A hypothesis on p34cdc2 sequestration based on the existence of Ca(2+)-coordinated changes in H+ and MPF activities during Xenopus egg activation [corrected]

The entry into, and exit from, mitosis are controlled by a universal M-phase promoting factor (MPF) composed of at least p34cdc2 and a cyclin. Embryonic systems are convenient for studying the association and dissociation of the active MPF complex because oocytes and eggs are naturally arrested at a specific point of the cell cycle until progression to the next point is triggered by a hormonal signal or sperm. In amphibians, eggs prior to fertilization are arrested at metaphase 2 of meiosis due to the presence of a stabilized MPF complex. Fertilization (egg activation) produces a transient increase in intracellular free Ca2+, a propagating Ca2+ wave, that specifically triggers the destruction of cyclin, leading to MPF inactivation and entry into the first embryonic inter-phase. We have recently shown that intracellular pH (pHi) variations in amphibian eggs, a large increase at fertilization and small oscillations during the embryonic cell cycle, were temporally and functionally related to the corresponding changes in MPF activity. In addition, the recent finding that the pHi increase at fertilization in Xenopus eggs is a propagating, Ca(2+)-dependent pH wave which closely follows the Ca2+ wave, together with the absence in the egg plasma membrane of pHi-regulating systems responsible for that pHi increase, suggest the existence of cortical or subcortical vesicles acidifying in the wake of the Ca2+ wave, thus producing the pH wave.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cycling of intracellular pH during cell division of Xenopus embryos is a cytoplasmic activity depending on protein synthesis and phosphorylation

In Xenopus embryos, the successive and rapid cell divisions that follow fertilization are accompanied by periodic oscillations of intracellular pH (pHi). Cycling of pHi occurs in phase with several other oscillatory activities, namely nuclear divisions, M phase-promoting factor (MPF) activity, and surface contraction waves (SCWs). We report that treatments that abolish cycling of MPF activity and the SCWs also suppress the pHi oscillations, whereas those that block cell division without affecting neither MPF activity nor the SCWs do not suppress the pHi oscillations. Experiments on enucleated oocytes, matured in vitro and activated, demonstrated that the activity governing the rhythmicity of the pHi oscillations resided in the cytoplasm of the oocyte. In this respect, the activity responsible for the pHi oscillations was different from that which drives the SCWs, which necessitated the presence of the oocyte germinal vesicle (Ohsumi et al., 1986), but more closely resembled MPF activity that did not require the presence of the oocyte germinal vesicle (Dabauvalle et al., 1988). In mature eggs enucleated at the time of egg activation, the pHi oscillations were similar to those in control nucleated eggs, whereas the period between two peaks of SCWs was 35-60 min vs. 20-35 min in nucleated control eggs. Previous studies had shown that the periodicity of SCWs was larger in anucleate egg fragments than in their nucleate counterparts (Sakai and Kubota, 1981), the difference being on the order of 6-15 min (Shinagawa, 1983). However, in these previous studies, enucleation was performed 30-50 min after fertilization. Our results clearly demonstrate that the periodicity of the SCWs is lengthened when the interval between egg activation and enucleation is shortened, thereby providing an easier way to assess the nuclear dependency of the SCWs. Finally, the various possibilities concerning the role of pHi cycling during cell division are discussed.     

Intracellular pH and intracellular free calcium responses to protein kinase C activators and inhibitors in Xenopus eggs.

Cell activation during fertilization of the egg of Xenopus laevis is accompanied by various metabolic changes, including a permanent increase in intracellular pH (pHi) and a transient increase in intracellular free calcium activity ([Ca2+]i). Recently, it has been proposed that protein kinase C (PKC) is an integral component of the Xenopus fertilization pathway (Bement and Capco, J. Cell Biol. 108, 885-892, 1989). Indeed, activators of PKC trigger cortical granule exocytosis and cortical contraction, two events of egg activation, without, however, releasing the cell cycle arrest (blocked in second metaphase of meiosis). In the egg of Xenopus, exocytosis as well as cell cycle reinitiation are supposed to be triggered by the intracellular Ca2+ transient. We report here that PKC activators do not induce the intracellular Ca2+ transient, or the activation-associated increase in pHi. These results suggest that the ionic responses to egg activation in Xenopus do not appear to depend on the activation of PKC. In addition, in eggs already pretreated with phorbol esters, those artificial activators that act by releasing Ca2+ intracellularly, triggered a diminished increase in pHi. Finally, sphingosine and staurosporine, two potent inhibitors of PKC, were found to trigger egg activation, suggesting that a decrease in PKC activity might be an essential event in the release of the metaphase block, in agreement with recent findings on the release of the prophase block in Xenopus oocytes (Varnold and Smith, Development 109, 597-604, 1990).     

Organization and regulation of cortical microtubules during the first cell cycle of Xenopus eggs.

Anti-tubulin antibodies and confocal immunofluorescence microscopy were used to examine the organization and regulation of cytoplasmic and cortical microtubules during the first cell cycle of fertilized Xenopus eggs. Appearance of microtubules in the egg cortex temporally coincided with the outgrowth of the sperm aster. Microtubules of the sperm aster first reached the animal cortex at 0.25, (times normalized to first cleavage), forming a radially organized array of cortical microtubules. A disordered network of microtubules was apparent in the vegetal cortex as early as 0.35. Cortical microtubule networks of both animal and vegetal hemispheres were reorganized at times corresponding to the cortical rotation responsible for specification of the dorsal-ventral (D-V) axis. Optical sections suggest that the cortical microtubules are continuous with the microtubules of the sperm aster in fertilized eggs, or an extensive activation aster in activated eggs. Neither assembly and organization, nor disassembly of the cortical microtubules coincided with MPF activation during mitosis. However, cycloheximide or 6-dimethylaminopurine, which arrest fertilized eggs at interphase, blocked cortical microtubule disassembly. Injection of p13, a protein that specifically inhibits MPF activation, delayed or inhibited cortical microtubule breakdown. In contrast, eggs injected with cyc delta 90, a truncated cyclin that arrest eggs in M-phase, showed normal microtubule disassembly. Finally, injection of partially purified MPF into cycloheximide-arrested eggs induced cortical microtubule breakdown. These results suggest that, despite a lack of temporal coincidence, breakdown of the cortical microtubules is dependent on the activation of MPF.     

Cell cycle dynamics of an M-phase-specific cytoplasmic factor in Xenopus laevis oocytes and eggs

We have examined the regulation of maturation-promoting factor (MPF) activity in the mitotic and meiotic cell cycles of Xenopus laevis eggs and oocytes. To this end, we developed a method for the small scale extraction of eggs and oocytes and measured MPF activity in extracts by a dilution end point assay. We find that in oocytes, MPF activity appears before germinal vesicle breakdown and then disappears rapidly at the end of the first meiotic cycle. In the second meiotic cycle, MPF reappears before second metaphase, when maturation arrests. Thus, MPF cycling coincides with the abbreviated cycles of meiosis. When oocytes are induced to mature by low levels of injected MPF, cycloheximide does not prevent the appearance of MPF at high levels in the first cycle. This amplification indicates that an MPF precursor is present in the oocyte and activated by posttranslational means, triggered by the low level of injected MPF. Furthermore, MPF disappears approximately on time in such oocytes, indicating that the agent for MPF inactivation is also activated by posttranslational means. However, in the absence of protein synthesis, MPF never reappears in the second meiotic cycle. Upon fertilization or artificial activation of normal eggs, MPF disappears from the cytoplasm within 8 min. For a period thereafter, the inactivating agent remains able to destroy large amounts of MPF injected into the egg. It loses activity just as endogenous MPF appears at prophase of the first mitotic cycle. The repeated reciprocal cycling of MPF and the inactivating agent during cleavage stages is unaffected by colchicine and nocodazole and therefore does not require the effective completion of spindle formation, mitosis, or cytokinesis. However, MPF appearance is blocked by cycloheximide applied before mitosis; and MPF disappearance is blocked by cytostatic factor. In all these respects, MPF and the inactivating agent seem to be tightly linked to, and perhaps participate in, the cell cycle oscillator previously described for cleaving eggs of Xenopus laevis (Hara, K., P. Tydeman, and M. Kirschner, 1980, Proc. Natl. Acad. Sci. USA, 77:462- 466).     

Activation of Xenopus laevis eggs in the absence of intracellular Ca activity by the protein phosphorylation inhibitor, 6-dimethylaminopurine (6-DMAP).

Xenopus laevis eggs pricked or microinjected with water or saline in medium containing a limited quantity of free Ca (1.0 to 2.0 microM) remain unactivated for at least 6 hr, even after transfer to oocyte medium containing Ca at higher concentrations (0.5-1.0 mM). These injected eggs, when later pricked in oocyte medium or exposed to A23187 or urethane are fully capable of activation. This confirms the observations of Wangh ('89). However, eggs injected in this Ca-limited medium (CaLM) with 6-DMAP as well as those simply exposed to this drug undergo changes characteristic of activation, including cortical contraction, cortical granule breakdown, a loss of MPF and CSF activities, and pronuclear formation. The time required for 6-DMAP to induce egg activation is inversely correlated to its concentration. Interestingly, eggs that have been injected with EGTA, and thus are unable to respond to activation stimuli such as pricking and A23187 or urethane treatment, can also be activated by exposure to 6-DMAP. In contrast, eggs exposed to or injected with a 6-DMAP analogue (6-aminopurine or puromycin) or a protein synthesis inhibitor (cycloheximide or emetine or puromycin) are not activated. As well, eggs injected in CaLM with 6-DMAP simultaneously with a phosphatase inhibitor (NaF or ammonium molybdate) fail to become activated. Although 6-DMAP-activated eggs remain at the pronucleus stage so long as 6-DMAP is present, they resume cell cycle activities after the drug is withdrawn. They form cleavage furrows, disassemble pronuclear envelopes, and recondense chromosomes. Also, MPF activity reappears and cycles at least twice, peaking each time shortly before cleavage furrow formation. These results suggest that activation of Xenopus eggs arrested at metaphase II by inhibition of protein phosphorylation does not require intracellular Ca release and that maintenance of the egg at metaphase II depends upon continuous protein phosphorylation.     

Role of nuclear material in the early cell cycle of Xenopus embryos

Activated Xenopus eggs show periodic surface contraction waves and oscillations in endogenous protein phosphorylation, MPF, and kinase activities timed with the cleavage cycle of control fertilized eggs. In this paper, we show that in activated eggs lacking the material that originates from the oocyte nucleus, MPF and kinase oscillations occur in the absence of surface contraction waves. Two mitotic phosphoproteins (M116 and M46), previously described by 32P labeling in nucleated eggs, are no longer detected in the enucleated eggs. We conclude that a cytoplasmic temporal control of MPF and kinase activities is likely to be the essential cell cycle oscillator. The oocyte nuclear components normally stored in the cytoplasm of the embryos are not involved in the clock although they appear to be required for the generation of surface contraction waves.     

Cyclic regulation of cytokinesis in amphibian eggs

The effects of amphibian egg cytoplasm extracted at different times after activation and during the first four cleavages on cytokinesis were examined. Extracts of artificially activated or fertilized Xenopus or Pleurodeles eggs taken at the time of activation (T = 0) provoked precocious cleavage furrows in Pleurodeles eggs. Between T = 0.25 and T = 0.75 of the first cell cycle, the period corresponding to interphase, an inhibitory effect was found, and the division of injected eggs was delayed up to 30%. After T = 0.75, that is during mitosis, the cleavage induction effect was observed again. These enhancing and inhibitory effects were also found in the two fractions obtained following gel filtration of the cytoplasmic extracts. These experiments support the hypothesis that two antagonistic factors control cytokinesis. The inhibitory factor is active only during interphase, while the positive factor is present during mitosis and appears to regulate cytokinesis.     

Cyclic changes in amphibian egg microvilli occur during the division cycle: implication of MPF.

The microvilli (MV) of Pleurodeles (amphibian) eggs were examined following fertilization and compared with those of artificially activated eggs and enucleated eggs using scanning and transmission electron microscopy. The MV pattern in fertilized eggs was found to undergo a cyclic transformation during the course of the first few division cycles. Similar changes also occurred in the MV of artificially activated eggs and enucleated eggs. The reorganization of the MV was sensitive to cycloheximide and cytochalasin B, but was unaffected by colchicine. Thus, this MV alteration requires protein synthesis and microfilaments but microtubules are not implicated in this process. In addition, the effects on the MV pattern of the maturation or mitosis promoting factor (MPF) were tested. Injection of MPF into eggs at different times during the first division cycle nearly always induced an elongation of the MV. This observation suggests that MPF could regulate either directly or indirectly, via a MPF-sensitive factor, the cyclic transformation of amphibian egg MV.     

Direct measurement of intracellular pH changes in Xenopus eggs at fertilization and cleavage

We have used Thomas-type recessed-tip pH-sensitive microelectrodes to measure the intracellular pH (pHi) in Xenopus eggs during both fertilization and ionophore activation. The average pHi in unfertilized eggs is 7.33 +/- 0.11 (SD; n = 21) with a resting membrane potential of -10.1 +/- 3.5 (SD; n = 38) mV. Within 2 min after the onset of the fertilization potential, there is a slight, transient pHi decrease of 0.03 +/- (SD, n = 8), followed by a distinct, permanent pHi increase of 0.31 +/- 0.11 (SD; n = 7) beginning approximately 10 min after the start of the fertilization potential and becoming complete approximately 1 h later. The pHi remains near this level of 7.67 +/- 0.13 (SD, n = 10) through at least 10 cleavage cycles, but it is possible to discern pHi oscillations with a mean amplitude of 0.03 +/- 0.02 (SD, n = 38). Eggs perfused for at least 2 h in Na+-free solution with 1 mM amiloride exhibited all of these pHi changes, so these changes do not require extracellular Na+. Similar cytoplasmic alkalinizations that accompany the activation of metabolism and the cell cycle in a wide variety of cell types are discussed.     

Intracellular pH and the increase in protein synthesis accompanying activation of Xenopus eggs

Metabolic activation following egg fertilization corresponds to an increase in protein synthesis and the initiation of DNA synthesis, which lead to cell division and development of the embryo. Since in several biological systems protein synthesis is regulated by intracellular pH (pHi), we have decided to investigate the situation during Xenopus egg activation. We confirmed that egg activation is accompanied by a pHi rise of 0.3 pH unit. Measurements of the rates of protein synthesis is unactivated and activated eggs, after microinjection of 3H-leucine, demonstrated that activation was followed by a 2.5-fold increase. Treatment of unactivated eggs with weak bases also increased pHi, but did not result in an increase in the rate of protein synthesis. Moreover, in vitro translation in cytoplasmic extracts was found to be pH-independent, at least between 6.8 and 8.2.     

Nuclei and microtubule asters stimulate maturation/M phase promoting factor (MPF) activation in Xenopus eggs and egg cytoplasmic extracts

Although maturation/M phase promoting factor (MPF) can activate autonomously in Xenopus egg cytoplasm, indirect evidence suggests that nuclei and centrosomes may focus activation within the cell. We have dissected the contribution of these structures to MPF activation in fertilized eggs and in egg fragments containing different combinations of nuclei, centrosomes, and microtubules by following the behavior of Cdc2 (the kinase component of MPF), the regulatory subunit cyclin B, and the activating phosphatase Cdc25. The absence of the entire nucleus-centrosome complex resulted in a marked delay in MPF activation, whereas the absence of the centrosome alone caused a lesser delay. Nocodazole treatment to depolymerize microtubules through first interphase had an effect equivalent to removing the centrosome. Furthermore, microinjection of isolated centrosomes into anucleate eggs promoted MPF activation and advanced the onset of surface contraction waves, which are close indicators of MPF activation and could be triggered by ectopic MPF injection. Finally, we were able to demonstrate stimulation of MPF activation by the nucleus-centriole complex in vitro, as low concentrations of isolated sperm nuclei advanced MPF activation in cycling cytoplasmic extracts. Together these results indicate that nuclei and microtubule asters can independently stimulate MPF activation and that they cooperate to enhance activation locally.     

DNA ligase I from Xenopus laevis eggs.

We have purified the major DNA ligase from Xenopus laevis eggs and raised antibodies against it. Estimates from SDS PAGE indicate that this DNA ligase is a 180 kDa protein. This enzyme is similar to the mammalian type I DNA ligase which is presumed to be involved in DNA replication. We have also analysed DNA ligase activity during X. laevis early development. Unfertilized eggs contain the highest level of activity reflecting the requirement for a large amount of DNA replicative enzymes for the period of intense replication following fertilization. In contrast with previous studies on the amphibians axolotl and Pleurodeles, the major DNA ligase activity detected during X. laevis early development is catalysed by a single enzyme: DNA ligase I. And the presence of this DNA ligase I in Xenopus egg before fertilization clearly demonstrates that the exclusion process of two forms of DNA ligase does not occur during X. laevis early development.     

Protein kinase C acts downstream of calcium at entry into the first mitotic interphase of Xenopus laevis.

Transit into interphase of the first mitotic cell cycle in amphibian eggs is a process referred to as activation and is accompanied by an increase in intracellular free calcium [( Ca2+]i), which may be transduced into cytoplasmic events characteristic of interphase by protein kinase C (PKC). To investigate the respective roles of [Ca2+]i and PKC in Xenopus laevis egg activation, the calcium signal was blocked by microinjection of the calcium chelator BAPTA, or the activity of PKC was blocked by PKC inhibitors sphingosine or H7. Eggs were then challenged for activation by treatment with either calcium ionophore A23187 or the PKC activator PMA. BAPTA prevented cortical contraction, cortical granule exocytosis, and cleavage furrow formation in eggs challenged with A23187 but not with PMA. In contrast, sphingosine and H7 inhibited cortical granule exocytosis, cortical contraction, and cleavage furrow formation in eggs challenged with either A23187 or PMA. Measurement of egg [Ca2+]i with calcium-sensitive electrodes demonstrated that PMA treatment does not increase egg [Ca2+]i in BAPTA-injected eggs. Further, PMA does not increase [Ca2+]i in eggs that have not been injected with BAPTA. These results show that PKC acts downstream of the [Ca2+]i increase to induce cytoplasmic events of the first Xenopus mitotic cell cycle.     

Calcium ultrastructural localization in Xenopus laevis eggs following activation by pricking or by calcium ionophore A 23187

In the egg of Xenopus laevis a cortical network of smooth endoplasmic reticulum (SER) surrounds and interconnects each cortical granule (CG) (Campanella and Andreuccetti, '77). This network is a possible intracellular site of calcium storage to be called into action for CG exocytosis. In our experiments, Xenopus eggs, unfertilized or activated by pricking or by calcium ionophore A 23187, have been fixed in osmium-pyroantimonate for calcium localization. Our data show that deposits can be detected only in activated eggs. The calcium chelator edetate (EGTA) and x-ray microprobe analysis demonstrate that they contain calcium. Deposits are found on liposomes and on all intraovular cytomembranes, which therefore appear to be possible sites of calcium sequestration. In the case of ionophore-activated eggs, deposits are detectable independently of the presence of extracellular calcium. These data show that in Xenopus at activation an intracellular liberation of calcium occurs similar to that described in other species. Furthermore, the fact that antimony deposits are observed only after activation makes Xenopus eggs appropriate material in which to follow the temporal and spatial sequence of appearance of the deposits during the early stages of activation. Our results show that antimony deposits appear first in SER vesicles between the plasma membrane and CGs and then spread to the rest of the egg cytomembranes. These data corroborate our hypothesis that in Xenopus the cortical SER network is the first intracellular site where calcium is released at activation. The possible mechanism of calcium release and propagation along the egg cortex is discussed.     

Maturation-promoting factor induces nuclear envelope breakdown in cycloheximide-arrested embryos of Xenopus laevis

We have studied the effect of maturation-promoting factor (MPF) on embryonic nuclei during the early cleavage stage of Xenopus laevis development. When protein synthesis is inhibited by cycloheximide during this stage, the embryonic cell cycle arrests in an artificially produced G2 phase-like state, after completion of one additional round of DNA synthesis. Approximately 100 nuclei can be arrested in a common cytoplasm if cytokinesis is first inhibited by cytochalasin B. Within 5 min after injection of MPF into such embryos, the nuclear envelope surrounding each nucleus disperses, as determined histologically or by immunofluorescent staining of the nuclear lamina with antilamin antiserum. The breakdown of the nuclear envelope occurs at levels of MPF comparable to or slightly lower than those required for oocyte maturation. Amplification of MPF activity, however, does not occur in the arrested egg as it does in the oocyte. These results suggest that MPF can act to advance interphase nuclei into the first events of mitosis and show that the nuclear lamina responds rapidly to MPF.     

Egg-to-embryo transition is driven by differential responses to Ca(2+) oscillation number

Ca(2+) oscillations and signaling represent a basic mechanism for controlling many cellular events. Activation of mouse eggs entrains a temporal series of Ca(2+)-dependent events that include cortical granule exocytosis, cell cycle resumption with concomitant decreases in MPF and MAP kinase activities, and recruitment of maternal mRNAs. The outcome is a switch in cellular differentiation, i.e., the conversion of the egg into the zygote. By activating mouse eggs with experimentally controlled and precisely defined Ca(2+) transients, we demonstrate that each of these events is initiated by a different number of Ca(2+) transients, while their completion requires a greater number of Ca(2+) transients than for their initiation. This combination of differential responses to the number of Ca(2+) transients provides strong evidence that a single Ca(2+) transient-driven signaling system can initiate and drive a cell into a new developmental pathway, as well as can account for the temporal sequence of cellular changes associated with early development.     

Cytoplasmic phases in the first cell cycle of the activated frog egg

The first cell cycle of the activated frog egg is longer than subsequent cycles and several developmentally important events such as the determination of bilateral symmetry occur at this time. When eggs of Rana pipiens or Xenopus laevis are dissected at times after activation, differences in the consistency of the animal half cytoplasm can be detected visually, and the first cell cycle has been divided into four cytoplasmic phases on this basis. Phase 1 includes the events of activation and lasts about one-third of the first cycle. In phase 2, the cytoplasm becomes fluid except for the rigid, growing sperm aster, and most of the migration of the pronuclei occurs in phase 2. In phase 3, the cytoplasm becomes firm whether or not a sperm aster had been present, and the grey crescent forms, indicating the plane of bilateral symmetry. The firmness of the cytoplasm is colchicine sensitive but cytochalasin B insensitive as is grey crescent formation. In phase 4, the cortex detaches from the firm cytoplasm, and the firmness is now cytochalasin B sensitive and colchicine insensitive. The changes in cytoplasmic consistency during the first cell cycle probably reflect changes in the cytoskeleton, and the cytoplasmic consistency is functionally correlated with developmental events in the first cell cycle.     

Localised MPF regulation in eggs

In this review we discuss the evidence that activation and inactivation of M-phase promoting factor (MPF), the universal mitotic activator, are regulated locally within the cell, and consider the mechanisms that might be responsible. Localised initiation of MPF activation has been demonstrated in Xenopus eggs and egg fragments by examination of the timing of surface contraction waves (SCWs), indicators of MPF activity, and confirmed by direct measurement of MPF in such fragments. Both the timing and the site of SCW initiation relate to the presence of nuclei and of associated centriole-nucleated microtubules. Localised MPF activation is likely to occur in the perinuclear cytoplasm as well as within the nucleus. Studies in a number of cell types show that the perinuclear/centrosomal region is the site of accumulation of MPF itself (the cyclin B-Cdc2 kinase complex) and of many of its molecular regulators. It also harbours calcium-regulating machinery, and in sea urchin eggs is the site of transient calcium release at the onset of mitosis. During mitosis MPF, regulatory molecules and calcium signalling components associate with spindle structures. Inactivation of MPF to end mitosis has been shown to be initiated locally at the mitoic spindle in Drosophila embryos. In sea urchin and frog eggs, calcium transients are required for both mitotic entry and exit and in mouse eggs, MPF inactivation requires both a calcium signal and an intact spindle. It thus appears that calcium signals coinciding with localised accumulation of MPF regulators are required first to set off and/or amplify the MPF activation process around the nucleus, and later to promote MPF inactivation via cyclin B destruction. Calcium release from sequestering machinery organised around nuclear and astral structures may act co-operatively with localised MPF regulatory molecules to trigger both mitotic entry and exit.     

The Ca2+ increase by the sperm factor in physiologically polyspermic newt fertilization: its signaling mechanism in egg cytoplasm and the species-specificity

The newt, Cynops pyrrhogaster, exhibits physiological polyspermic fertilization, in which several sperm enter an egg before egg activation. An intracellular Ca(2+) increase occurs as a Ca(2+) wave at each sperm entry site in the polyspermic egg. Some Ca(2+) waves are preceded by a transient spike-like Ca(2+) increase, probably caused by a tryptic protease in the sperm acrosome at the contact of sperm on the egg surface. The following Ca(2+) wave was induced by a sperm factor derived from sperm cytoplasm after sperm-egg membrane fusion. The Ca(2+) increase in the isolated, cell-free cytoplasm indicates that the endoplasmic reticulum is the major Ca(2+) store for the Ca(2+) wave. We previously demonstrated that citrate synthase in the sperm cytoplasm is a major sperm factor for egg activation in newt fertilization. In the present study, we found that the activation by the sperm factor as well as by fertilizing sperm was prevented by an inhibitor of citrate synthase, palmitoyl CoA, and that an injection of acetyl-CoA or oxaloacetate caused egg activation, indicating that the citrate synthase activity is necessary for egg activation at fertilization. In the frog, Xenopus laevis, which exhibits monospermic fertilization, we were unable to activate the eggs with either the homologous sperm extract or the Cynops sperm extract, indicating that Xenopus sperm lack the sperm factor for egg activation and that their eggs are insensitive to the newt sperm factor. The mechanism of egg activation in the monospermy of frog eggs is quite different from that in the physiological polyspermy of newt eggs.