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.     

Analysis of mouse metaphase II oocytes as an assay for chemically induced aneuploidy

Our initial objective was to develop an in vivo mammalian, female aneuploid assay that is consistent, time efficient, and that yields a large number of oocytes amenable to objective analyses. Subsequently, we desired to use such an assay for identifying chemicals and dosages that could increase the incidence of aneuploidy in mouse metaphase II oocytes. The experimental protocol involved superovulating CD-1 mice with PMS; HCG was given 48 h later. At the time of HCG injection, different dosages od diethylstilbestrol diphosphate, cadmium chloride, chloral hydrate, or colchicine were injected intraperitoneally. 17 h later, oocytes were collected and fixed prior to C-banding the chromosomes. The procedure required about 3 h to process oocytes from 25 mice and yielded over 100 analyzable metaphase II oocytes. Colchicine was the only compound tested that resulted in a statistically significant (P less than 0.01) increase in hyperploid (N greater than 20) oocytes over controls. The incidence of hyperploid oocytes in the colchicine group was 2/167, 1/182, 21/220, and 38/202, for control, 0.1 mg/kg, 0.2 mg/kg, and 0.3 mg/kg, respectively. This assay appears sensitive for aneuploidy detection but requires further validation.     

Griseofulvin-induced aneuploidy and meiotic delay in female mouse germ cells. II. Cytogenetic analysis of one-cell zygotes.

The effects of griseofulvin (GF) upon the first meiotic division of female mouse germ cells were evaluated by cytogenetic analysis of first-cleavage (1-Cl) zygotes. The present study is an extension of an investigation that began with the cytogenetic analysis of metaphase II (M II) oocytes. Different doses (200, 666, 1332, 2000 mg/kg) were tested by oral administration of GF to superovulated animals either at the time of human chorionic gonadotrophin (HCG) injection or 2 h post HCG. When GF was given at the time of HCG, significant dose-dependent increases of different types of cytogenetically abnormal cells were found. These included zygotes containing ostensibly female-derived M I or M II arrested chromosomes and polyploid zygotes. The total yields of these aberrations were 2.9, 4.3, 26.2, 60.6, and 64.1% for control, 200, 666, 1332, and 2000 mg/kg, respectively. The origin of these zygotes was attributed to the fertilization of oocytes that had been previously arrested at M I. No significant induction of hyperploidy was detected. Developmentally abnormal zygotes were still observed when GF was administered 2 h post HCG, although their frequencies were significantly lower than in the first series of experiments. The yields of developmentally abnormal zygotes were 49, 10.2, and 23.6% at 200, 666, and 2000 mg/kg. Additionally, a dose-dependent increase in the frequency of hyperploid zygotes was detected up to a maximum of 36.5% at 2000 mg/kg. These results confirm the cytogenetic observations from M II oocytes after GF treatment under the same experimental conditions; namely, a dramatic change in the oocyte target susceptibility to GF occurred within a short time period. Also, the present study demonstrated that most of GF-induced aneuploid oocytes were fertilized and reached first-cleavage metaphase.     

Trichlorfon effects on mouse oocytes following in vivo exposure

Trichlorfon (TCF) is a widely used pesticide, which according to some epidemiological and experimental data, is suspected of being aneugenic in human and mouse cells. In particular, in vitro studies in mouse oocytes showed the induction of aneuploidy and polyploidy at the first meiotic division and of severe morphological alterations of the second meiotic spindle. We have tested the hypothesis that an acute treatment of mice with TCF might similarly affect chromosome segregation in maturing oocytes. Superovulated MF-1 mice were intraperitoneally injected with 400mg/kg TCF or orally administered with 600mg/kg TCF either at the time of or 4h after human chorionic gonadotrophin (HCG) injection. Oocytes were harvested 17h after HCG and metaphase II chromosomes were cytogenetically analyzed. No significant increase of aneuploid or polyploid cells was detected at any treatment condition. A significant (p<0.001) decrease of metaphases showing premature chromatid separation or premature anaphase II in all TCF-treated groups with respect to controls suggested that TCF treatment may have delayed the first meiotic division. To evaluate possible effects of the pesticide upon the second meiotic division, a group of females orally treated with 600mg/kg TCF at resumption of meiosis was mated with untreated males and zygotes were collected for cytogenetic analysis. No evidence of aneuploidy induction was obtained, but the frequency of polyploid zygotes was increased fivefold over the control level (p<0.01). Such polyploid embryos might have arisen from fertilization of oocytes that were either meiotically delayed and still in metaphase I at fertilization or progressed through anaphase II without cytokinesis. These findings show that in vivo studies on aneuploidy induction in oocytes may yield results different from those obtained by in vitro experiments and that both kinds of data may be necessary for risk assessment of environmentally relevant exposures.     

Whole-chromosome aneuploidy analysis in human oocytes: focus on comparative genomic hybridization

The study of aneuploidy in human oocytes, discarded from IVF cycles, has provided a better understanding of the incidence of aneuploidy of female origin and the responsible mechanisms. Comparative genomic hybridization (CGH) is an established technique that allows for the detection of aneuploidy in all chromosomes avoiding artifactual chromosome losses. In this review, results obtained using CGH in single cells (1PB and/or MII oocytes) are included. The results of oocyte aneuploidy rates obtained by CGH from discarded oocytes of IVF patients and of oocyte donors are summarized. Moreover, the mechanisms involved in the aneuploid events, e.g. whether alterations occurred due to first meiotic errors or germ-line mitotic errors are also discussed. Finally, the incidence of aneuploid oocyte production due to first meiotic errors and germ-line mitotic errors observed in oocytes coming from IVF patients and IVF oocyte donors was assessed.     

Frequency of aneuploidy in in vitro-matured MII oocytes and corresponding first polar bodies in two dairy cattle (Bos taurus) breeds as determined by dual-color fluorescent in situ hybridization

The current study was undertaken to investigate the aneuploidy rates in in vitro-matured meiosis II (MII) oocytes and corresponding first polar bodies in two dairy cattle (Bos taurus) breeds by using dual-color fluorescent in situ hybridization (FISH). A total of 159 and 144 in vitro-matured MII oocytes of the Italian Friesian and Italian Brown breeds, respectively, were obtained according to the standard methods and analyzed by FISH using “Xcen” and “5” chromosome-specific painting probes, produced by chromosome microdissection and Degenerate Oligonucleotide Primer- Polymerase Chain Reaction (DOP-PCR). Oocytes with unreduced chromosome number were 10.1% and 16.7% in the two breeds, respectively. To avoid bias due to possible artifacts, the aneuploidy rates were determined by analyzing only oocytes with the corresponding polar bodies. In the Italian Friesian, 100 of 143 (69.9%) secondary MII oocytes showed clear MII plates with corresponding first polar bodies and were scored for aneuploidy detection; one oocyte was “nullisomic” for chromosome X (1.0%) and one “disomic” for chromosome 5 (1.0%). In the Italian Brown, 100 of 120 (83.3%) MII oocytes with corresponding first polar bodies were analyzed; one oocyte was nullisomic (1.0%) and one was disomic (1.0%), both for chromosome 5. Totally, 303 oocytes were analyzed, 40 of which showed an unreduced chromosome complement (13.2%); of 200 MII oocytes with the corresponding first polar bodies, the aneuploidy rate (nullisomy + disomy) for the two chromosomes scored was 2%. Assuming that each chromosome is equally involved in aneuploidy, it results that in cattle oocytes matured in vitro, at least 30% of the oocytes (1 × 30 haploid chromosomes) should be aneuploid. Premature separation of sister chromatids (PSSC) was also observed in 2% of the oocytes in the Italian Friesian breed involving chromosome 5 and in 1% of the Italian Brown breed involving the X chromosome. Estimation of the “baseline” level of aneuploidy in the in vitro-matured oocytes of the various domestic animal species and breeds is, to our opinion, a useful reference for improving the in vitro production of embryos as well as for monitoring future trends of the reproductive health of the species/breeds engaged in zootechnical productions, especially in relation to management errors and environmental hazards.     

Tamoxifen-induced alterations in meiotic maturation and cytogenetic abnormalities in mouse oocytes and 1-cell zygotes

Alterations in the rate of oocyte meiotic maturation (OM) and the timing of the metaphase-anaphase transition may predispose oocytes to premature centromere separation (PCS) and aneuploidy. Tamoxifen has the potential for perturbing the rate of OM since it can function as a calcium antagonist by binding to calmodulin and inhibiting the formation of a calcium-calmodulin complex which is needed for activating calmodulin-dependent cAMP phosphodiesterase and initiating OM. The objective of this study was to test the hypothesis that tamoxifen alters the rate of OM and predisposes oocytes to PCS and aneuploidy. Different does of tamoxifen were administered by oral gavage to female mice preovulation. Metaphase II oocyte and 1-cell zygote chromosomes were C-banded and cytogenetically analysed. Tamoxifen treatment resulted in a modest, but significant (p < 0.05), increase in oocytes with PCS. Similar frequencies of hyperploidy and oocytes with unpaired, single chromatids (SC) were found. Metaphase I, diploid and premature anaphase (PA) oocytes were not detected. Hyperploidy, polyploidy, PCS, PA and SC were not detected in zygotes. These data indicate that the levels of tamoxifen-induced PCS found in mouse oocytes did not predispose zygotes to aneuploidy. Tamoxifen did, however, reduce the proportion of females exhibiting oestrus.     

Sperm-derived activating ability does not persist in mouse oocytes inseminated during in vitro maturation

Activity of the sperm-derived oocyte-activating factor persists in zygotes and can be detected by a fusion with metaphase II (MII) oocytes leading to the activation of the hybrids. We have shown, that in the great majority of oocytes inseminated 1-2 hr after germinal vesicle breakdown (GVBD) the sperm-derived activating ability was eliminated. Only few hybrids produced by fusion of MII oocytes with oocytes inseminated during in vitro maturation (M x IVM-P + sperm hybrids) underwent activation, whereas almost all of MII oocyte x zygote hybrids entered interphase. However, frequency of activation of M x IVM-P + sperm hybrids was higher than that of control hybrids, which were obtained by fusion of MII oocytes with oocytes uninseminated during in vitro maturation. Although the difference was not statistically significant, it suggested that in a certain number of oocytes inseminated after GVBD the sperm-derived oocyte-activating factor remained partially active. This was confirmed by our observation that several oocytes, which were inseminated during in vitro maturation and managed to accomplish MII, underwent activation and formed pronuclei when examined 25-26 hr after the beginning of maturation. We have also demonstrated that parthenogenotes, could acquire the sperm-derived activity, as a consequence of sperm injection. MII oocytes were fused with parthenogenotes inseminated by ICSI and all hybrids underwent activation. This result indicated that the ability to induce activation in hybrid, was sperm-derived.     

Cryopreservation of equine oocytes by 2-step freezing

Immature equine oocytes were frozen-thawed with ethylene glycol (EG), 1,2-propanediol (PD) or glycerol (GL) in PBS and cultured to assess the rate of in vitro maturation (Experiment 1). Compact-cumulus oocyte complexes were collected from slaughterhouse ovaries and equilibrated for 10 min in the freezing medium containing 10% (V/V) cryoprotectant and 0.1 M sucrose. The 0.25-ml straws, loaded with 10 to 30 oocytes, were seeded at -6 degrees C and cooled to -35 degrees C at 0.3 degrees C/min before being plunged into liquid nitrogen. The straws were thawed rapidly in a 37 degrees C waterbath for 20 sec. The proportions of frozen-thawed oocytes reaching Metaphase II (MII) stage after in vitro maturation of 32 h were 15.8% (EG), 5.8% (PD) and 0% (GL), while 63.3% of the nonfrozen control oocytes matured in vitro. The fertilizing ability of immature and mature oocytes after freezing in EG was tested by the insemination of zona-free oocytes with stallion spermatozoa (Experiment 2). Spermatozoa were preincubated for 3 h with 5 mM caffeine, treated with 0.1 mu M ionophore A23187, and inseminated for 20 h at the concentration of 1 to 2 x 10(7)/ml with 6 to 10 oocytes in 50 mu l of Brackett and Oliphant (BO) medium. Immature oocytes (Group 1) were matured in vitro after thawing and then their zona pellucida removed using 0.5% protease. The zona of mature oocytes were removed immediately after thawing (Group 2) or maturation (nonfrozen controls). The oocytes, which had mechanically damaged plasma membrane or lost by artifact, were not examined for insemination. Significantly more control oocytes exhibited a polar body at the time of insemination (53.5%) than either frozen-thawed immature or mature oocytes (25.8 and 27.3%, respectively). Similar proportion of frozen-thawed and control oocytes were penetrated by spermatozoa (71.8 to 79.1%) and exhibited 2 or more pronuclei (73.6 to 80.8%). The mean numbers of spermatozoa per penetrated oocyte were 1.9, 3.0 and 2.5, respectively, for Groups 1 and 2 and for the control oocytes. These results indicate that immature equine oocytes mature to the MII stage in vitro following freezing and thawing in EG or PD but not in GL. Stallion spermatozoa can penetrate zona-free immature and mature oocytes following freezing/thawing in EG and form morphologically normal pronuclei.     

Elimination of X-ray-induced chromosomal aberrations in the progeny of female mice

Female NMRI mice were irradiated with various doses of X-rays and induced chromosome aberrations were scored in MII oocytes (Dosage: 0.222, 0.666, 2 and 6 Gy). After irradiation with 2 Gy, early zygotes were examined in the 2-cell stage; additional dominant lethals were counted and surviving embryos were examined after 13.5 days of pregnancy. 87.2% of the MII oocytes showed structural chromosomal aberrations after irradiation with 2 Gy. Surviving embryos, however, failed to show any increase in the aberration rate. This result points to (almost) complete elimination of genetically damaged oocytes and zygotes already before birth. In addition to the structural aberrations, aneuploidies were induced. Most of them, however, were hypoploidies. Hence, the study confirmed the well-known susceptibility of oocytes around the time of fertilization for induced chromosome loss. Induced hyperploidies, however, were very rare. Evidence for induction of meiotic non-disjunction was weak. In surviving embryos, no increase in numerical aberrations, either hypoploid or hyperploid was discovered. The significance of these data for the prediction of chromosomal damage due to to ionizing radiation in humans is discussed. Recent risk estimates of UNSCEAR and other agencies represent very cautious upper levels.     

Merotelic kinetochore attachment in oocyte meiosis II causes sister chromatids segregation errors in aged mice

Mammalian oocyte chromosomes undergo 2 meiotic divisions to generate haploid gametes. The frequency of chromosome segregation errors during meiosis I increase with age. However, little attention has been paid to the question of how aging affects sister chromatid segregation during oocyte meiosis II. More importantly, how aneuploid metaphase II (MII) oocytes from aged mice evade the spindle assembly checkpoint (SAC) mechanism to complete later meiosis II to form aneuploid embryos remains unknown. Here, we report that MII oocytes from naturally aged mice exhibited substantial errors in chromosome arrangement and configuration compared with young MII oocytes. Interestingly, these errors in aged oocytes had no impact on anaphase II onset and completion as well as 2-cell formation after parthenogenetic activation. Further study found that merotelic kinetochore attachment occurred more frequently and could stabilize the kinetochore-microtubule interaction to ensure SAC inactivation and anaphase II onset in aged MII oocytes. This orientation could persist largely during anaphase II in aged oocytes, leading to severe chromosome lagging and trailing as well as delay of anaphase II completion. Therefore, merotelic kinetochore attachment in oocyte meiosis II exacerbates age-related genetic instability and is a key source of age-dependent embryo aneuploidy and dysplasia.     

Interactions between metaphase and interphase factors in heterokaryons produced by fusion of mouse oocytes and zygotes

The cytoplasmic factor responsible for chromosome condensation was introduced into mouse zygotes at different times after fertilization by fusion of the zygotes with metaphase I oocytes. In 72% of heterokaryons obtained after fusion of early zygotes (14-18 hr post-human chorionic gonadotrophin (HCG) with oocytes, the male and female pronuclei of the zygote decondensed. At the same time, the oocyte chromosomes became enclosed in a nuclear envelope and decondensed to an interphase state. However, in the rest of the heterokaryons, the chromatin of the pronuclei condensed to metaphase chromosomes, thus resulting in three sets of chromosomes. Fusion of zygotes that had begun DNA synthesis (20-22 hr post-HCG) with oocytes induced chromosome condensation of the pronuclei in 76% of the cases. In some heterokaryons, however, the oocyte chromosome decondensed to an interphase state similar to the zygote pronuclei. Fusion between late zygotes (27-29 hr post-HCG) with oocytes resulted in chromosome condensation of the pronuclei in all heterokaryons. On the basis of these results, the formation of the pronuclei and their progression toward mitosis in the zygote may be explained by changing levels of a metaphase factor in the cell, or by a balance between interphase and metaphase factors.     

Timing of meiotic progression in bovine oocytes and its effect on early embryo development

This study was designed to investigate the effect of the kinetics of nuclear maturation in bovine oocytes on early embryo development and to examine whether the time of insemination of mature oocytes affects the oocytes' ability to support events of early embryo development. The time required for completion of nuclear maturation was influenced by gonadotropins used to supplement the maturation medium. Luteinizing hormone (LH) enhanced the speed of nuclear maturation when compared to follicle-stimulating hormone (FSH). Oocytes completing their nuclear maturation early (by 16 hours after the initiation of culture) were more likely to complete the first embryonic cell cycle (78% in LH vs. 43% in FSH) and develop to the blastocyst stage (47% in LH vs. 34% in FSH). As the age of the oocytes at the time of MII arrest increased (extrusion of the polar body by 20 or 24 hours), a decrease in their ability to cleave and develop to the blastocyst stage was observed. Differences in the oocyte's ability to decondense chromatin and form pronuclei were also observed. Early maturing oocytes started forming pronuclei earlier than their later maturing counterparts. The time of insemination of mature oocytes played an equally important role. Generally, when insemination of mature oocytes was delayed for 8 hours, higher proportions of fertilized oocytes developed to advanced preimplantation stages than did the oocytes inseminated immediately after metaphase II arrest. Mol. Reprod. Dev. 47:456–467, 1997. © 1997 Wiley-Liss, Inc.     

The genetic basis of non-disjunction: Increased incidence of hyperploidy in oocytes from F1 hybrid mice

Summary Oocytes from parental mice strains NMRI/Han, C57/bl and Balb/c and from F₁ hybrid lines were analysed for aneuploidy due to non-disjunction after gonadotropin-stimulated ovulation. No hyperploid oocytes were present in five of the strains studied. F₁ hybrids from crosses of NMRI/HanxC57/bl did ovulate, however, a significantly increased number of hyperploid oocytes, although females from their parental strains show a rather low incidence of non-disjunction. The evidence for a genetic basis for non-disjunction is assessed and possible causative factors are discussed.Dedicated to Professor Dr.P.E. Becker on the occasion of his 75th birthday     

Mitochondrial organization in prepubertal goat oocytes during in vitro maturation and fertilization

The aim of this study was to evaluate mitochondrial distribution during in vitro maturation (at 0, 15, 20, and 27 hr of IVM) and fertilization of prepubertal goat oocytes compared to mitochondrial distribution of ovulated and in vitro fertilized oocytes from adult goats. Oocytes from prepubertal goats were recovered from a slaughterhouse and were matured in M199 with hormones and serum for 27 hr. Ovulated oocytes were collected from gonadotrophin-treated Murciana goats. Frozen-thawed spermatozoa were selected by centrifugation in Percoll gradient and were capacitated in DMH with 20% steer serum for 1 hr. Ovulated and IVM-oocytes were inseminated in DMH medium with steer serum and calcium lactate for 20 hr. Oocytes and presumptive zygotes were stained with Mitotraker Green FM and observed under a confocal laser scanning microscope. Ultrastructural morphology of oocytes and presumptive zygotes were analyzed by transmission electron microscopy (TEM). Prepubertal goat oocytes at germinal vesicle stage (GV) presented mitochondria localized in the cortical and perinuclear region. IVM-oocytes at metaphase II presented mitochondria peripheral polarized to the region opposite were the metaphase spindle is positioned and within the polar body. Ovulated oocytes presented peripheral mitochondria distribution and mitochondrial aggregation around the MII spindle. At 20 hr post-insemination, mitochondria were distributed around the two synchronous pronuclei (2PN rpar; in zygotes ovulated oocytes whereas in prepubertal 2PN-zygotes mitochondria presented a peripheral polarized distribution. Images by TEM detected that immature prepubertal goat oocytes that are less electrodense and present fewer cristae than in vitro matured prepubertal goat oocytes; these are characterized by being associated to swollen vesicles. Mol. Reprod. Dev. 73: 617-626, 2006 (c) 2006 Wiley-Liss, Inc.     

Differential chromatin condensation of female and male pronuclei in mouse zygotes

Mouse zygotes or halves of zygotes, containing either a female or a male pronucleus, were fused with ovulated metaphase II oocytes. In 59.7% of the resulting hybrid cells, the pronuclei underwent premature chromosome condensation (PCC). In some of these heterokaryons the 2 pronuclei differed in the dynamics of condensation. Detectability of differential PCC of pronuclei (dPCC) depended on the type of preparation. In hybrids with PCC, produced by fusion of intact zygotes with metaphase II oocytes and processed for whole-mount preparations, one pronucleus was more advanced in the condensation process in 47% of cases. In air-dried preparations dPCC was detected in as many as 94% of hybrids. Experiments with the fusion of halves of zygotes with metaphase II oocytes have shown that the differential reaction of pronuclei to condensation factor depended on their parental origin. Maternal chromatin responded faster to the condensation factor and attained more advanced stages of PCC than paternal chromatin. Different responses of the maternal and paternal pronucleus to the condensation factor suggests that the 2 pronuclei are not identical with regard to the organization of chromatin and/or the lamin composition of the nuclear envelope. © 1993 Wiley-Liss, Inc.     

Meiotic arrest and aneuploidy induced by vinblastine in mouse oocytes

Young superovulated female mice were injected i.p. with single doses of vinblastine sulfate just before the onset of the first meiotic division. Secondary oocytes, fixed one by one on a slide, were cytogenetically scored. Evidence of the meiotic arresting activity of vinblastine was produced by the observation of increasing frequencies of M1-arrested oocytes and by the presence of undegenerated chromosome sets of first polar bodies. When the first meiotic division could be undertaken chromosome malsegregation occurred with high frequency, both in terms of aneuploidy and polyploidy. M1-blocked and polyploid oocytes have been interpreted as the consequence of irreversible damage to the spindle induced by vinblastine through its binding on tubulin low-affinity sites; this reaction, in fact, causes microtubule crystallization. According to this mechanism, dose-effect relationships of both phenomena show a threshold at 0.45 mg/kg. On the other hand, the incidence of aneuploid oocytes is correlated with meiotic delay, as detected by the delayed degeneration of polar bodies, and increases linearly with dose. Both phenomena are, therefore, stochastic and can be referred to the binding of the chemical on tubulin high-affinity sites, which is known to cause tubulin depolymerization in a colchicine-like way.     

Chromosomal analysis of mammalian oocytes matured in vitro with various culture systems

The objective of this study was to evaluate oocyte maturation in vitro. Ten virgin CD-1 mice were used with 3 replications for in vitro with 4 different culture media. Media were minimal essential medium (MEM) with Earl's salt, Waymouth MB 752/1 (MB 752/1), BGjb medium (BGjb), and tissue culture medium-199 (TCM-199). The oocyte chromosomes were C-banded to enable an objective analysis of the chromosome abnormality and number. There was a percentage of blockage at metaphase I (M I), in matured oocytes in all culture media. Metaphase II (M II) was reached by 70.9 to 87.3% of oocytes in 4 different culture media. The frequencies of hyperploid M II oocytes were 0.0, 1.1, 2.8 and 2.6% for TCM-199, MEM, MB 752/1 and BGjb, respectively. A small proportion of oocytes was also found to be polyploid in 4 different culture media. There was an occurrence of premature centromere separation among oocytes. It was concluded that the chromosomes of the oocytes matured in vitro were not all in the normal condition (being at M II). The media used in this study for oocyte maturation caused maturation delay (being blocked at M I), premature centromere separation, polyploidy, and aneuploidy (such as, hyperploid, hypoploid).     

Microtubule and microfilament organization in immature, in vitro matured and in vitro fertilized prepubertal goat oocytes

The aim of our study was to analyse the cytoskeletal organization of prepubertal goat oocytes. Microtubule and microfilament organization during in vitro maturation of prepubertal and adult goat oocytes and presumptive zygotes of in vitro matured-in vitro fertilized (IVM-IVF) prepubertal goat oocytes were analysed. Oocytes were matured in M-199 with hormones and serum and inseminated with frozen-thawed sermatozoa. Oocytes and presumptive zygotes were treated with anti-alpha-tubulin antibody and fluorescein isothiocyanate (FITC)-labelled goat anti-mouse antibody to stain the microtubules. Microfilaments were localized by means of phalloidin 5 microg/ml conjugated with fluorescein isothiocyanate (FITC-phalloidin). DNA was stained with propidium iodide. Stained oocytes were observed under a confocal laser scanning microscope. At the germinal vesicle nuclear stage, microfilaments were distributed at the cortex of the oocytes. After in vitro maturation, 91.7% of metaphase II (MII) oocytes from adult goats displayed microfilaments in the cortex and within the polar body and were characterized by the presence of a microfilament thickening at the cortical region over the meiotic spindle. In prepubertal goat MII oocytes only 5.7% of oocytes displayed microfilaments at the cortex and within the polar body. After insemination, most of the zygotes displayed microfilaments distributed at the cortex. An undefined microtubular network was observed in adult and prepubertal goat oocytes at the germinal vesicle stage. After in vitro maturation, 100% of MII oocytes from adult goats displayed microtubules on the meiotic spindle and within the polar body. This pattern of distribution was observed in 71.6% of prepubertal goat oocytes. Undefined microtubule networks were present in most of the zygotes analysed. In conclusion, cytoskeletal differences were found between prepubertal and adult goat MII oocytes. Furthermore, most of the zygotes from IVM-IVF prepubertal goat oocytes displayed cytoskeletal anomalies.     

Disturbances of nuclear maturation in BCB positive oocytes collected from peri-pubertal gilts

The developmental competence (quality) of oocytes is affected by several factors linked to their intrinsic properties and also to growth and maturation environment. Donor puberty and chromosomal complement are one of the main factors influencing oocyte quality. A high rate of porcine oocytes matured in vitro is chromosomally imbalanced. Moreover, there is no published data on chromosomal aberrations in oocytes selected by the brilliant cresyl blue (BCB) test. Therefore, the aim of this study was to analyze whether BCB positive (BCB+) oocytes derived from ovaries of peripubertal gilts (prepubertal NCL and cyclic CL) differ with respect to the incidence of numerical chromosome aberrations. COCs collected from NCL and CL ovaries were selected by the BCB test. Only BCB+ oocytes were matured in vitro and subjected to FISH analysis using molecular probes for chromosome pairs 1 and 10. The rate of BCB+ oocytes was similar for both groups of ovaries (NCL 80%, CL 92%). Altogether 554 oocytes were fixed and 471 oocytes at the MII stage were analyzed cytogenetically. Diploid (2MII) and aneuploid oocytes were detected. The contribution of MII oocytes was similar for NCL (85%) and CL (90%) group. Chromosomally aberrant BCB+ oocytes accounted for 18.0% and ranged from 13.7% for CL and 22.2% for NCL ovaries. Diploidy was a predominant anomaly observed (11.2%) with a significantly higher frequency in BCB+ oocytes of pre-pubertal (16.7%) than cyclic gilts (5.6%, P < 0.05). Aneuploid oocytes occurred with similar rate in NCL (6.7%) and CL (8.5%) females. The majority of aneuploid spreads (72.2%; P < 0.01) concerned the chromosome pair 10. The overall rate of disomy (56%) and nullisomy (44.4%) was similar. We have shown that donor puberty affects the incidence of chromosomal abnormalities in porcine oocytes matured in vitro. Significantly more diploid oocytes was derived from prepubertal ovaries, whereas the frequency of aneuploidy was similar in NCL and CL gilts.