Phospholipase C-dependent Ca2+ release by worm and mammal sperm factors

Egg activation in all animals evidently requires the synthesis of inositol 1,4,5-trisphosphate (InsP(3)) from phosphatidylinositol 4,5-bisphosphate (PIP(2)) by phospholipase C (PLC). Depending on the organism, InsP(3) elicits either calcium oscillations or a single wave, which in turn initiates development. A soluble component in boar sperm that activates mammalian eggs has been suggested to be a PLC isoform. We tested this hypothesis in vitro using egg microsomes of Chaetopterus. Boar sperm factor elicited Ca(2+) release from the microsomes by an InsP(3)-dependent mechanism. The PLC inhibitor U-73122, but not its inactive analog U-73343, blocked the response to sperm factor but not to InsP(3). U-73122 also inhibited the activation of fertilized and parthenogenetic eggs. Chaetopterus sperm also contained a similar activity. These results strongly support the hypothesis that sperm PLCs are ubiquitous mediators of egg activation at fertilization.     

Animal-vegetal axis patterning mechanisms in the early sea urchin embryo

During mouse fertilization the spermatozoon induces a series of low-frequency long-lasting Ca(2+) oscillations. It is generally accepted that these oscillations are due to Ca(2+) release through the inositol 1,4,5-trisphosphate (InsP(3)) receptor. However, InsP(3) microinjection does not mimic sperm-induced Ca(2+) oscillations, leading to the suggestion that the spermatozoon causes Ca(2+) release by sensitizing the InsP(3) receptor to basal levels of InsP(3). This contradicts recent evidence that the spermatozoon triggers Ca(2+) oscillations by introducing a phospholipase C or else an activator of phospholipase C. Here we show for the first time that sperm-induced Ca(2+) oscillations may be mimicked by the photolysis of caged InsP(3) in both mouse metaphase II eggs and germinal vesicle stage oocytes. Eggs, and also oocytes that had displayed spontaneous Ca(2+) oscillations, gave long-lasting Ca(2+) oscillations when fertilized or when caged InsP(3) was photolyzed. In contrast, oocytes that had shown no spontaneous Ca(2+) oscillations did not generate many oscillations when fertilized or following photolysis of caged InsP(3). Fertilization in eggs was most closely mimicked when InsP(3) was uncaged at relatively low amounts for extended periods. Here we observed an initial Ca(2+) transient with superimposed spikes, followed by a series of single transients with a low frequency; all characteristics of the Ca(2+) changes at fertilization. We therefore show that InsP(3) can mimic the distinctive pattern of Ca(2+) release in mammalian eggs at fertilization. It is proposed that a sperm Ca(2+)-releasing factor operates by generating a continuous small amount of InsP(3) over an extended period of time, consistent with the evidence for the involvement of a phospholipase C.     

Flowering plant sperm contains a cytosolic soluble protein factor which can trigger calcium oscillations in mouse eggs

There is evidence showing that the sperm-induced Ca(2+) oscillations in mammalian eggs at fertilization are triggered by a sperm-derived protein factor. It was established recently that the activity of the putative sperm protein in causing Ca(2+) oscillations in mammalian eggs is not species-specific in vertebrates (1, 16). Here we report that cytosolic soluble extracts derived from flowering plant sperms in Brassica campestris can also induce fertilization-like Ca(2+) oscillations when microinjected into mouse eggs. The factor responsible for inducing Ca(2+) oscillations in the plant sperm was sperm-specific and heat- or trypsin-labile. Eight to ten sperm equivalents of the plant sperm extracts had enough activity to trigger Ca(2+) oscillations in mouse eggs. Our study suggests that, although plant and mammal are evolutionary divergent species, the activity of the putative sperm protein factor in triggering Ca(2+) signaling in mammalian eggs is not specific to the animal kingdom.     

Inositol 1,4,5-trisphosphate receptors are downregulated in mouse oocytes in response to sperm or adenophostin A but not to increases in intracellular Ca(2+) or egg activation

Fertilization in mammals stimulates a series of Ca(2+) oscillations that continue for 3-4 h. Cell-cycle-dependent changes in the ability to release Ca(2+) are one mechanism that leads to the inhibition of Ca(2+) transients after fertilization. The downregulation of InsP(3)Rs at fertilization may be an additional mechanism for inhibiting Ca(2+) transients. In the present study we examine the mechanism of this InsP(3)R downregulation. We find that neither egg activation nor Ca(2+) transients are necessary or sufficient for the stimulation of InsP(3)R downregulation. First, parthenogenetic activation fails to stimulate downregulation. Second, downregulation persists when fertilization-induced Ca(2+) transients and egg activation are inhibited using BAPTA. Third, downregulation can be induced in immature oocytes that do not undergo egg activation. Other than fertilization, the only stimulus that downregulated InsP(3)Rs was microinjection of the potent InsP(3)R agonist adenophostin A. InsP(3)R downregulation was inhibited by the cysteine protease inhibitor ALLN but MG132 and lactacystin were not effective. Finally, we have injected maturing oocytes with adenophostin A and produced MII eggs depleted of InsP(3)Rs. We show that sperm-induced Ca(2+) signaling is inhibited in such InsP(3)R-depleted eggs. These data show that InsP(3)R binding is sufficient for downregulation and that Ca(2+) signaling at fertilization is mediated via the InsP(3)R.     

Xenopus and chicken sperm contain a cytosolic soluble protein factor which can trigger calcium oscillations in mouse eggs

There is evidence showing that at fertilization the sperm introduces into egg cytoplasm a protein-based cytosolic factor, which serves as the physiological trigger for inducing Ca(2+) oscillations in mammalian eggs. Here we show that sperm of nonmammalian vertebrates also contain a cytosolic protein factor that can induce Ca(2+) oscillations when introduced into mammalian eggs. We have observed that cytosolic extracts derived from Xenopus or chicken sperm could induce mouse eggs to undergo Ca(2+) oscillations similar to those induced by bovine sperm extracts. The factor responsible for inducing Ca(2+) oscillations was of high molecular weight and heat- or proteinase K-labile. We show that 0.5 chicken sperm-equivalents or 1-2 Xenopus sperm-equivalents of the extracts had enough activity to trigger Ca(2+) oscillations in mouse eggs. Our findings illustrate that although Xenopus, chicken, and mammals are evolutionarily divergent species, the function of the sperm protein factor in triggering Ca(2+) oscillations in mammalian eggs appears not to be species specific in vertebrates.     

PLC zeta: a sperm-specific trigger of Ca(2+) oscillations in eggs and embryo development

Upon fertilisation by sperm, mammalian eggs are activated by a series of intracellular Ca(2+) oscillations that are essential for embryo development. The mechanism by which sperm induces this complex signalling phenomenon is unknown. One proposal is that the sperm introduces an exclusive cytosolic factor into the egg that elicits serial Ca(2+) release. The 'sperm factor' hypothesis has not been ratified because a sperm-specific protein that generates repetitive Ca(2+) transients and egg activation has not been found. We identify a novel, sperm-specific phospholipase C, PLC zeta, that triggers Ca(2+) oscillations in mouse eggs indistinguishable from those at fertilisation. PLC zeta removal from sperm extracts abolishes Ca(2+) release in eggs. Moreover, the PLC zeta content of a single sperm was sufficient to produce Ca(2+) oscillations as well as normal embryo development to blastocyst. Our results are consistent with sperm PLC zeta as the molecular trigger for development of a fertilised egg into an embryo.     

Cell cycle-coupled [Ca(2+)](i) oscillations in mouse zygotes and function of the inositol 1,4,5-trisphosphate receptor-1

Sperm entry in mammalian eggs initiates oscillations in the concentration of free calcium ([Ca(2+)](i)). In mouse eggs, oscillations start at metaphase II (MII) and conclude as the zygotes progress into interphase and commence pronuclear (PN) formation. The inositol 1,4,5-trisphosphate receptor (IP(3)R-1), which underlies the oscillations, undergoes degradation during this transition, suggesting that one or more of the eggs' Ca(2+)-releasing machinery components may be regulated in a cell cycle-dependent manner, thereby coordinating [Ca(2+)](i) responses with the cell cycle. To ascertain the site(s) of interaction, we initiated oscillations at different stages of the cell cycle in zygotes with different IP(3)R-1 mass. In addition to sperm, we used two other agonists: porcine sperm factor (pSF), which stimulates production of IP(3), and adenophostin A, a non-hydrolyzable analogue of IP(3). None of the agonists tested induced oscillations at interphase, suggesting that neither decreased IP(3)R-1 mass nor lack of production or excessive IP(3) degradation can account for the insensitivity to IP(3) at this stage. Moreover, the releasable Ca(2+) content of the stores did not change by interphase, but it did decrease by first mitosis. More importantly, experiments revealed that IP(3)R-1 sensitivity and possibly IP(3) binding were altered at interphase, and our data demonstrate stage-specific IP(3)R-1 phosphorylation by M-phase kinases. Accordingly, increasing the activity of M-phase kinases restored the oscillatory-permissive state in zygotes. We therefore propose that the restriction of oscillations in mouse zygotes to the metaphase stage may be coordinated at the level of IP(3)R-1 and that this involves cell cycle stage-specific receptor phosphorylation.     

Mechanism of Ca2+ release at fertilization in mammals.

At fertilization in mammals the sperm triggers a series of oscillations in intracellular Ca2+ within the egg. These Ca2+ oscillations activate the development of the egg into an embryo. It is not known how the sperm triggers these Ca2+ oscillations. There are currently three different theories for Ca2+ signaling in eggs at fertilization. One idea is that the sperm acts as a conduit for Ca2+ entry into the egg after membrane fusion. Another idea is that the sperm acts upon plasma membrane receptors to stimulate a phospholipase C (PLC) within the egg which generates inositol 1,4, 5-trisphosphate (InsP(3)). We present a third idea that the sperm causes Ca2+ release by introducing a soluble protein factor into the egg after gamete membrane fusion. In mammals this sperm factor is also referred to as an oscillogen because, after microinjection, the factor causes sustained Ca2+ oscillations in eggs. Our recent data in sea urchin egg homogenates and intact eggs suggests that this sperm factor has phospholipase C activity that leads to the generation of InsP(3). We then present a new version of the soluble sperm factor theory of signaling at fertilization. J. Exp. Zool. (Mol. Dev. Evol.) 285:267-275, 1999.     

Starting a new life: sperm PLC-zeta mobilizes the Ca2+ signal that induces egg activation and embryo development: an essential phospholipase C with implications for male infertility

We have discovered that a single sperm protein, phospholipase C-zeta (PLCζ), can stimulate intracellular Ca(2+) signalling in the unfertilized oocyte ('egg') culminating in the initiation of embryonic development. Upon fertilization by a spermatozoon, the earliest observed signalling event in the dormant egg is a large, transient increase in free Ca(2+) concentration. The fertilized egg responds to the intracellular Ca(2+) rise by completing meiosis. In mammalian eggs, the Ca(2+) signal is delivered as a train of long-lasting cytoplasmic Ca(2+) oscillations that begin soon after gamete fusion and persist beyond the completion of meiosis. Sperm PLCζ effects Ca(2+) release from egg intracellular stores by hydrolyzing the membrane lipid PIP(2) and consequent stimulation of the inositol 1,4,5-trisphosphate (InsP(3) ) receptor Ca(2+) -signalling pathway, leading to egg activation and early embryogenesis. Recent advances have refined our understanding of how PLCζ induces Ca(2+) oscillations in the egg and also suggest its potential dysfunction as a cause of male infertility.     

Mammalian fertilization: from sperm factor to phospholipase Czeta

In mammalian eggs, the fertilizing sperm evokes intracellular Ca2+ ([Ca2+]i) oscillations that are essential for initiation of egg activation and embryonic development. Although the exact mechanism leading to initiation of [Ca2+]i oscillations still remains unclear, accumulating studies suggest that a presently unknown substance, termed sperm factor (SF), is delivered from the fertilizing sperm into the ooplasm and triggers [Ca2+]i oscillations. Based on findings showing that production of inositol 1,4,5-trisphosphate (IP3) underlies the generation of [Ca2+]i oscillations, it has been suggested that SF functions either as a phospholipase C (PLC), an enzyme that catalyzes the generation of IP3, or as an activator of a PLC(s) pre-existing in the egg. This review discusses the role of SF as the molecule responsible for the production of IP3 and the initiator of [Ca2+]i oscillations in mammalian fertilization, with particular emphasis on the possible involvement of egg- and sperm-derived PLCs, including PLCzeta, a novel sperm specific PLC.     

Transgenic RNA interference reveals role for mouse sperm phospholipase Czeta in triggering Ca2+ oscillations during fertilization

A sperm-specific phospholipase (PL) C, termed PLCzeta, is proposed to be the soluble sperm factor that induces Ca(2+) oscillations in mammalian eggs and, thus, initiates egg activation in vivo. We report that sperm from transgenic mice expressing short hairpin RNAs targeting PLCzeta mRNA have reduced amounts of PLCzeta protein. Sperm derived from these transgenic mice trigger patterns of Ca(2+) oscillations following fertilization in vitro that terminate prematurely. Consistent with the perturbation in patterns of Ca(2+) oscillations is the finding that mating of transgenic founder males to females results in lower rates of egg activation and no transgenic offspring. These data strongly suggest that PLCzeta is the physiological trigger of Ca(2+) oscillations required for activation of development.     

Human glucosamine-6-phosphate isomerase, a homologue of hamster oscillin, does not appear to be involved in Ca2+ release in mammalian oocytes

Injections of cytosolic preparations from mammalian sperm into oocytes have been shown to trigger calcium [Ca2+]i oscillations and initiate activation of development. Recently, a protein isolated from hamster sperm has been suggested to be involved in the generation of these oscillations and it was named "oscillin." The human homologue of hamster oscillin is glucosamine 6-phosphate isomerase (GPI, EC no. 5.3.1.10), an enzyme so far described to be involved in hexose phosphate metabolism. To assess the role of GPI on Ca2+ signaling, a human recombinant protein was generated in a prokaryotic system and injected into fura-2-dextran-loaded metaphase II (MII) mouse oocytes. Injection of recombinant GPI failed to induce Ca2+ responses in 12/12 injected MII oocytes despite the fact that the recombinant GPI was active as assessed by an enzymatic assay. Injection of buffer (0/6 oocytes) or fructose-6-phosphate, a product of GPI enzymatic reaction (0/5 oocytes), also failed to initiate Ca2+ responses. Conversely, injections of sperm cytosolic factor induced [Ca2+]i oscillations in all 17/17 oocytes. In addition, injection of recombinant GPI or GPI mRNA failed to induce parthenogenetic activation (0/30 oocytes). Immunofluorescence studies using an anti-GPI polyclonal antibody (GK) resulted in localization of GPI to the sperm's equatorial region. Incubation of the GK antibody with sperm extracts failed to block the [Ca2+]i responses induced by these extracts. Moreover, near complete depletion of GPI from sperm fractions by immunoprecipitation did not impair the ability of these fractions to induce [Ca2+]i oscillations. In summary, our results support the role of a sperm cytosolic component(s) in the generation of [Ca2+]i oscillations during mammalian fertilization, although a protein other than GPI/oscillin is likely to be the active calcium releasing factor.     

Mammalian sperm contain a Ca(2+)-sensitive phospholipase C activity that can generate InsP(3) from PIP(2) associated with intracellular organelles

We have previously described a phospholipase C (PLC) activity in mammalian sperm cytosolic extracts. Here we have examined the Ca(2+) dependency of the enzyme, whether there is enough in a single sperm to account for Ca(2+) release at fertilization, and finally where in the egg is the phosphatidyl 4,5-bisphosphate, the substrate for the enzyme. As for all PLCs examined so far in vitro, we found that the boar sperm PLC activity was Ca(2+) dependent. Specific activity increased when free Ca(2+) levels were micromolar. However, even at nanomolar free Ca(2+) concentration the boar sperm PLC activity was considerable, being two orders of magnitude greater than PLC activities in other tissues. We calculated that PLC activity of a single boar sperm in a mammalian egg is enough to generate 400 nM inositol 1,4,5-trisphosphate (InsP(3)) in 1 min, which may be sufficient to account for the observed Ca(2+) changes in an egg at fertilization. We fractionated sea urchin egg homogenate and examined the ability of boar sperm extract to generate InsP(3) from these fractions. The sperm PLC activity triggered InsP(3) production from a PIP(2)-enriched nonmicrosomal egg compartment that contained yolk platelets. We propose that this sperm PLC activity, which is active at nanomolar Ca(2+) levels and hydrolyzes PIP(2) from intracellular membranes, could be involved in the Ca(2+) changes observed at fertilization.     

The dynamics of calcium oscillations that activate mammalian eggs

It has been known for some time that mammalian eggs are activated by a series of intracellular calcium oscillations that occur shortly after sperm egg membrane fusion. Recent work has identified a novel sperm specific phospholipase C zeta as the likely agent that stimulates the calcium oscillations in eggs after sperm-egg membrane fusion. PLCzeta is stimulated by low intracellular calcium levels in a manner which suggests that there is a regenerative feedback of calcium release and PLCzeta induced inositol 1,4,5-trisphophate (InsP(3)) production in eggs. This implies calcium oscillations in fertilizing mammalian eggs are driven by underlying oscillations of InsP(3). This model of oscillations is supported by the response of mouse eggs to sudden increases in InsP(3). The cellular targets of calcium oscillations include calmodulin-dependent protein kinases, protein kinase C and mitochondria. There is evidence that eggs might be best activated by multiple calcium increases rather than a single calcium rise. As yet we do not fully understand how the target of calcium in a mammalian egg might decode the patterns of calcium changes that can occur during egg activation.     

PLCzeta(zeta): a sperm protein that triggers Ca2+ oscillations and egg activation in mammals

At fertilization in mammals, the sperm activates development by causing a prolonged series of intracellular Ca(2+) oscillations that are generated by increased production of inositol trisphosphate (InsP(3)). It appears that the sperm initiates InsP(3) generation via the introduction of a sperm factor into the egg after gamete membrane fusion. We recently identified a sperm-specific form of phospholipase C (PLC), referred to as PLCzeta(zeta). We review the evidence that PLCzeta represents the sperm factor that activates development of the egg and discuss the characteristics of PLCzeta that distinguish it from the somatic forms of PLC.     

Activation of development in mammals: is there a role for a sperm cytosolic factor?

In mammalian oocytes, fertilization-associated calcium [Ca2+]i oscillations are responsible for the activation of development. The mechanism(s) by which the sperm triggers the initial [Ca2+]i rise and supports long-lasting oscillations is not resolved. It has been proposed that the sperm may interact with receptors in the oocyte's plasma membrane and engage intracellular signaling pathways that result in Ca2+ release. A different line of investigation suggests that upon sperm-oocyte fusion, a sperm cytosolic factor is released into the oocyte which interacts with unknown cytosolic targets, and generates [Ca2+]i oscillations. We will discuss the most recent evidence for both lines of thought and demonstrate that injections of sperm crude extracts (SF) into mammalian oocytes trigger [Ca2+]i oscillations that support in vitro parthenogenetic development to the blastocyst stage.     

Analysis of Mn(2+)/Ca(2+) influx and release during Ca(2+) oscillations in mouse eggs injected with sperm extract

Repetitive Ca(2+) release from the endoplasmic reticulum (ER) is necessary for activation of mammalian eggs. Influx and release of Mn(2+) and Ca(2+) during Ca(2+) oscillations induced by injection of sperm extract (SE) into mouse eggs were investigated by Mn(2+)-quenching of intracellular Fura-2 after adding Mn(2+) to external medium. Mn(2+)/Ca(2+) influx was detected at the resting state. A marked Mn(2+)/Ca(2+) influx occurred during the first Ca(2+) release upon SE injection, and persistently facilitated Mn(2+)/Ca(2+) influx was observed during steady Ca(2+) oscillations. As intracellular Mn(2+) concentration ([Mn(2+)](i)) increased progressively, periodic [Mn(2+)](i) rises appeared, corresponding to each Ca(2+)transient but taking a slower time course. A numerical simulation based on continuous Mn(2+)/Ca(2+) influx-extrusion across the plasma membrane and release-uptake across the ER membrane in a competitive manner mimicked well the Mn(2+) oscillations calculated from experimental data, strongly suggesting that repetitive Mn(2+) release develops after Mn(2+) entry and uptake into the ER. In other experiments, a marked Mn(2+) influx occurred upon Mn(2+) addition to Ca(2+)-free medium after depletion of the ER using an ER Ca(2+) pump inhibitor plus repeated injection of inositol 1,4,5-trisphosphate (InsP(3)). No significant increase in Mn(2+) influx was induced by injection of SE, InsP(3), or Ca(2+), when Ca(2+) release was prevented by pre-injection of an antibody against the InsP(3) receptor. We concluded that Ca(2+) influx is activated during the initial large Ca(2+)release possibly by a capacitative mechanism and kept facilitated during steady Ca(2+) oscillations. The finding that repetitive Mn(2+) release is caused by continuous Mn(2+) entry suggests that continuous Ca(2+) influx may play a critical role in refilling the ER and, thereby, maintaining Ca(2+)oscillations in mammalian fertilization.     

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

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

Teleost fish spermatozoa contain a cytosolic protein factor that induces calcium release in sea urchin egg homogenates and triggers calcium oscillations when injected into mouse oocytes

Established studies in a variety of organisms including amphibians, fish, ascidians, nemerteans, echinoderms, mammals, and even a species of flowering plant, clearly demonstrate that an increase in intracellular egg calcium is crucial to the process of egg activation at fertilization. In echinoderms, egg activation appears to involve an egg phospholipase C gamma (PLCgamma). However, numerous studies in mammalian species suggest that calcium is released from internal egg stores at fertilization by a sperm-derived cytosolic protein factor. Recent studies in the mouse have identified this sperm-derived factor as being a novel sperm-specific PLC isoform with distinctive properties (PLCzeta). Homologues of PLCzeta have since been isolated from human and cynomolgus monkey sperm. In addition, sperm factor activity has been detected in non-mammalian species such as chicken, Xenopus, and a flowering plant. Here we report evidence for the existence of a similar sperm-derived factor in a commercially important species of teleost fish, the Nile tilapia Oreochromis niloticus (L). Using an established bioassay for calcium release, the sea urchin egg homogenate, we demonstrate that protein extracts obtained from tilapia spermatozoa exhibit PLC activity similar to that seen in mammalian sperm extracts, and also induce calcium release when added directly to the homogenate. Further, tilapia sperm extracts induced calcium oscillations when injected into mouse oocytes.     

Production of haploid-haploid chimeras by sperm injection in the sawfly,Athalia rosae (Hymenoptera)

Mature unfertilized eggs (oocytes) dissected from the ovary of the sawfly Athalia rosae (Hymenoptera) begin parthenogenetic development if exposed to distilled water and produce haploid males. Injection of sperm into mature oocytes through the anterior pole resulted in karyogamy in a fraction of cases which developed as diploid females. No haploid-haploid chimeras due to independent participation of the injected sperm in development were produced. When sperm were injected through the posterior pole, however, fertilization never occurred but haploid-haploid chimeras were produced in a smaller fraction of cases. Both egg nucleus-derived and injected sperm-derived nuclei contributed in forming the germ cells of the chimeric males.