Relationships between DNA synthesis and mitotic events in fertilized sea urchin eggs: aphidicolin inhibits DNA synthesis, nuclear breakdown and proliferation of microtubule organizing centers, but not cycles of microtubule assembly

The synthesis of DNA in fertilized eggs of the American Gulf Coast sea urchin Lytechinus variegatus is 90% inhibited in the presence of 5.0 micrograms/ml aphidicolin. This inhibition may be imposed immediately upon addition of aphidicolin to the external medium when embryos are in "S" phase. Observations of living embryos with Nomarski optics and time-lapse video microscopy reveal that when eggs are fertilized and cultured in the continuous presence of aphidicolin, nuclear envelope breakdown, chromosome condensation, and cytokinesis are inhibited. All other post-fertilization events observable with this technique, including the assembly and disassembly of a bipolar spindle, proceed in the presence of aphidicolin. Antitubulin immunofluorescence microscopy of aphidicolin-arrested embryos demonstrates that microtubules attempt to assemble a mitotic apparatus at the first cell cycle; the arrested intact zygote nucleus is embedded within this bipolar structure. Subsequent cycles of microtubule assembly and disassembly proceed roughly on schedule with later division cycles, but the microtubule organizing centers (MTOC's) are unable to duplicate properly and irregular monasters are observed. If aphidicolin is added to embryos after the first DNA synthetic period, nuclear envelope breakdown, chromosome condensation, and cytokinesis proceed for that cycle and the embryos arrest at the two-cell stage. These results suggest that the direct inhibitory effects of aphidicolin may well be limited to the synthesis of DNA, which itself regulates nuclear cycles independently from the subsequent generation of mitotic poles, and that cytoplasmic clocks regulate microtubule assembly cycles but not the configuration of microtubule arrays.     

Presence of a nucleus or nucleus-deriving factors is indispensable for the formation of the spindle, the diastema and the cleavage furrow in the blastomere of the Xenopus embryo

The present study examines the indispensability of a nucleus or nucleus-deriving factors in the induction of cleavage in Xenopus eggs by testing cleavage in Xenopus eggs fertilized with ultraviolet (UV)-damaged sperm and deprived of the female nucleus. These eggs, which contain only one UV-damaged nucleus with one set of centrioles, undergo unique cleavages. Cleavage takes place in only one of the two blastomeres formed by the immediately preceding cleavage. Histologically, only one nucleus, which does not appear to be organized into typical chromosomes, is found in one of the two blastomeres formed by the immediately preceding cleavage. The typical bipolar spindle and the diastema, or a slit of astral rays, are formed in the blastomere that contains the nucleus. By contrast, only asters lacking the spindle and the diastema are formed in the remaining blastomeres, which do not contain a nucleus. The same results are obtained in eggs that contain two UV-damaged nuclei with one set of centrioles. In these eggs, cleavage appears to occur in one or two blastomeres that contain either or both of the nuclei and one bipolar spindle. In eggs that contain one intact and one UV-damaged nuclei, cleavage takes place quite normally with each blastomere containing one nucleus or one set of chromosomes as well as one bipolar spindle. Thus, there is a very close correlation between the presence of a nucleus and the formation of the mitotic spindle, the diastema and the cleavage furrow in the blastomeres of Xenopus embryos. We conclude that the presence of a nucleus or nucleus-deriving factors is indispensable for the formation of the bipolar spindle, the diastema and the cleavage furrow in the blastomeres of the Xenopus embryos.     

Experiments Pertaining to the Suppression of Accessory Sperm in Fertilized Newt Eggs*

In the physiologically polyspermic eggs of the newt, Cynops pyrrhogaster, a number of accessory sperm undergo pronuclear formation along with a concomitant DNA synthesis, but degenerate after zygote nucleus formation. When denuded eggs were divided into two halves at various post-fertilization stages, the andromerogons produced before zygote nucleus formation but not after that stage cleaved at a high frequency. The accessory sperm were unable to participate in the cleavage when they were located in the half of the egg which was connected with the diploid merogon by a cytoplasmic bridge higher than 100 μm in height. The removal of the egg nucleus or the retardation of early post-fertilization nuclear events by treatment with cycloheximide resulted in the induction of multipolar cleavage. Continuous exposure of the fertilized eggs to aphidicolin showed that in the appreciable absence of the DNA synthesis many eggs underwent a first cleavage cytokinesis of a mostly abortive type, but failed to initiate the following cytokinesis at all. Cytological examinations in association with these experiments suggest that the observed suppression of accessory sperm includes the inhibition of centriolar replication under the influence of the zygote nucleus, resulting in the failure of cytasters corporating with nuclear-independent activity of cortical cytoplasm.     

Effects of aphidicolin on premature condensation of sperm chromosomes in fertilized sea urchin eggs

Unfertilized Strongylocentrotus purpuratus eggs may be treated with ammonia to initiate maternal DNA replication and the maternal cell cycle. When these eggs are polyspermically fertilized 75 min after the beginning of ammonia treatment, the nuclei of the fertilizing spermatozoa undergo premature chromosome condensation (PCC) in an apparent attempt to conform to the advanced maternal cell cycle. PCC is inhibited if maternal DNA replication is blocked by exposing the eggs to aphidicolin but will proceed if this exposure begins after replication is complete. Additionally, PCC will proceed in ammonia-activated, polyspermically fertilized anucleate merogons in the continuous presence of aphidicolin. These results suggest that the direct inhibitory effect of aphidicolin may well be limited to the replication of DNA and that the unreplicated maternal nucleus itself exerts negative control over the development of chromosome-condensing conditions in the maternal cytoplasm.     

Studies on differentiation without cleavage in Chaetopterus: effects of inhibition of DNA synthesis with aphidicolin

The effects of aphidicolin - a powerful inhibitor of DNA polymerase alpha and of DNA replication - on normal development and on differentiation without cleavage of Chaetopterus eggs have been studied with cytological, cytochemical, and biochemical methods. The experiments show that the initial period of pseudocleavage can take place in the absence of nuclear DNA synthesis, but further development (segregation, hatching, ciliation) requires DNA synthesis. However ciliated unicellular larvae can be obtained under conditions where the DNA content of the embryos in only 40% of the controls. In fertilized eggs, aphidicolin immediately stops cleavage. The significance of these results is discussed.     

Increased uptake of thymidine in the activation of sea urchin eggs. III. Effects of aphidicolin

Uptake and phosphorylation of externally supplied [3H]-thymidine are fully stimulated in fertilized sea urchin eggs exposed to 5.0 micrograms/ml aphidicolin. As in untreated controls, the rate of uptake in aphidicolin-treated eggs increases greater than 50-fold shortly after fertilization, and greater than 85% of the transported thymidine is immediately phosphorylated to the triphosphate. The intracellular levels of [3H]-thymidine triphosphate (3H-dTTP) resulting from an external supply of [3H]-thymidine is therefore equal in aphidicolin-treated and untreated fertilized eggs. Under the same experimental conditions, the incorporation of externally supplied [3H]-thymidine into newly synthesized DNA of fertilized eggs is 90% inhibited by exposure to aphidicolin. The full availability of 3H-dTTP in these eggs further suggests that aphidicolin inhibits specifically at the level of DNA synthesis. This inhibitory effect is proportional to the concentration of aphidicolin between 0 and 5.0 micrograms/ml. In the continuous presence of 5.0 micrograms/ml aphidicolin, fertilized eggs fail to undergo mitotic chromosome condensation, nuclear envelope breakdown, and cytokinesis, suggesting a dependent link between these processes and the completion of nuclear DNA synthesis.     

Studies on fertilization in the teleost IV. Effects of aphidicolin and camptothecin on chromosome formation in fertilized medaka eggs

To clarify the mechanisms of fish fertilization, the effects of inhibitors of DNA polymerase-alpha and DNA topoisomerases on nuclear behavior before and after fertilization were examined in eggs of the medaka, Oryzias latipes. Eggs underwent the fertilization process from sperm penetration to karyogamy of pronuclei, even when inseminated and incubated in the continuous presence of aphidicolin (DNA polymerase alpha inhibitor), camptothecin (DNA topoisomerase I inhibitor), etoposide, or beta-lapachone (DNA topoisomerase II inhibitor). However, continuous treatment with aphidicolin or camptothecin during fertilization inhibited the formation of sister chromosomes that were normally separated into blastomeres at the time of the subsequent cleavage. Sister chromosome formation appeared concomitantly with an increase in histone H1 kinase activity at the end of DNA synthesis, 30 min post insemination. However, non-activated eggs that were inseminated in saline containing anesthetic MS222 and aphidicolin had high levels of histone H1 kinase and MAP kinase activities, and transformation of the penetrated sperm nucleus to metaphase chromosomes occurred even in the presence of aphidicolin or camptothecin. The male chromosomes were normally separated into two anaphase chromosome masses upon egg activation. These results suggest that DNA polymerase alpha or DNA topoisomerase I, but not DNA topoisomerase II, may be required for the process by which the mitotic interphase nucleus transforms to separable metaphase chromosomes while the activity of MAP kinase is low, unlike the situation in meiotic division, during which MAP kinase activity is high and DNA replication is not required.     

Changes in microtubule structures during the first cell cycle of physiologically polyspermic newt eggs

The unfertilized egg of the newt, Cynops pyrrhogaster, has a second meiotic spindle at the animal pole and numerous cortical cytasters. After physiologically polyspermic fertilization, all sperm nuclei incorporated into the egg develop sperm asters, and the cortical cytasters change into bundles of cortical microtubules. The size of the sperm asters in the animal hemisphere is ∼5.6-fold larger than that in the vegetal hemisphere. Only one sperm nucleus moves toward the center of the animal hemisphere to form a zygote nucleus with the egg nucleus. This movement is inhibited by nocodazole, but not by cytochalasin B. The centrosome in the zygote nucleus divides into two parts to form a bipolar spindle for the first cleavage synchronously with the nuclear cycle, but centrosomes of accessory sperm nuclei in the vegetal hemisphere remained to form monopolar interphase asters and subsequently degenerate around the first cleavage stage. The size of sperm asters in monospermically fertilized Xenopus eggs was ∼37-fold larger than those in Cynops eggs. Since sperm asters that formed in polyspermically fertilized Xenopus eggs exclude each other, the formation of a zygote nucleus is inhibited. Cynops sperm nuclei form larger asters in Xenopus eggs, whereas Xenopus sperm nuclei form smaller asters in Cynops eggs compared with those in homologous eggs. Since there was no significant difference in the concentration of monomeric tubulin between those eggs, the size of sperm asters is probably regulated by a component(s) in egg cytoplasm. Smaller asters in physiologically polyspermic newt eggs might be useful for selecting only one sperm nucleus to move toward the egg nucleus. Mol. Reprod. Dev. 47:210–221, 1997. © 1997 Wiley-Liss, Inc.     

Hypotonic buffer induces meiosis and formation of anucleate cytoplasmic islands in the egg of the two-spotted cricket Gryllus bimaculatus

In insects, egg activation is known to occur in vivo and independently of fertilization, but its mechanisms are poorly understood. To gain understanding of these mechanisms, an attempt was made to activate the egg of Gryllus bimaculatus in vitro. It was found that meiosis resumed and was completed in unfertilized eggs treated with hypotonic buffer. Early developmental processes in activated, unfertilized eggs were investigated and compared with those in fertilized eggs. Mitosis did not progress, resulting in formation of anucleate cytoplasmic islands (pseudoenergids). Development in the activated, unfertilized eggs stopped at this stage and both yolk subdivision and cellularization did not occur. To elucidate the role of the nucleus in the developmental process to the syncytial stage in fertilized eggs, eggs were treated with aphidicolin to inhibit DNA polymerization. It was found that pseudoenergids also formed in these aphidicolin-treated fertilized eggs. These results demonstrate that pseudoenergids can increase in number independently of nuclei, suggesting that the cytoplasm rather than the nucleus plays the primary role in development to the syncytial stage in G. bimaculatus.     

Relationship between nuclear DNA synthesis and centrosome reproduction in sea urchin eggs

The importance of nuclear DNA synthesis for the doubling, or reproduction, of centrosomes in cells that are not growth-limited, such as sea urchin eggs, has not been clearly defined. Studies of enucleated, fertilized eggs show that nuclear activities are not required at each cell cycle for the normal reproduction of the complete centrosome. However, other studies report that the inhibition of nuclear DNA synthesis in intact eggs by the drug aphidicolin prevents centrosome reproduction and entry into mitosis as seen by nuclear envelope breakdown. To resolve this paradox, we systematically characterized the effect of aphidicolin on cell division in eggs from three species of sea urchins. Eggs were continuously treated with 5 or 10 micrograms/ml aphidicolin starting 5 min after fertilization. This blocked total incorporation of 3H-thymidine into DNA by at least 90%, as previously reported. We found that the sperm aster always doubles prior to first mitosis. Over a period of several hours, the centrosomes reproduce in the normal 2-4-8-16 fashion, with a period that is longer and more variable than normal. In every culture, a variable percentage of the eggs undergoes nuclear envelope breakdown. Once broken down, the nuclear envelope never visibly reforms even though centrosomes continue to double. Fluorescent labeling of DNA revealed that the chromatin does not condense into discrete chromosomes. Whether or not the nuclear envelope breaks down, the chromatin appears as an amorphous mass of fibers stretched between first two and then four asters. Later, the nuclear envelope/chromatin loses its association with some or all centrosomes. Our results were the same for all eggs at both drug concentrations. Thus, nuclear DNA synthesis is not required for centrosome reproduction in sea urchin eggs.     

Studies on Differentiation without Cleavage in Chaetopterus: Effects of Inhibition of DNA Synthesis with Aphidicolin

The effects of aphidicolin – a powerful inhibitor of DNA polymerase α and of DNA replication – on normal development and on differentiation without cleavage of Chaetopterus eggs have been studied with cytological, cytochemical, and biochemical methods. The experiments show that the initial period of pseudocleavage can take place in the absence of nuclear DNA synthesis, but further development (segregation, hatching, ciliation) requires DNA synthesis. However ciliated unicellular larvae can be obtained under conditions where the DNA content of the embryos in only 40% of the controls. In fertilized eggs, aphidicolin immediately stops cleavage. The significance of these results is discussed.     

Regulation of stage-specific gene expression during early mouse development: effect of cytochalasin B and aphidicolin on stage-specific protein synthesis in mouse eggs

Mechanisms regulating stage-specific translation in mouse embryos were studied by inhibitor experiments. When fertilized eggs were continuously treated with cytochalasin B, cleavage was prevented, whereas karyokinesis proceeded, resulting in protein synthesis patterns changing stage-specifically as in control embryos through preimplantation development. When fertilized eggs were continuously exposed to aphidicolin, cleavage and DNA synthesis were inhibited, thus keeping their protein synthesis at the level of fertilized eggs with few new polypeptides appearing after one day. The next day these eggs stopped translation almost completely. Stage-specific translation therefore might be controlled by nuclear replications rather than by cytoplasmic clock.     

Induction of achromosomal cleavage by hydroxyurea in starfish embryo and the reversal by a combination of deoxyadenosine and deoxycytidine: possible involvement of salvage pathway for deoxynucleoside triphosphate biosynthesis in the presence of hydroxyurea

Effects of hydroxyurea, an inhibitor of ribonucleotide reductase, on cleavage of starfish embryos were studied. In the presence of 1 mM hydroxyurea, fertilized eggs of the starfish, Asterina pectinifera, cleaved up to the 256-cell stage and decomposed before blastulation. Before the 16-cell stage, each blastomere contained a normal nucleus or chromosomes with mitotic apparatus. The cleavage after the 16-cell stage was slow compared to the control embryos, and not all blastomeres contained a nucleus or normal chromosomes. During the fifth cell division (between 16-cell- and 32-cell-stage embryos), chromatin mass unassociated with the mitotic apparatus remained near the cleavage furrow. When hydroxyurea was removed before the 16-cell stage, the embryos developed to normal bipinnalia larvae via normal blastulae. However, the embryos were disintegrated before blastulation when hydroxyurea was removed after the 32-cell stage. DNA synthesis was normally observed before the 16-cell stage but not after the 16-cell stage, but dNTP contents in the embryos remained low throughout development in the presence of hydroxyurea. The achromosomal cleavage observed in the presence of hydroxyurea was reversed by the combination of extracellular dAR and dCR. Therefore, it is assumed that the synthesis of dNTPs required for DNA synthesis in the presence of hydroxyurea occurs via the salvage pathway using deoxynucleosides (dNR) (dNR to dNTP via dNMP and dNDP).     

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 components are not required for the cell-cycle oscillator of the early starfish embryo

We show that certain events of the cell cycle can still occur in starfish oocytes or fertilized eggs from which the germinal vesicle (the prominent nucleus of prophase-arrested oocytes) has been removed before the induction of meiotic maturation. Two meiotic asters develop following hormonal induction of meiotic maturation in these enucleated oocytes. The asters then divide to form a transient tetrapolar figure. When enucleated oocytes are fertilized, the sperm centrosome duplicates at the times corresponding to each cleavage in control nucleated embryos. Periodic changes in the organization of the asters and in the morphology of the cell surface also occur in synchrony with controls. Decondensation of the sperm nucleus, spindle formation, and cleavage do not occur when enucleated oocytes are fertilized. Ultimately the number of asters increases to approximately 520 (about 2(9] before the pseudo-embryo arrests and cytolyzes. Fertilized eggs from which both pronuclei but not the sperm aster have been removed undergo nine cleavages and then cease cell division. The cessation of division may be related to the events that cause the midblastula transition after seven cleavages in normal nucleated embryos.     

Inhibition of cysteine protease activity disturbs DNA replication and prevents mitosis in the early mitotic cell cycles of sea urchin embryos

Recent findings suggested that the role of cysteine proteases would not be limited to protein degradation in lysosomes but would also play regulatory functions in more specific cell mechanisms. We analyzed here the role of these enzymes in the control of cell cycle during embryogenesis. The addition of the potent cysteine protease inhibitor E64d to newly fertilized sea urchin eggs disrupted cell cycle progression, affecting nuclear as well as cytoplasmic characteristic events. Monitoring BrdU incorporation in E64d treated eggs demonstrated that DNA replication is severely disturbed. Moreover, this drug treatment inhibited male histones degradation, a step that is necessary for sperm chromatin remodeling and precedes the initiation of DNA replication in control eggs. This inhibition likely explains the DNA replication disturbance and suggests that S phase initiation requires cysteine protease activity. In turn, activation of the DNA replication checkpoint could be responsible for the consecutive block of nuclear envelope breakdown (NEB). However, in sea urchin early embryos this checkpoint doesn't control the mitotic cytoplasmic events that are not tightly coupled with NEB. Thus the fact that microtubule spindle is not assembled and cyclin B-cdk1 not activated under E64d treatment more likely rely on a distinct mechanism. Immunofluorescence experiments indicated that centrosome organization was deficient in absence of cysteine protease activity. This potentially accounts for mitotic spindle disruption and for cyclin B mis-localization in E64d treated eggs. We conclude that cysteine proteases are essential to trigger S phase and to promote M phase entry in newly fertilized sea urchin eggs.     

Paternal chromosome incorporation into the zygote nucleus is controlled by maternal haploid in Drosophila

maternal haploid (mh) is a strict maternal effect mutation that causes the production of haploid gynogenetic embryos (eggs are fertilized but only maternal chromosomes participate in development). We conducted a cytological analysis of fertilization and early development in mh eggs to elucidate the mechanism of paternal chromosome elimination. In mh eggs, as in wild-type eggs, male and female pronuclei migrate and appose, the first mitotic spindle forms, and both parental sets of chromosomes congress on the metaphase plate. In contrast to control eggs, mh paternal sister chromatids fail to separate in anaphase of the first division. As a consequence the paternal chromatin stretches and forms a bridge in telophase. During the first three embryonic divisions, damaged paternal chromosomes are progressively eliminated from the spindles that organize around maternal chromosomes. A majority of mh embryos do not survive the deleterious presence of aneuploid nuclei and rapidly arrest their development. The rest of mh embryos develop as haploid gynogenetic embryos and die before hatching. The mh phenotype is highly reminiscent of the early developmental defects observed in eggs fertilized by ms(3)K81 mutant males and in eggs produced in incompatible crosses of Drosophila harboring the endosymbiont bacteria Wolbachia.     

Timing system for the start of gastrulation in the Xenopus embryo

This study examined which component of the egg, the nucleus or cytoplasm, is involved in the timing of the start of gastrulation in the Xenopus embryo, and when it starts to measure time. First, nuclei of cells of 256-cell stage embryos were transplanted to enucleated eggs 60 min after activation. These eggs showed first cleavage 20-30 min later than control eggs fertilized at the same time as the activation of recipient eggs, and started gastrulation 25-35 min later than control embryos (depending on the delay in the first cleavage). Second, eggs whose nuclei were temporarily isolated by the extrusion of the portion containing the nucleus out of the fertilization envelope showed first cleavage 60-90 min later than sibling control eggs, because of delayed introduction of the nucleus from the extruded portion. They started gastrulation 60-90 min later than sibling control embryos (depending on the delay in the first cleavage). The portion inside the envelope underwent two to three rounds of oscillation in cell cycle relevant activities before the first cleavage, while the portion outside underwent the same rounds of cleavage as the inside portion. From the present and previous results it is concluded that the putative timing system for the start of gastrulation in the Xenopus embryo, whether it consists of a single or of multiple clocks, starts measuring time at or around the first cleavage, and that the presence of both the nucleus and the cytoplasm in the same cell and occurrence of mitosis and/or cleavage there are indispensable for the timing system to work, although the role of the cytoplasm is superior to that of the nucleus.     

Specific inhibitors of eukaryotic DNA synthesis and DNA polymerase alpha, 3-deoxyaphidicolin and aphidicolin-17-monoacetate

Of several phytotoxins isolated from culture filtrates of Phoma betae Frank PS-13, an incitant of leaf spot disease of sugar beet, three have been identified as aphidicolin, 3-deoxyaphidicolin and aphidicolin-17-monoacetate. Aphidicolin is a selective inhibitor of eukaryotic DNA polymerase alpha (Ikegami et al. (1978) Nature 275, 458-460). Consequently, we studied the action mechanism of 3-deoxyaphidicolin and aphidicolin-17-monoacetate. These aphidicolin analogues markedly inhibited the in vivo DNA synthesis of sea urchin embryos and HeLa cells but not RNA and protein syntheses. Only DNA polymerase alpha, not DNA polymerase beta and gamma, was inhibited by these drugs. The mode of action of these analogues on DNA polymerase alpha from the sea urchin was competitive inhibition with respect to dCTP with Ki values of 0.44 micrograms/ml for deoxyaphidicolin and 0.89 micrograms/ml for aphidicolin monoacetate, respectively. None of the other three dNTPs competed with these drugs. A similar inhibitory mode was observed using the enzyme from HeLa cells and toad oocytes. These drugs at a concentration of 2 micrograms/ml caused a delay in the cleavage of fertilized eggs of the sea urchin and decomposition before blastulation, indicating the possibility of achromosomal cleavage because of the absence of DNA synthesis. Based on the above, it is concluded that these analogues can be used as other inhibitors of eukaryotic DNA synthesis and DNA polymerase alpha.     

UV irradiation of pig metaphase chromosomes: maturation-promoting factor degradation, nuclear cytology and cell cycle progression

Experiments were designed to test two hypotheses. The first was that irradiation of pig metaphase chromosomes would block the normal sequence of cytological and molecular events associated with activation; the second postulated that damaged DNA would prevent eggs from progressing through the first mitotic cleavage cycle. The experimental protocol involved selectively irradiating the metaphase II plate of pig oocytes with highly focused 254 nm ultraviolet (UV) light, followed by activation using standard electroactivation procedures. The following assessments were made of different groups of eggs: (i) nuclear membrane reassembly; (ii) chromosomal cytology; (iii) changes in maturation-promoting factor kinase (MPF kinase) activity at 1 h intervals after activation; and (iv) mitotic progression of eggs containing damaged chromosomal fragments. UV irradiation neither prevented the reassembly of nuclear membranes required for pronuclear formation nor interfered with the normal pattern of MPF kinase degradation after egg activation. UV irradiation did induce a wide range of chromatin defects, including condensation and dispersal of DNA fragments which, in turn, resulted in the formation of micronuclei in the treated eggs and embryos. The presence of damaged DNA retarded, but did not inhibit, progression through the first mitotic cycle. No evidence was obtained that the subsequent mitotic cycle was adversely affected by the presence of UV-damaged DNA. Overall, these results indicate that early cleavage divisions in pig eggs are not blocked by the presence of damaged, hypercondensed chromatin. In this respect, pig eggs are similar to Xenopus eggs, but are different from bovine eggs. On the basis of these findings it is suggested that focused UV irradiation offers a simple and rapid technique for the non-invasive enucleation of pig oocytes provided that the residual hypercondensed chromatin does not affect later developmental stages.