因的克隆及其在胚胎的表达

目的：克隆和筛选小鼠生发泡完整卵母细胞(Gv卵)特异基因，并检测其一在胚胎中的表达。方法：应用抑制性消减杂交技术(SSH)，建立Gv卵特异的cDNA文库。通过斑点杂交法进一步筛选并对阳性克隆进行序列测定和同源性分析；采用RT-PC方法观察其一在着床前胚胎的表达。结果：克隆发现18个基因和8个EST序列在GV卵中特异表达。RT-PCR显示该阳性克隆的基因在GV卵、MII卵、1-细胞胚胎和2-细胞胚胎有表达，其短片段是预期要扩增者，从MII卵开始表达下降；长片段在Gv卵、MII卵、1．细胞胚胎和2-细胞胚胎表达未见明显变化。长、短片段两端序列一致。结论：该基因是GV卵特异cDNA文库中的一个基因，且是母源性基因，提示该基因在卵母细胞成熟和合子基因激活中起一定作用。     

人卵母细胞体外成熟前后线粒体分布的变化

目的 研究人未成熟和成熟卵母细胞中线粒体的分布,进一步阐明卵母细胞成熟和线粒体分布的关系.方法 未成熟卵母细胞和成熟卵母细胞均用Mito Tracker Green FM染色,经多聚甲醛固定后在激光扫描共焦显微镜下观察线粒体的分布.结果 线粒体在细胞质中的分布方式可分为:周边分布、半周边分布和均匀分布.在64.10%(50/78)的GV期卵母细胞中,线粒体呈周边分布.45.16%(28/62)的MI期卵母细胞中,线粒体仍维持周边分布;呈均匀分布的卵母细胞的比例为38.71%(24/62).体外培养成熟以后,线粒体在75.47%(80/106)的卵母细胞中呈现均匀分布.与体外培养成熟的卵母细胞相比,体内成熟的卵母细胞中线粒体分布最明显的特点是胞质中央区域线粒体的浓集,荧光强度高于周边区域.结论 人卵母细胞成熟前后,线粒体出现明显的分布变化,由未成熟卵母细胞中以周边分布为主变为成熟卵母细胞中以均匀分布为主.     

Maturation at high frequency of germinal-vesicle-stage mouse oocytes after cryopreservation: alterations in cytoplasmic, nuclear, nucleolar and chromosomal structure and organization associated with vitrification

After thawing and culture in vitro, > 90% of germinal-vesicle(GV)-stage mouse oocytes cryopreserved by vitrification, werecapable of resuming meiosis and undergoing normal chromosomaland cytoplasmic maturation to metaphase II. This high frequencyof development occurred against a background of profound alterationsin the structure and organization of the cytoplasm, nucleus,nucleolus and chromatin during the dehydration stage of vitrification.Most, but not all, cytoplasmic and nuclear perturbations returnedto a normal state during post-thaw culture. However, the resultsclearly demonstrate that vitrification is associated with chromosomaland cellular disorders that could adversely affect developmentafter fertilization. Irreversible changes of potential developmentalsignificance observed after vitrification at the GV stage include(i) premature chromosomal condensation, (ii) mixing of nucleoplasmicand cytoplasmic components prior to GV breakdown, and (iii)externalization of chromatin fragments into the cytoplasm afterreformation of the oocyte nucleus, which shows the potentialfor the generation of fertilizable oocytes containing deletedsegments of DNA.     

Mitochondrial distribution and function in oocytes and early embryos

Active mitochondria relocate during oocyte maturation or fertilization in several species. Detailed studies with hamster oocytes and early embryos reveal a pattern of active mitochondria migrating to surround the pronuclei to form a pattern that persists through the early cleavage stages. Although the functional significance of this relocation is unknown, it appears to be an important part of normal development in hamsters. Treatments that disrupt embryo development in vitro (such as the presence of inorganic phosphate or alteration of intracellular pH) also disrupt the normal pattern of mitochondrial distribution. Active mitochondria also reorganize during maturation in bovine oocytes and during fertilization in rhesus monkey oocytes. Examination of these changes in mitochondrial organization may provide insights into the regulation of normal embryo development and might serve as predictors of oocyte or embryo developmental competence.     

Developmental incompetency of denuded mouse oocytes undergoing maturation in vitro is ooplasmic in nature and is associated with aberrant Oct-4 expression

BACKGROUND: Germinal vesicle (GV) oocytes constitute a potential resource but their developmental competence is questionable especially when surrounding cumulus cells are removed. The intercellular factors/mechanisms underlying such poor embryonic competence may originate at a nuclear and/or ooplasmic level. METHODS: Immature or mature oocytes were obtained from three mouse strains following pregnant mare serum gonadotropin (PMSG) or PMSG+ human chorionic gonadotropin (hCG) treatment. Immature oocytes were denuded of cumulus cells prior to in vitro maturation. Pronuclear (PN) transfer was used to examine nuclear-ooplasmic interplay on resultant embryonic development and Oct-4 immuno-staining patterns. RESULTS: Embryos arising from ooplasts of in vivo matured oocytes displayed significant increases in blastocyst formation rates and total blastomere numbers when compared to those created from ooplasts of denuded oocytes. Oct-4 staining was more pronounced and restricted to the inner cell mass (ICM) in blastocysts arising from the ooplasm of in vivo matured zygotes than in those created from denuded oocytes. CONCLUSIONS: Developmental defect(s) appear to develop primarily in the ooplasm of oocytes that are denuded of their cumulus cells prior to in vitro maturation. Such oocytes result in embryos with poor developmental competence. These defects result in anomalies in cell number and Oct-4 expression during the morula-blastocyst developmental transition.     

Effects of myo-inositol on the in-vitro maturation and subsequent development of mouse oocytes

BACKGROUND: The study aim was to assess whether the incorporation of myo-inositol (MI) into culture medium could improve oocyte maturation in vitro. METHODS AND RESULTS: We performed a controlled prospective study using female ICR strain mice superovulated with pregnant mare's serum gonadotrophins. Cumulus-enclosed germinal vesicle (GV) oocytes were randomly cultured in medium with or without MI supplementation. The kinetics of GV breakdown after 4 h of incubation was significantly higher in oocytes incubated with 30 mmol/l of MI than in controls (P < 0.001). Accordingly, this concentration of MI was used for subsequent experiments. The proportion of metaphase II oocytes achieved after 24 h of culture, their fertilization and cleavage rates were significantly higher in the MI-treated group (P < 0.01, P < 0.05, P < 0.05 respectively). This group also demonstrated significant improvement in postimplantation development after transferring the 2-cell embryos to pseudopregnant mice. Confocal microscopy revealed spontaneous intracellular Ca(2+) oscillations within competent GV oocytes and treatment with MI caused an earlier onset of these Ca(2+) signals. CONCLUSIONS: Our results suggest that MI may affect meiotic progression of mouse GV oocytes possibly by enhancing the intracellular Ca(2+) oscillations. Supplementation of MI in culture medium may be useful for human oocyte maturation.     

The oxidizing agent tertiary butyl hydroperoxide induces disturbances in spindle organization, c-meiosis, and aneuploidy in mouse oocytes

It has been recently proposed that a concomitant generationof oxidative stress of oocytes with increasing maternal agemay be a major factor responsible for the age-related increasein aneuploid conceptions. As a preliminary step in the testingof this hypothesis, we need to confirm that oxidative stressin itself can induce errors in chromosome segregation. In orderto achieve this goal, germinal vesicle (GV)-stage mouse oocytesfrom unstimulated ICR and (C57BLxCBA) F₁ hybrid female micewere matured in vitro for 9 h for metaphase I (MI) oocytes or16 h for metaphase II (MII) oocytes in the presence of varyingconcentrations of the oxidizing agent tertiary-butyl hydroperoxide(tBH). MII oocytes from (C57BLxCBA) F₁ hybrid mice were fixedand C-banded for karyotyping analysis. MI and MII oocytes fromICR mice were fixed and stained with the DNAfluorescent probe4',6-diamidino-2-phenylindole (DAPI) to detect abnormalitiesin chromosomal distribution. Meiosis I and meiosis II spindlesfrom ICR mice were visualized by confocal immunofluorescencemicroscopy. Data from these experiments demonstrate that in-vitroexposure of mouse oocytes to tBH during meiosis I reduces thelength (pole-to-pole distance) and width (diameter at the equatorof the spindle) of meiosis I and meiosis II spindles. This reductionis associated with an increase in the percentage of oocytesshowing chromosome scattering and clumping on the MII plate,and of aneuploidy (hyperhaploidy) in MII oocytes. However, tBHat the concentrations used in the present study has only a minimalnegative effect on the frequency of meiotic maturation. Theseresults suggest that oxidative stress during meiotic maturationin vitro may induce chromosomal errors that are undetectablein the living oocyte and whose developmental consequences maybecome manifest after fertilization. aneuploidy/meiosis/mouse oxidative stress/spindle/tertiary butyl hydroperoxide     

Visualization of the metaphase II meiotic spindle in living human oocytes using the Polscope enables the prediction of embryonic developmental competence after ICSI

BACKGROUND: Meiotic spindles in living human oocytes can be visualized by the Polscope. This study investigated the relationship between the presence/location of the spindle in metaphase II (MII) oocytes and developmental competence of embryos in vitro. METHODS: The spindles in 626 MII oocytes were examined by the Polscope and divided into six groups (A-F) based on the presence or absence of the spindles and the angle between the spindle and the first polar body. After ICSI, the fertilization and embryo development were evaluated. RESULTS: Meiotic spindles were imaged in 523 oocytes (83.5%), while 103 (16.5%) did not have a visible spindle (group F). The majority of oocytes (68.8%) had the spindle directly beneath or adjacent to the first polar body (groups A and B: 48.2 and 20.6%). Oocytes in group C (11.2%) had the spindle located between 60 and 120 degrees angle away from the first polar body, those in group D (2.4%) had the spindle located between 120 and 180 degrees angle and those in group E (1.1%) had the spindle located at 180 degrees angle to the first polar body. The fertilization and embryonic development were similar in the oocytes with spindles regardless of spindle position. However, the rate of high quality embryos was significantly higher in the oocytes (64.2%) with visible spindles than in the oocytes (35.9%) without spindle and multipronuclear proportion showed a slight tendency to increase in oocytes without spindles. (10.7 versus 5.9%, P = 0.12; NS). CONCLUSIONS: the presence of a bi-refringent meiotic spindle in human oocytes by using the Polscope can predict a higher embryonic developmental competence. However, the relative position of the spindle within the oocyte doesn't appear to influence the developmental potential of embryos.     

Sperm integrity is critical for normal mitotic division and early embryonic development.

The human zygote relies on the paternal gamete to provide the centrosome component essential for the first mitotic division. It is not known whether normal centrosome function requires an intact spermatozoon, or whether donation of an isolated paternal centrosome component can result in normal zygotes and embryos. To explore this possibility, mature human oocytes were microinjected with either intact or dissected spermatozoa. Fertilization and cleavage rates were documented; nuclear and cytoskeletal changes were observed with fluorescent immunocytochemistry; and chromosomal normality was assessed with fluorescent in-situ hybridization. A pilot study was performed to identify cytoskeletal features suggestive of centrosome function. Unfertilized oocytes and tripronucleate (3PN) zygotes from in-vitro fertilization or intracytoplasmic sperm injection were assessed to confirm the sequence of the landmarks of human fertilization. Oocytes injected with mechanically-dissected spermatozoa appear to be capable of normal pronuclear formation and embryonic cleavage, but do not undergo normal mitotic division. Although decondensed, apposed nuclei are noted in combination with diffuse cytoskeleton assembly, no spindle was detected in any zygote resulting from the injection of a dissected spermatozoon. Analysis of selected embryos resulting from dissected sperm injection revealed chromosomal mosaicism in the majority of specimens. The lack of a bipolar spindle, in combination with chromosomal mosaicism, suggests abnormalities of the mitotic apparatus when sperm integrity is impaired following dissection.     

Preliminary findings in germinal vesicle transplantation of immature human oocytes

Transplanting a germinal vesicle (GV) from an aged woman's oocyte into a younger ooplasm has been proposed as a possible way to reduce the incidence of oocyte aneuploidy which is considered to be responsible for age-related infertility. In this study, we have assessed the efficiency of each step involved in nuclear transplantation-specifically cell survival, nuclear-cytoplasmic reconstitution, and the capacity of the reconstituted oocytes for in-vitro maturation. In addition, we have evaluated the fertilizability and karyotypic status of the manipulated oocytes by intracytoplasmic sperm injection (ICSI) and fluorescent in-situ hybridization technique respectively. Nuclear transplantation was accomplished with an overall efficiency of 73%. Due to the limited availability of materials, most nuclear transplantation procedures were performed between sibling oocytes. The maturation rate of 62% following reconstitution was comparable with that of control oocytes, as was the incidence of aneuploidy among the reconstituted oocytes. The ICSI results of the reconstituted oocytes yielded a survival rate of 77%, a fertilization rate of 52%, and a satisfactory early embryonic cleavage. Furthermore, in a limited number of observations where the nucleus of an aged oocyte was transferred into a younger ooplasm, there was an appropriate chromosomal segregation. These findings demonstrate that human oocytes reconstituted with GV nuclei are able to undergo maturation, fertilization, and early embryo cleavage, and maintain a normal ploidy. Although in-vitro maturation seems to be a limiting step, this technique would allow us to investigate further the nuclear-ooplasmic relationship during meiotic maturation.     

The developmental ability of human oocytes penetrated at the germinal vesicle stage after insemination in vitro

This study demonstrates that sperm penetration into the ooplasmoccurs at high frequency in germinal vesicle (GV)stage humanoocytes which failed to resume meiosis after ovulation inductionin cycles of ovarian hyperstimulation for in-vitro fertilization.The capacity of the immature human oocyte to prevent polyspermicpenetration at the cell surface level was suggested by the findingthat despite the presence of numerous spermatozoa within thezona pellucida and on the oocyte surface within 3 h after insemination,all normal-appearing GV stage oocytes examined in this studywere penetrated by a single spermatozoon. This notion was alsosupported by scanning confocal microscopic analysis of oocytesdouble-stained for DNA and cortical granules– which showedhighly localized regions of cortical granule-free cytoplasmin proximity to the penetrated spermatozoon. The developmentalability of these oocytes was assessed by culture in vitro. Theresults show that oocytes penetrated by a spermatozoon at theGV stage resume meiosis, develop the capacity to decondensesperm DNA, abstrict both first and second polar bodies, andform a male pronucleus from the spermatozoon which enters theoocyte prior to the resumption of meiotic maturation. Afterpenetration, sperm nuclei rapidly migrate to the centre of theoocyte and become juxtaposed with the germinal vesicle, suggestingthe presence of a cellular mechanism which permits directedmovement within the cytoplasm. The developmental ability ofthese oocytes and the normality of the resulting embryos arediscussed