Transformation of sperm nuclei into male pronuclei in nucleate and anucleate fragments of parthenogenetic mouse eggs

Our objective was to examine the ability of nucleate and anucleate fragments of artificially activated mouse eggs to transform sperm nucleus into male pronucleus. To this end, zona-free oocytes in metaphase II were activated by ethanol and bisected into halves (one with the spindle, the other anucleate) either within 10 to 20 min (series A) or 3 or 5 hr later (series B). In series A, the fragments were inseminated 3,5, and 8 h after activation, and in series B. 3 and 5 h after activation. Both nucleate and anucleate fragments lose the capability of transforming sperm nucleus into fully formed pronucleus sometime between 3 and 5 h after activation. In 8 h old parthenogenetic fragments, the majority of sperm nuclei remain unchanged or begin decondensation but never reach the stage of an early pronucleus. In over 1/3 of anucleate fragments of this age group, sperm nuclei develop defectively: chromatin decondenses inside the persisting nuclear envelope. In other experimental groups, the incidence of these abnormal sperm nuclei varies between 0 and 10%. In general, the anuclcate fragments retain the capability to transform sperm nuclei (fully or partially) longer than their nuclear counterparts. This difference may be accounted for by a different level of substances required for pronuclcar growth (extrachromosomal constituents of the germinal vesicle and nuclear lamins): high and constant in the cytoplasm of anucleate egg halves and low and progressively decreasing in the nucleate halves because of their putative uptake by the female pronucleus. However, the cytoplasmic factors responsible for the initial stages of transformation (nuclear envelope breakdown, chromatin decondensation) become eventually inactivated both in the presence and in the absence of a female pronucleus.     

Electron microscopic observations on sperm entry and pronuclear formation in naked eggs of the rose bitterling in polyspermic fertilization

Unfertilized eggs of the rose bitterling (Rhodeus ocellatus ocellatus) were squeezed out of females that had an elongated ovipositor and were dechorionated mechanically with fine forceps in physiological saline. The dechorionated eggs were transferred into fresh water then inseminated at once by spermatozoa of the same species. A large number of spermatozoa was found on the surface of eggs that had not yet had cortical reaction following insemination. The surface of the naked eggs responded by formation of many small cytoplasmic protrusions (viz., fertilization cones) at sperm attachment sites. The formed fertilization cones were rosettelike structures formed by the aggregation of some bleblike swellings devoid of microvilli and microplicae. About 10 min after insemination, the fertilization cones retracted, but marks of their presence characterized by less microvilli and microplicae remained in the eggs 15 min after insemination. Many spermatozoa penetrated into the cytoplasm of each naked egg. The sperm nuclear envelope disappeared by means of vesiculation resulting from fusion of the inner and outer membranes. The sperm nucleus decondensed and developed into a larger male pronucleus. Smooth-surfaced vesicles surrounded the decondensing sperm nucleus and formed the new male pronuclear envelope. Sperm mitochondria and flagella were found in the egg 15 min after insemination. The response of the egg surface to sperm entry and pronucleus formation are discussed.     

Mitochondrial regulation in sea urchins. III. Rapid degradation of mitochondrial RNA in association with a failure to form mitochondrial polyribosomes in eggs activated with ionophore A 23187.

Most of the biochemical changes which have been examined in eggs of sea urchins, following activation with ionophore A-23187, parallel those events which have been observed to occur after fertilization. However, the results reported here indicate that mitochondrial polyribosomes fail to form after ionophore activation of either nucleate or anucleate fragments of eggs of the sea urchin. The results also demonstrate that ionophore activation does not impair the ability of eggs to generate ATP within the subsequent 2.5 h and thus the absence of mitochondrial protein synthesis appears not to be responsible for the failure of ionophore activated eggs to divide. Studies of the rates of uptake and incorporation of [³H]uridine into nucleic acid within ionophore activated anucleate fragments suggest that the rates of synthesis and degradation for both messenger and ribosomal “like” RNAs reach equilibrium within 5 min after the addition of isotope to the cultures, demonstrating that the half-lives of newly synthesized mitochondrial RNAs may be relatively brief in the absence of polyribosome formation. These results support and extend the conclusion of Lambowitz et al. [42] which suggests that ribosomal proteins may be important for stabilization of at least one of the mitochondrial ribosomal RNAs.     

Ca2+ oscillation-inducing phospholipase C zeta expressed in mouse eggs is accumulated to the pronucleus during egg activation

Sperm-specific phospholipase C zeta (PLC zeta) is known to induce intracellular Ca(2+) oscillations and egg activation when expressed in mouse eggs by injection of RNA encoding PLC zeta. We investigated the expression level and spatial distribution of PLC zeta in the egg in real time and in relation to the initiation and termination of Ca(2+) oscillations by monitoring fluorescence of a yellow fluorescent protein 'Venus' fused with PLC zeta. Ca(2+) oscillations similar to those at fertilization were induced at 40-50 min after RNA injection, when expressed PLC zeta reached 10-40 x 10(-15) g in the egg. PLC zeta-Venus increased up to 3 h and attained a steady level at 4-5 h. Interestingly, PLC zeta-Venus is accumulated to the pronucleus (PN) formed at 5-6 h and continuously increased there. Ca(2+) oscillations stopped in most eggs before initiation of the accumulation. A variant of PLC zeta that lacks three EF hand domains was much less effective in induction of Ca(2+) oscillations and little accumulated in the pronucleus, indicating a critical role of those domains. The ability of the accumulation to the pronucleus qualifies PLC zeta for a strong candidate of the Ca(2+) oscillation-inducing sperm factor, which is introduced into the ooplasm upon sperm-egg fusion and concentrated to the pronucleus after inducing egg activation.     

Cytological changes and DNA and protein synthesis in parthenogenetically activated sea urchin eggs

Summary The present study deals with cytological observations, DNA and protein synthesis in artificially activated sea urchin eggs. The eggs were activated by means of Loeb's double treatment with butyric acid and hypertonic sea water. Most of the eggs ofHemicentrotus pulcherrimus divided when the chromosomes duplicated after formation of the first monaster and other eggs divided at a later cell cycle. In the eggs ofTemnopleurus toreumaticus, however, haploid division at the first cell cycle was observed predominantly.Activated eggs that were treated for 25 min with hypertonic sea water showed a marked uptake of³H-thymidine during the two periods of 30–40 min and 90–100 min after the double treatment. These periodic changes in the³H-thymidine uptake paralleled morphological changes within the nucleus. However, these periods of increased uptake were not observed in the eggs treated with hypertonic sea water for 60 min. During exposure to hypertonic sea water, the³H-thymidine-uptake by eggs activated with butyric acid decreased gradually. When the uptake of¹⁴C-valine by eggs was measured, a very low level was seen in unfertilized eggs. The level of uptake increased strikingly when the eggs were activated with butyric acid but was suppressed by the hypertonic treatment. However, removal of the eggs to sea water allowed the uptake to return to the former high level. This pattern suggests that the hypertonic treatment has an inhibitory effect on the synthesis of protein (or enzymes) which obstruct cleavage induction.     

Delayed sperm injection and fertilization in parthenogenetically activated insect egg (Athalia rosae,Hymenoptera)

Summary Mature eggs dissected from the ovary of unmated females of Athalia rosae ruficornis Jakovlev (Hymenoptera, Tenthredinidae) can be activated to develop (into haploid parthenogenetic males) simply by exposing them to distilled water. These eggs, which are primary oocytes arrested at the first meiotic metaphase, resume meiosis upon activation and reach the first meiotic telophase in 20 min. Mature eggs immediately upon dissection have previously been shown to complete karyogamy and develop as fertilized diploid females if injected with sperm. We show here that the eggs activated in water for 20 min have a much higher rate of successful fertilization if injected with sperm, and that the eggs activated for 40 min, upon sperm injection, though at a reduced frequency still develop as diploid fertilized females. Eggs left in water for 60 min, however, are no longer fertilized upon sperm injection and develop as haploid males.     

Cytological effects of urethan on cleavage induction in parthenogenetically activated sea urchin eggs

The effect of urethan on artificial induction of cleavage in eggs of the sea urchin, Hemicentrotus pulcherrimus, was studied. When the eggs were exposed for 20 minutes to seawater containing urethan (final concentration, 0.08 M) after butyric acid-activation and then treated with hypertonic seawater, the cleavage rate was enchanced by about 1.5 times as compared with the nontreated eggs. In the eggs exposed to urethan–seawater for over 70 minutes many clear spots appeared throughout the cytoplasm. Simultaneously, the pigment granules, which had been embedded within the cortex, migrated to the inner cytoplasm and encircled a monastral centrosphere and clear spots. The clear spots were composed of microtubules much like cytasters, and in the central region of them centrioles were not yet found. The eggs in which the pigment granules disappeared from the cortex may be more susceptible to cleavage induction by succeeding hypertonic treatment.     

Fertilization of eggs of zebrafish, Danio rerio, by intracytoplasmic sperm injection

To evaluate the potential for fertilization by sperm injection into fish eggs, sperm from zebrafish, Danio rerio, were microinjected directly into egg cytoplasm of two different zebrafish lines. To evaluate physiological changes of gametes on the possible performance of intracytoplasmic sperm injection (ICSI), four different combinations of injection conditions were conducted using activated or nonactivated gametes. From a total of 188 zebrafish eggs injected with sperm in all treatments, 31 (16%) developed to blastula, 28 (15%) developed to gastrula, 10 (5%) developed abnormally to larval stages, and another 3 (2%) developed normally and hatched. The highest fertilization rate (blastodisc formation) was achieved by injection of activated spermatozoa into nonactivated eggs (35%). Injections were most effective when performed within the first hour after egg collection. Flow cytometric analysis of the DNA content of the developing ICSI embryos revealed diploidy, and the use of a dominant pigment marker confirmed paternal inheritance. Our study indicates that injection of a single sperm cell into the cytoplasm of zebrafish eggs allows fertilization and subsequent development of normal larvae to hatching and beyond.     

Patterns of microtubule polymerization relating to cortical rotation in Xenopus laevis eggs.

Following fertilization, the Xenopus egg cortex rotates relative to the cytoplasm by 30 degrees about a horizontal axis. The direction of rotation, and as a result the orientation of the embryonic body axes, is normally specified by the position of sperm entry. The mechanism of rotation appears to involve an array of aligned microtubules in the vegetal cortex (Elinson and Rowning, 1988, Devl Biol. 128, 185-197). We performed anti-tubulin immunofluorescence on sections to follow the formation of this array. Microtubules disappear rapidly from the egg following fertilization, and reappear first in the sperm aster. Surprisingly, astral microtubules then extend radially through both the animal and vegetal cytoplasm. The cortical array arises as they reach the vegetal cell surface. The eccentric position of the sperm aster gives asymmetry to the formation of the array and may explain its alignment since microtubules reaching the cortex tend to bend away from the sperm entry side. The radial polymerization of cytoplasmic microtubules is not dependent on the sperm aster or on the female pronucleus: similar but more symmetric patterns arise in artificially activated and enucleate eggs, slightly later than in fertilized eggs. These observations suggest that the cortical microtubule array forms as a result of asymmetric microtubule growth outward from cytoplasm to cortex and, since cortical and cytoplasmic microtubules remain connected throughout the period of the rotation, that the microtubules of the array rotate with the cytoplasm.     

Pronuclear synthesis of DNA in fertilized and parthenogenetically activated mouse eggs : A cytophotometric study

Mouse one-cell embryos were taken 1, 1.5, 2, 3, 4, 6, 8, 10, 13 and 18 h after insemination. One-cell parthenogenones were induced by treatment of mouse eggs obtained 20 h after HCG injection with hyaluronidase and cultured for 0.5, 1, 3, 4.5, 6, 8, 10, 12 and 24 h. Some parthenogenones were pulse-labelled with tritiated thymidine, cut and autoradiographed. Both the embryos and parthenogenones were Feulgen-stained, and integrated relative optical absorption of either pronuclei or nuclei of polar bodies was measured with a cytophotometer. In some fertilized eggs and parthenogenones the DNA synthesis sets in 4–6 h after either insemination or parthenogenetic stimulus. Between the 8th and 13th hour after insemination the fraction of DNA synthesizing embryonic pronuclei remained at the level 30–40%. Most parthenogenones duplicated their DNA content between the 8th and 12th hour after hyaluronidase treatment. The DNA synthesis time in pronuclei of embryos was determined to be 3.5–4.0 h and that of pronuclei of parthenogenones approx. 4 h. The minimal time of the G2 phase was estimated to be 3–5 h. The first labelled pronuclei of parthenogenones were detected 6 h after stimulus. Male pronuclei started and ended DNA synthesis earlier than female pronuclei. Differences in the DNA content between pronuclei of the parthenogenones (when there are two in one parthenogenone) were observed beginning with the 10th h after hyaluronidase treatment.The DNA content in the nuclei of the second polar bodies (PB) of embryos increased slowly between the 8th and 22nd hour after insemination, up to an overall value of 1.4 C. That of the nuclei of the polar bodies of parthenogenones accompanied the synthesis of DNA in pronuclei to the 10th hour after hyaluronidase treatment, up to an overall value of 1.4 C.     

Inhibition of MEK or cdc2 kinase parthenogenetically activates mouse eggs and yields the same phenotypes as Mos(-/-) parthenogenotes

Mammalian eggs are arrested in metaphase II of meiosis until fertilization. Arrest is maintained by cytostatic factor (CSF) activity, which is dependent on the MOS-MEK-MAPK pathway. Inhibition of MEK1/2 with a specific inhibitor, U0126, parthenogenetically activated mouse eggs, producing phenotypes similar to Mos(-/-) parthenogenotes (premature, unequal cleavages and large polar bodies). U0126 inactivated MAPK in eggs within 1 h, in contrast to the 5 h required after fertilization, while the time course of MPF inactivation was similar in U0126-activated and fertilized eggs. We also found that inactivation of MPF by the cdc2 kinase inhibitor roscovitine induced parthenogenetic activation. Inactivation of MPF by roscovitine resulted in the subsequent inactivation of MAPK with a time course similar to that following fertilization. Notably, roscovitine also produced some Mos(-/-)-like phenotypes, indistinguishable from U0126 parthenogenotes. Simultaneous inhibition of both MPF and MAPK in eggs treated with roscovitine and U0126 produced a very high proportion of eggs with the more severe phenotype. These findings confirm that MEK is a required component of CSF in mammalian eggs and imply that the sequential inactivation of MPF followed by MAPK inactivation is required for normal spindle function and polar body emission.     

Sperm aster formation and pronuclear decondensation during rabbit fertilization and development of a functional assay for human sperm

Microtubule organization and chromatin configurations in rabbit eggs after in vivo rabbit fertilization and after intracytoplasmic injection with human sperm were characterized. In unfertilized eggs, an anastral barrel-shaped meiotic spindle, oriented radially to the cortex, was observed. After rabbit sperm incorporation, microtubules were organized into a radial aster from the sperm head, and cytoplasmic microtubules were organized around the male and female pronuclei. The microtubules extending from the decondensed sperm head participated in pronuclear migration, and organization around the female pronucleus may also be important for pronuclear centration. Support for these observations was found in parthenogenetically activated eggs, in which microtubule arrays were organized around the single female pronucleus that formed after artificial activation. These observations support a biparental centrosomal contribution during rabbit fertilization as opposed to a strictly paternal inheritance pattern suggested from previous studies. In rabbit eggs that received injected human donor sperm, an astral array of microtubules radiated from the sperm neck and enlarged as the sperm head underwent pronuclear decondensation. gamma-Tubulin was observed in the center of the sperm aster. We conclude that the rabbit egg exhibits a blended centrosomal contribution necessary for completion of fertilization and that the rabbit egg may be a novel animal model for assessing centrosomal function in human sperm and spermatogenic cells following intracytoplasmic injection.     

The first cycle of DNA replication in mouse embryogenesis studied by microinjections of 3H-thymidine into the cytoplasm of fertilized ova

H-thymidine was injected into cytoplasm of the eggs taken at different intervals after fertilization and the eggs were fixed immediately thereafter. DNA synthesis was shown to begin in pronuclei when they are still in the marginal zones of cytoplasm, immediately after their formation. S-phase lasts 5-6 h in every pronucleus and is terminated at 1-2 h before the first cleavage division when the pronuclei are closely approached and located in the center of cytoplasm. At the end of S-phase late replicating heterochromatic regions are distinctly localized near the nuclear envelope and in pronuclei. Male and female pronuclei display asynchrony in the course of S-phase and differences in 3H-thymidine incorporation into chromatin. Structural features of the first cell cycle in mouse embryogenesis are discussed.     

Intracellular localization of argyrophilic proteins in the maturing oocyte,fertilized egg,and spermatozoa of the starfish,Asterina pectinifera

Changes in intracellular localization of argyrophilic proteins visualized as silver-stained particles by nuclear organizer region (NOR)-silver staining were investigated in starfish oocyte maturation. The silver-stained particles were localized in the germinal vesicle and nucleolus of immature oocytes and dispersed into the cytoplasm at the time of germinal vesicle breakdown (GVBD). In the mature egg cytoplasm, silver-stained particles were distributed on yolk-like granules with diameters of 0.3–1.0 μm. In spermatozoa, silver-stained particles were detected heavily in the acrosome and centrosomes but few were detected in the nucleus, whereas they were present in the male pronucleus of fertilized eggs. The silver-stained particles were removed by pretreatment of eggs with protease but not with nuclease. These results indicate that argyrophilic proteins disperse to the egg cytoplasm during GVBD and might be incorporated to the male pronucleus from the egg cytoplasm in fertilization. The morphological changes from chromosomes through chromosome vesicles to female pronucleus were also observed with light microscopy after NOR-silver staining.     

Analysis of fertilization and polyspermy in serotonin-spawned eggs of the zebra mussel,Dreissena polymorpha

Eggs isolated from animals spawned with 10⁻³ M serotonin were inseminated with sperm concentrations ranging from 10³–10⁶ sperm/ml. Multiple sperm attached to the surface of the egg and sperm incorporation occurred within 3 min postinsemination (PI). Sperm mitochondria, centrioles, and flagellum were also incorporated. Incorporation was essentially complete by 6 min PI. In the egg cortex, the sperm head rotated 180°, and a rapid translocation of the sperm through the cytoplasm towards the egg interior began by 5–6 min PI. In heavily polyspermic inseminations, translocations of the sperm were either minimal or nonexistent. In monospermic eggs, nuclear decondensation occurred after translocation was complete, beginning by 9–10 min PI. A male pronucleus began to develop in the cytoplasm by 21 min PI and enlarged to 20 μm before fusing with the female pronucleus. Oscillation of the egg cytoplasm and mitotic spindle apparatus was observed immediately prior to cleavage. Cleavage occurred at 60 min PI. Sperm incorporation and pronuclear formation were confirmed with fluorescent and confocal microscopy using the DNA-specific dyes Hoescht 33342 and 7-aminoactinomycin D. In sperm concentrations >10⁴ sperm/ml, 26–76% of the eggs exhibited polyspermy. The high incidence of polyspermy suggests that rapid, effective blocks to polyspermy were not present or were ineffective in a significant proportion of serotonin-spawned eggs. © 1996 Wiley-Liss, Inc.     

Nascent protein requirement for completion of meiotic maturation and pronuclear development: examination of fertilized and A-23187-activated surf clam (Spisula solidissima) eggs

The involvement of newly synthesized proteins and calcium in meiotic processes, sperm nuclear transformations, and pronuclear development was examined in emetine-treated, fertilized, and A-23187-activated Spisula eggs by observing changes in the morphogenesis of the maternal and paternal chromatin. Emetine treatment (50 micrograms/ml) initiated 30 min before fertilization or A-23187 activation inhibited incorporation of [3H]leucine into TCA-precipitable material and blocked second polar body formation. Sperm incorporation and the initial enlargement of the sperm nucleus were unaffected; however, the dramatic enlargement and transformation of the sperm nucleus into a male pronucleus, which normally follow polar body formation, were delayed 10 to 20 min. Unlike the situation in untreated, control eggs, male pronuclear development took place while the maternally derived chromosomes remained condensed. It was not until approximately 20 min after the normal period of pronuclear development that the maternal chromosomes dispersed and formed a female pronucleus in emetine-treated, fertilized eggs. Formation of pronuclei, however, was unaffected in both emetine-treated, A-23187-activated eggs and fertilized eggs incubated with A-23187. These observations indicate that germinal vesicle breakdown, first polar body formation, and initial transformations of the sperm nucleus are independent of newly synthesized proteins. Inhibition of second polar body formation and the delay in pronuclear development brought about by emetine, as well as the appearance of silver grains over pronuclei in autoradiographs of control eggs incubated with [3H]leucine demonstrate that nascent proteins are involved with the completion of meiotic maturation and the development of male and female pronuclei. The ability of A-23187 to override the inhibitory effects of emetine on pronuclear development suggests that both nascent protein and calcium signals are involved in regulating the status of the maternal and paternal chromatin during pronuclear development.     

Intracellular pH regulation by HCO3-/Cl- exchange is activated during early mouse zygote development

We report here that at least one major pHi-regulatory mechanism, the HCO3-/Cl- exchanger, is quiescent in unfertilized mouse eggs but becomes fully activated during early development following fertilization. Zygotes (8-12 h postfertilization) exhibited a marked intracellular alkalinization upon external Cl- removal, which is indicative of active HCO3-/Cl- exchangers, in contrast to the very small response observed in eggs. In addition, efflux of Cl- from eggs upon external Cl- removal was much slower than that from zygotes, indicating additional pathways for Cl- to cross the plasma membrane in zygotes. Furthermore, while zygotes quickly recovered from an induced alkalosis, eggs exhibited only a slow, incomplete recovery. Following in vitro fertilization (IVF), increased HCO3-/Cl- exchanger activity was first detectable about 4 h postfertilization and reached the maximal level after about 8 h. The upregulation of HCO3-/Cl- exchanger activity after fertilization appeared to occur by activation of existing, inactive exchangers rather than by synthesis or transport of new exchangers, as the increase in activity following IVF was unaffected by inhibition of protein synthesis or by disruption of the Golgi apparatus or the cytoskeleton. This activation may depend on the Ca2+ transients which follow fertilization, as suppression of these transients, using the Ca2+ chelator BAPTA, reduced subsequent upregulation of HCO3-/Cl- exchanger activity by about 50%. Activation of pHi-regulatory systems may be a widespread feature of the earliest period of embryonic development, not restricted to species such as marine invertebrates as previously believed.     

Relationship between sperm nucleus remodelling and cell cycle progression of fragments of mouse parthenogenotes

Nucleate and anucleate fragments of parthenogenetically activated mouse oocytes, as well as cybrids obtained by fusion of anucleate fragments (cytoplasts) of maturing and activated matured oocytes were fertilized at different time after activation. Remodelling of the sperm nucleus was studied by electron microscopy at 1.5 and 3 h after fertilization and, in addition, at 14 h in cybrids. Results show that (1) the nuclear envelope of the sperm nucleus can break down when the insemination takes place after the end of M-phase, but the capacity of the parthenote cytoplasm to remodel the sperm nucleus is restricted in time. (2) Male chromatin can decondense within the old, unbroken nuclear envelope, but in such cases formation of a male pronucleus, one of the two nuclei of zygote possessing inactive nucleoli, is never observed. © 1994 Wiley-Liss, Inc.