Dithiothreitol induces sperm nuclear decondensation and protects against chromosome damage during male pronuclear formation in hybrid zygotes between Chinese hamster spermatozoa and Syrian hamster oocytes

The present study was undertaken to investigate whether a time lag in sperm nuclear decondensation and male pronuclear formation in the course of development of eggs is associated with any occurrence of structural chromosome aberrations in male genomes of hybrid zygotes between Chinese hamster spermatozoa and zona-free Syrian hamster oocytes. Shortly after insemination, hybrid zygotes were treated with dithiothreitol (DTT) at different concentrations (0.1-10.0 mM) for 30 min to reduce protamine disulphide (S-S) bonds and thereby accelerate sperm nuclear decondensation and male pronuclear formation. The incidence of sperm nuclear decondensation and male pronuclear formation increased with increasing DTT concentrations, indicating that a reduction in S-S bonds effectively induces these cytological events. Chromosomes of male genomes in hybrid zygotes generated by treatment with 1.0 mM, 2.5 mM and 10.0 mM DTT were analysed at the first cleavage metaphase. Incidence of structural chromosome aberrations in each treatment was 34.5%, 27.1% and 24.7%, respectively. There was a significant difference between the incidences with 1.0 mM and 10.0 mM DTT treatment. As the time lag in nuclear decondensation and male pronuclear formation was greatest in the 1.0 mM treatment condition, followed in order by 2.5 mM and 10.0 mM, it is suggested that the lag in sperm nuclear development behind egg development is responsible for structural chromosome aberrations in male genomes of hybrid zygotes.     

Glutathione (GSH) concentrations vary with the cell cycle in maturing hamster oocytes,zygotes, and pre-implantation stage embryos

Glutathione (GSH) is thought to play critical roles in oocyte function including spindle maintenance and provision of reducing power needed to initiate sperm chromatin decondensation. Previous observations that GSH concentrations are higher in mature than immature oocytes and decline after fertilization, suggest that GSH synthesis may be associated with cell cycle events. To explore this possibility, we measured the concentrations of GSH in Golden Hamster oocytes and zygotes at specific stages of oocyte maturation and at intervals during the first complete embryonic cell cycle. Between 2 and 4 hr after the hormonal induction of oocyte maturation, GSH concentrations increased significantly (approximately doubling) in both oocytes and their associated cumulus cells. This increase was concurrent with germinal vesicle breakdown and the condensation of metaphase I chromosomes in the oocyte. GSH remained high in ovulated, metaphase II (MII) oocytes, but then declined significantly, by about 50%, shortly after fertilization, as the zygote progressed back into interphase (the pronucleus stage). GSH concentrations then plummeted by the two-cell embryo stage and remained at only 10% of those in MII oocytes throughout pre-implantation development. These results demonstrate that oocyte GSH concentrations fluctuate with the cell cycle, being highest during meiotic metaphase, the critical period for spindle growth and development and for sperm chromatin remodeling. These observations raise the possibility that GSH synthesis in maturing oocytes is regulated by gonadotropins, and suggest that GSH is more important during fertilization than during pre-implantation embryo development.     

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.     

Kinetochore appearance during meiosis,fertilization and mitosis in mouse oocytes and zygotes

The events of mammalian fertilization overlap with the completion of meiosis and first mitosis; the pronuclei never fuse, instead the parental genomes first intermix at the mitotic spindle equator at metaphase. Since kinetochores are essential for the attachment of chromosomes to spindle microtubules, this study explores their appearance and behavior in mouse oocytes, zygotes and embryos undergoing the completion of meiosis, fertilization and mitoses. Kinetochores are traced with immunofluorescence microscopy using autoimmune sera from patients with CREST (CREST = calcinosis, Raynaud's phenomenon, esophageal dysmotility, sclerodactyly, telangiectasia) scleroderma. These sera cross-react with the 17 kDa centromere protein (CENP-A) and the 80 kDa centromere protein (CENP-B) found at the kinetochores in human cell cultures. The unfertilized oocyte is ovulated arrested at second meiotic metaphase and kinetochores are detectable as paired structures aligned at the spindle equator. At meiotic anaphase, the kinetochores separate and remain aligned at the distal sides of the chromosomes until telophase, when their alignment perpendicular to the spindle axis is lost. The female pronucleus and the second polar body nucleus each receive a detectable complement of kinetochores. Mature sperm have neither detectable centrosomes nor detectable kinetochores, and shortly after sperm incorporation kinetochores become detectable in the decondensing male pronucleus. In pronuclei, the kinetochores are initially distributed randomly and later found in apposition with nucleoli. At mitosis, the kinetochores behave in a pattern similar to that observed at meiosis or mitosis in somatic cells: irregular distribution at prophase, alignment at metaphase, separation at anaphase and redistribution at telophase. They are also detectable in later stage embryos. Colcemid treatment disrupts the meiotic spindle and results in the dispersion of the meiotic chromosomes along the oocyte cortex; the chromosomes remain condensed with detectable kinetochores. Fertilization of Colcemid-treated oocytes results in the incorporation of a sperm which is unable to decondense into a male pronucleus. Remarkably kinetochores become detectable at 5 h post-insemination, suggesting that the emergence of the paternal kinetochores is not strictly dependent on male pronuclear decondensation.     

Behavior of sperm nuclei in intact and bisected metaphase II mouse oocytes fertilized in the presence of colcemid

Our objective was to examine the developmental fate of sperm nuclei in oocytes fertilized under conditions of meiotic arrest. Therefore zona-free metaphase II oocytes and oocyte fragments (nucleate and anucleate) were fertilized in the presence of colcemid. In anucleate oocyte fragments, normal male pronuclei develop. In contrast, in intact oocytes and nucleate fragments sperm nuclei after initial decondensation undergo secondary condensation. This state is maintained as long as the oocytes are treated with colcemid. When the drug is removed 3 h after insemination, the meiotic spindle(s) is reconstructed, the second polar body(ies) is extruded, and a female pronucleus (or micronuclei) forms. At the same time the sperm nucleus decondenses again and transforms into a male pronucleus. In addition oocytes fertilized in the presence of colcemid could not be refertilized. These observations suggest that oocytes and oocyte fragments fertilized in the presence of colcemid undergo activation despite the failure of pronucleus formation. The inhibitory effect of colcemid on the formation of pronuclei is expressed only in the presence of oocyte chromosomes. We suggest that colcemid stabilizes factors responsible for chromosome condensation that are associated with oocyte chromosomes but not factors (whether the same or different) present in the cytoplasm.     

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.     

利用卵胞浆精子注射（ICSI）技术生产转基因小鼠

在掌握小鼠ICSI技术的基础上,进行了ICSI技术生产转基因小鼠的研究。来自成年KM小鼠附睾尾的精子,使用未加抗冻剂的HEPES-CZB溶液,在液氮中冻融1次后,用于本实验。解冻精子与DNA混匀1min后,精子头被显微注射到B6D2F1小鼠成熟卵母细胞质中。精子头与pEGFP-N1环状DNA共注射生产的ICSI受精卵,在CZB溶液中培养至囊胚期时,39.1%(9/23)的囊胚表达GFP基因。精子注射后6h,直接移植ICSI受精卵后,7只妊娠受体一共产仔30只,效率为23.8%(30/126)。Southernblot分析其中16只小鼠发现,3只(18.8%)转基因小鼠同时整合了GFP和Neomycin基因,它们全部来自精子和线性DNA混合的实验组(阳性效率为33.3%,3/9),相反,精子与环状质粒DNA共注射生产的7只ICSI后代中,没有检测到外源基因。转基因小鼠整合的外源基因能够传递给它们后代。结果说明,利用ICSI技术可以高效地生产转基因小鼠,宿主基因组可能更容易整合线性化的外源基因。     

The role of disulfide bond reduction during mammalian sperm nuclear decondensation in vivo

These studies were designed to test the hypothesis that sperm nuclear decondensation and male pronuclear formation during hamster fertilization depend upon the ability of the fertilized oocyte to reduce sperm nuclear disulfide bonds. In a first series of experiments, treatment of mature oocytes with the sulfhydryl blocking agent iodoacetamide or the glutathione oxidant diamide caused a dose-dependent inhibition of decondensation in microinjected sperm nuclei. Inhibition of decondensation was not observed, however, when sperm nuclei were treated in vitro with dithiothreitol (DTT) to reduce disulfide bonds prior to their microinjection. In a second series of experiments, germinal vesicle (GV)-intact oocytes and pronuclear eggs, in which mature, disulfide-rich sperm nuclei do not decondense, were found to support the decondensation of disulfide-poor DTT-treated sperm nuclei or testicular spermatid nuclei. The decondensed sperm nuclei were not, however, transformed into male pronuclei. The results of these studies suggest: (1) that sperm nuclear decondensation in the hamster requires disulfide bond reduction, (2) that GV-intact oocytes and pronuclear eggs lack sufficient reducing power to effect sperm nuclear decondensation, and (3) that disulfide bond reduction is required but not sufficient for pronuclear formation.     

Morphological events during in vitro fertilization of prepubertal goat oocytes matured in vitro

Experiments were carried out to study morphological changes temporally associated with in vitro fertilization (IVF) of prepubertal goat oocytes and to elucidate some of the abnormalities occurring during this process. The effects of different intervals of insemination on subsequent embryonic development were also studied. Prepubertal goat oocytes collected at slaughter were matured in TCM199 supplemented with estrous goat serum (20%), FSH (10 microg/ml), LH (10 microg/ml) and estradiol-17 beta (1 microg/ml) for 27 h at 38.5 degrees C. Matured oocytes were inseminated with freshly ejaculated spermatozoa following capacitation as described by Younis et al. (37) but with 100 microg/ml heparin. Representative oocytes were fixed every 2 to 4 h from 2 to 28 h after insemination for a study of sperm penetration, sperm head decondensation, meiotic activation, female chromosome decondensation, and male and female pronuclear formation. At the same intervals after insemination, some of the ova were co-cultured on granulosa cell monolayers for up to 9 d. Sperm penetration into the ooplasm was first observed at 4 h post insemination; decondensation of male and female chromatin and formation of male and female pronuclei occurred at 6 to 8 and 10 to 16 h after insemination, respectively. Highest proportions of oocytes were penetrated after exposure to spermatozoa for 8 h. There were no significant differences in ovum penetration after longer insemination intervals. Cleavage was first observed 24 h after insemination. Three types of abnormalities were observed. These were polyspermy, polygyny and asynchrony in the development of the female and male pronuclei, apparently due to a delay in the decondensation of the male pronucleus. Significantly higher proportions of oocytes cleaved (31.2 to 45.5%) after 20, 24 or 28 h insemination intervals than following shorter intervals of exposure to spermatozoa. However, the sperm exposure interval did not significantly affect subsequent embryonic development to the blastocyst stage. Embryos resulting from oocytes exposed to sperm cells for at least 12 h developed further than the 8-cell stage.     

Pronucleus formation, DNA synthesis and metaphase entry in porcine oocytes following intracytoplasmic injection of murine spermatozoa

The onset of pronucleus formation and DNA synthesis in porcine oocytes following the injection of porcine or murine sperm was determined in order to obtain insights into species-specific paternal factors that contribute to fertilisation. Similar frequencies of oocytes with female pronuclei were observed after injection with porcine sperm or with murine sperm. In contrast, male pronuclei formed 8-9 h following the injection of porcine sperm, and 6-8 h following the injection of murine sperm. After pronucleus formation maternally derived microtubules were assembled and appeared to move both male and female pronuclei to the oocyte centre. A few porcine oocytes entered metaphase 22 h after the injection of murine sperm, but normal cell division was not observed. The mean time of onset of S-phase in male pronuclei was 9.7 h following porcine sperm injection and 7.4 h following mouse sperm injection. Ultrastructural observation revealed that male pronuclei derived from murine sperm in porcine oocytes are morphologically similar to normal male pronuclei in porcine zygotes. These results suggest that species-specific paternal factors influence the onset of pronucleus formation and DNA synthesis. However, normal nuclear cytoplasmic interactions were observed in porcine S-phase oocytes following murine sperm injection.     

The timing of hamster sperm nuclear decondensation and male pronucleus formation is related to sperm nuclear disulfide bond content

The relationship between the timing of both sperm nuclear decondensation and male pronucleus formation in the oocyte and the relative level of disulfide bonds within the sperm nucleus was evaluated. Since reduction of sperm nuclear disulfide (S-S) bonds is a prerequisite for sperm nuclear decondensation in vitro and in vivo, we hypothesized that sperm nuclei with relatively few S-S bonds would require less time to decondense in the oocyte than sperm nuclei with higher numbers of S-S bonds, and that male pronucleus formation would occur more rapidly as well. Four types of hamster sperm nuclei, in which the extent of S-S bonding differed, were microinjected into hamster oocytes, and the time course of sperm nuclear decondensation and male pronucleus formation was charted. Cauda epididymal sperm nuclei, which are rich in S-S bonds, required 45-60 min to decondense. In contrast, nuclei containing few S-S bonds (namely sonication-resistant spermatid nuclei and cauda epididymal sperm nuclei treated in vitro with the S-S bond-reducing agent dithiothreitol) decondensed within 5-10 min of microinjection. Caput epididymal sperm nuclei, with intermediate S-S bond content, decondensed in 10-20 min. Regardless of when decondensation occurred, formation of the male pronucleus never preceded that of the female pronucleus, which occurred 1.25-1.5 h after microinjection. However, sperm nuclei with few S-S bonds were more likely than S-S rich nuclei to transform into male pronuclei in synchrony with the formation of the female pronucleus. We conclude that the timing sperm nuclear decondensation and pronucleus formation depends in part upon the S-S bond content of the sperm nucleus.     

Pronuclear formation in starfish eggs inseminated at different stages of meiotic maturation: correlation of sperm nuclear transformations and activity of the maternal chromatin

Changes in sperm nuclei incorporated into starfish, Asterina miniata, eggs inseminated at different stages of meiosis have been correlated with the progression of meiotic maturation. A single, uniform rate of sperm expansion characterized eggs inseminated at the completion of meiosis. In oocytes inseminated at metaphase I and II the sperm nucleus underwent an initial expansion at a rate comparable to that seen in eggs inseminated at the pronuclear stage. However, in oocytes inseminated at metaphase I, the sperm nucleus ceased expanding by meiosis II and condensed into chromosomes which persisted until the completion of meiotic maturation. Concomitant with the formation and expansion of the female pronucleus, sperm chromatin of oocytes inseminated at metaphase I enlarged and developed into male pronuclei. Condensation of the initially expanded sperm nucleus in oocytes inseminated at metaphase II was not observed. Instead, the enlarged sperm nucleus underwent a dramatic increase in expansion commensurate with that taking place with the maternal chromatin to form a female pronucleus. Fusion of the relatively large female pronucleus and a much smaller male pronucleus was observed in eggs fertilized at the completion of meiotic maturation. In oocytes inseminated at metaphase I and II, the male and female pronuclei, which were similar in size, migrated into juxtaposition, and as separate structures underwent prophase. The chromosomes in each pronucleus condensed, intermixed, and became aligned on the metaphase palate of the mitotic spindle in preparation for the first cleavage division. These observations demonstrate that the time of insemination with respect to the stage of meiotic maturation has a significant effect on sperm nuclear transformations and pronuclear morphogenesis.     

Germinal vesicle materials are requisite for male pronucleus formation but not for change in the activities of CDK1 and MAP kinase during maturation and fertilization of pig oocytes

In amphibian oocytes, it is known that germinal vesicle (GV) materials are essential for sperm head decondensation but not for activation of MPF (CDK1 and cyclin B). However, in large animals, the role of GV materials in maturation and fertilization is not defined. In this study, we prepared enucleated pig oocytes at the GV stage and cultured them to examine the activation and inactivation of CDK1 and MAP kinase during maturation and after electro-activation. Moreover, enucleated GV-oocytes after maturation culture were inseminated or injected intracytoplasmically with spermatozoa to examine their ability to decondense the sperm chromatin. Enucleated oocytes showed similar activation/inactivation patterns of CDK1 and MAP kinase as sham-operated oocytes during maturation and after electro-stimulation or intracytoplasmic sperm injection. During the time corresponding to MI/MII transition of sham-operated oocytes, enucleated oocytes inactivated CDK1. However, penetrating sperm heads in enucleated oocytes did not decondense enough to form male pronuclei. To determine whether the factor(s) involved in sperm head decondensation remains associated with the chromatin after GV breakdown (GVBD), we did enucleation soon after GVBD (corresponding to pro-metaphase I, pMI) to remove only chromosomes. The injected sperm heads in pMI-enucleated oocytes decondensed and formed the male pronuclei. These results suggest that in pig oocytes, GV materials are not required for activation/inactivation of CDK1 and MAP kinase, but they are essential for male pronucleus formation.     

Sperm nuclear enlargement in fertilized hamster eggs is related to meiotic maturation of the maternal chromatin

Experiments were conducted to test the hypothesis that sperm nuclear expansion in fertilized hamster eggs is correlated with meiotic processing of the maternal chromatin. In vitro fertilized hamster eggs were fixed at regular intervals following insemination, stained with the DNA specific fluorochrome, Hoechst 33342, and the extent of sperm nuclear expansion measured. Sperm nuclei enlarged in multiple, distinct phases (A-E) that were temporally correlated with meiotic processing of the maternal chromosomes: phase A, metaphase II; phase B, early anaphase II; phase C, late anaphase II, and phases D and E, female pronuclear development and expansion. During phase A, sperm nuclei were unchanged but enlarged at different rates during phases B (272 microns2/min), D (106 microns2/min) and E (29 microns2/min), and condensed during phase C (rate = -102 microns2/min). Area increases of both sperm nuclei and female pronuclei during phase D were significantly less in polyspermic and polygynic zygotes. If sperm nuclear enlargement and the status/activity of the maternal chromatin were correlated, it would be anticipated that alterations in the normal progression of meiotic maturation would be manifested in sperm nuclear expansion. The following agents affected both meiotic maturation and sperm nuclear enlargement: colchicine, antimycin A, and puromycin. These observations suggest that processes attending sperm nuclear transformations, the completion of maternal meiotic maturation, and development of the female pronucleus are coupled and may be linked by common regulatory agents.     

DNA synthesis in the fertilizing hamster sperm nucleus: sperm template availability and egg cytoplasmic control

To assess the role of the availability of sperm nuclear templates in the regulation of DNA synthesis, we correlated the morphological status of the fertilizing hamster sperm nucleus with its ability to synthesize DNA after in vivo and in vitro fertilization. Fertilized hamster eggs were incubated in 3H-thymidine for varying periods before autoradiography. None of the decondensed sperm nuclei nor early (Stage I) male pronuclei present after in vivo or in vitro fertilization showed incorporation of label, even in polyspermic eggs in which more advanced pronuclei were labeled. In contrast, medium-to-large pronuclei (mature Stage II pronuclei) consistently incorporated 3H-thymidine. To investigate the contribution of egg cytoplasmic factors to the regulation of DNA synthesis, we examined the timing of DNA synthesis by microinjected sperm nuclei in eggs in which sperm nuclear decondensation and male pronucleus formation were accelerated experimentally by manipulation of sperm nuclear disulfide bond content. Although sperm nuclei with few or no disulfide bonds decondense and form male pronuclei faster than nuclei rich in disulfide bonds, the onset of DNA synthesis was not advanced. We conclude the the fertilizing sperm nucleus does not become available to serve as a template for DNA synthesis until it has developed into a mature Stage II pronucleus, and that, as with decondensation and pronucleus formation, DNA synthesis also depends upon egg cytoplasmic factors.     

Interspecies differences in the stability of mammalian sperm nuclei assessed in vivo by sperm microinjection and in vitro by flow cytometry

To assess the structural stability of mammalian sperm nuclei and make interspecies comparisons, we microinjected sperm nuclei from six different species into hamster oocytes and monitored the occurrence of sperm nuclear decondensation and male pronucleus formation. The time course of sperm decondensation varied considerably by species: human and mouse sperm nuclei decondensed within 15 to 30 min of injection, and chinchilla and hamster sperm nuclei did so within 45 to 60 min, but bull and rat sperm nuclei remained intact over this same period of time. Male pronuclei formed in oocytes injected with human, mouse, chinchilla, and hamster sperm nuclei, but rarely in oocytes injected with bull or rat sperm nuclei. However, when bull sperm nuclei were pretreated with dithiothreitol (DTT) in vitro to reduce protamine disulfide bonds prior to microinjection, they subsequently decondensed and formed pronuclei in the hamster ooplasm. Condensed rat spermatid nuclei, which lack disulfide bonds, behaved similarly. The same six species of sperm nuclei were induced to undergo decondensation in vitro by treatment with DTT and detergent, and the resulting changes in nuclear size were monitored by phase-contrast microscopy and flow cytometry. As occurred in the oocyte, human sperm nuclei decondensed the fastest in vitro, followed shortly by chinchilla, mouse, and hamster and, after a lag, by rat and bull sperm nuclei. Thus species differences in sperm nuclear stability exist and appear to be related to the extent and/or efficiency of disulfide bonding in the sperm nuclei, a feature that may, in turn, be determined by the type(s) of sperm nuclear protamine(s) present.     

Parthenogenetic activation of Chinese hamster oocytes by chemical stimuli and its cytogenetic evaluation

This study was undertaken parthenogenetically to activate Chinese hamster oocytes in vitro by chemical stimuli. Oocytes were exposed to five different chemical agents, ethanol (EtOH), strontium chloride (SrCl₂), cycloheximide (CHX), phorbol ester (PMA), and ionophore A23187 (IA23). No parthenogenetic activation was observed in the oocytes treated with 8% EtOH for 8–11 min, 1.7 mM and 5.0 mM SrCl₂ for 1 hr, 100 μM and 400 μM CHX for 2 hr, and 81 nM and 162 nM PMA for 5 min. In contrast, 89.7% of oocytes parthenogenetically extruded the second polar body in treatment with 3 μM IA23 for 5 min, but only 22.6% of them formed a pronucleus and developed to 2-cell embryos. The remaining ova stopped their cell cycle immediately after completion of the second meiotic division. They had unichromatid chromosomes (monads), which are called MIII chromosomes. Treatment with 5 μM IA23 for 5 min was so deleterious that >90% of oocytes were degenerated. However, oocyte activation was significantly improved when the treatment with 3 μM IA23 for 5 min was followed by treatment with 8% EtOH for 10 min, 100 μM CHX for 2 hr, 81 nM PMA for 5 min or 3 μM IA23 for 5 min: rates of pronuclear formation were 54.4%, 84.3%, 34.2%, and 54.6%, respectively. More than 80% of pronucleate ova successfully developed into 2-cell stage. Additive treatment with 5 mM SrCl₂ for 1 hr had no positive effect on pronuclear formation. Incidences of aneuploidy (4.6%) and structural chromosome aberrations (1.0%) in parthenogenons produced by combined stimuli of IA23 and CHX were not significantly different from those (3.8% and 1.6%, respectively) in female pronuclei of ova fertilized in vitro, showing that combined treatments with IA23 and CHX cause neither nondisjunction at the second meiotic division nor structural aberrations in MII chromosomes. The present technique for parthenogenetic activation of Chinese hamster oocytes may be useful as an assessment system to detect aneugenic and clastogenic effects of mutagens on mammalian oocytes. Mol. Reprod. Dev. 47:72–78, 1997. © 1997 Wiley-Liss, Inc.     

The effects of spermatozoal irradiation with X-rays on chromosome abnormalities and on development of mouse zygotes after delayed fertilization

The chromosome complements of zygotes derived from oocytes aged post ovulation and fertilized in vivo with X-ray-irradiated sperm were studied. Ovulation was induced by an injection of luteinizing hormone-releasing hormone (LHRH) at pro-estrus and fertilization was achieved by artificial insemination at 13 h and 24 h after LHRH in order to obtain embryos from unaged and aged (12 h post-ovulation) oocytes respectively. Post-ovulatory aging prior to fertilization did not significantly affect the percentage of zygotes with irradiation-induced chromosome abnormalities. However, post-ovulatory aging had a negative effect on the morphology of male as well as female pronuclear chromosomes of the first cleavage metaphase. When fertilized with control spermatozoa this effect was apparent in both the male and the female pronucleus. When unaged oocytes were fertilized with X-irradiated spermatozoa chromosome morphology was also adversely affected in both pronuclei. In zygotes from aged oocytes, there was an extra negative effect of X-rays on the male pronuclear chromosomes only. After fertilization with X-irradiated sperm 27% of zygotes from aged oocytes were arrested at interphase compared to 7% from unaged oocytes. We suggest that post-ovulatory aging and X-rays affect the male and female pronuclear chromatin structure after fertilization. These chromatin alterations could interact with DNA lesions induced in the spermatozoa prior to fertilization, such that development to first cleavage can be blocked.     

Nuclear and Cytoplasmic Maturation of Bovine Oocytes Cultured with dbc AMP,FSH AND hCG

The present investigation was undertaken to study the effect of addition of dbc AMP on bovine oocyte maturation and fertilization in vitro. The bovine oocytes isolated from 2–8 mm follicles were cultured for 26 h in TCM-199. The maturation rate (71.4 %) did not significantly increase after supplementation of the culture medium with dbc AMP (86.3 %.) or FSH + hCG (86.3 %). The in vitro fertilization rate of oocytes based on sperm penetration and presence of sperm tail in the ooplasm increased significantly in the dbc AMP (34.7 %) and the dbc AMP + FSH + hCG (33.9 %) treated groups when compared with untreated controls (17.9 %). However, dbc AMP treated oocytes were not able to secure the formation of male pronucleus 20 h after in vitro fertilization, while in oocytes matured in dbc AMP free medium both pronuclei were present in approximately 15 % of the penetrated oocytes. Also, the sperm head decondensation was blocked or slowed down by the dbc AMP treatment. It is concluded (1) that dbc AMP may improve the condition for the interaction of oocytes with spermatozoa, and (2) that the ooplasm of such dbc AMP treated oocytes apparently is not able to decandense the sperm head and transform it to the male pronucleus.     

Configuration of maternal and paternal chromatin and pertaining microtubules in human oocytes failing to fertilize after intracytoplasmic sperm injection

The microtubules and chromosomes of 180 human oocytes failing to fertilize after intracytoplasmic sperm injection were observed in order to establish how sperm chromatin and sperm astral microtubule configuration is related to the phases of oocyte cell cycle, and to find the defects in those structures causing fertilization arrest. As many as 125 (69%) oocytes were arrested at metaphase II. In one-fourth of them, damages of the second meiotic spindle were noted. In their cytoplasm intact sperm were found in 38 (30%) cases, a swollen sperm head in 36 (29%) and prematurely condensed sperm chromosomes (G1-PCC)-a result of active mitosis promoting factor (MPF)-in 51 (41%) cases. G1-PCC were mostly (73%) surrounded by the bipolar paternal spindle instead of astral microtubules. A male pronucleus was never presented in metaphase II oocytes. In 19 (11%) oocytes, arrested at anaphase II, no intact sperm were found. As many as 9 (47%) oocytes contained sperm in G1-PCC form, which proves that anaphase II oocytes mostly retain active MPF, despite oocyte activation. As many as 78% of 36 monopronucleate oocytes contained sperm, with delay in the process of sperm nucleus decondensation. Sperm in G1-PCC form and a bipolar paternal spindle were never found in monopronucleate oocytes. From this we conclude that sperm that does not activate the oocyte may continue decondensing the chromatin, but the oocyte prevents male pronucleus formation before the female one, mostly by causing PCC in the sperm and by duplicating the sperm centrosome. Mol. Reprod. Dev. 55:197-204, 2000.