Relation of cytoplasmic alkalinization to microvillar elongation and microfilament formation in the sea urchin egg

Experiments have been carried out to test the proposal that the pH increase at fertilization in sea urchin eggs promotes microvillar elongation. Results presented herein show that microvillar elongation and microfilament formation occurred when sea urchin eggs were incubated in sodium-free seawater containing the calcium ionophore A23187, a treatment which initiates activation, i.e., induces a transient increase in intracellular free calcium, but prevents subsequent cytoplasmic alkalinization. Within elongated microvilli and cortices of these eggs, microfilaments were arranged in a loose meshwork. However, if the pH of the egg cytoplasm was increased experimentally, microfilament bundles appeared within individual microvilli. These findings suggest that: (1) microvillar elongation and microfilament formation in the sea urchin egg at fertilization may occur when cytoplasmic alkalinization is inhibited, and (2) formation of the microvillus bundle of microfilaments at egg activation is pH sensitive. Additionally, if the cytoplasmic pH of unfertilized eggs was experimentally elevated by NH₄Cl, microvilli failed to elongate. These data indicate that elevation of intracellular pH by this method is not sufficient to induce microvillar elongation.     

Spatiotemporal relationships among early events of fertilization in sea urchin eggs revealed by multiview microscopy.

Four early events of egg fertilization, changes in intracellular calcium concentration and intracellular pH, reorientation of the surface membrane, and the elevation of the fertilization envelope, were imaged in real time and in pairs in single sea urchin eggs. The paired imaging allowed the correlation of the four events spatially and temporally. Three of them propagated as waves starting at the sperm entry site. The earliest was the calcium wave, visualized with fluorescent indicator dyes. After a delay of 10 s there followed a large decrease in the fluorescence polarization of membrane-bound dyes, which we interpret as arising from membrane reorientation as a result of cortical granule exocytosis and microvillar elongation. With a further delay of 15 s the fertilization envelope was seen to rise in transmitted light. All three waves propagated with similar velocities of approximately 10 microns/s, supporting the view that calcium triggers the latter two events. The fluorescence polarization changed in two steps with a clear pause of 10-20 s in between. The second step, which also propagated as wave, reflects either further elongation of microvilli or straightening of irregular microvilli. This second step was abolished by cytochalasin B and was coincident with an increase in cytoplasmic pH, suggesting that pH-induced actin reorganization may play a role. The cytoplasmic alkalinization, imaged with a fluorescent probe, was quite different from the other events in that it took place homogeneously throughout the egg and slowly (over 100 s). Apparently, the alkalinization is not on a direct downstream pathway of calcium origin. An opposing possibility, that the alkalinization may in fact be triggered by the traveling calcium wave, is also discussed.     

Sodium-potassium exchange in sea urchin egg. II. Ionic events stimulating the Na+-K+ pump activity at fertilization

The preceding paper (Ciapa et al., 1984) provided biochemical and kinetic characterization of the Na+-K+ exchange in Paracentrotus lividus eggs. The present work is a study of the ionic events involved in the stimulation of the Na+-K+ transporter after fertilization. Fertilization in low Na+-external medium containing amiloride (0.1 mM) suppresses the stimulation of the net efflux of H+ and 86Rb uptake. Activation of eggs with the ionophore A23187 leads to stimulation of both Na+-H+ exchange and ouabain-sensitive 86Rb influx. When eggs were activated with A23187 in artificial seawater, 86Rb uptake and 24Na influx showed similar saturable kinetics with respect to the external Na+. A23187 treatment of eggs in Na+-free artificial seawater did not stimulate the Na+-K+ exchange until 10 mEq Na+ was added. Activation of eggs by NH4Cl (5 mM) stimulated 86Rb influx and Na+ exit; both fluxes were ouabain sensitive. Monensin increased cell Na+ of unfertilized eggs without any significant increase in intracellular pH: a condition in which 86Rb influx was not markedly stimulated. Addition of 10 mEq Na+ to unfertilized eggs in Na+-free artificial seawater stimulated 86Rb uptake but to a lower extent that did 10 mEq Na+ plus sperm. It is concluded that (1) the stimulation of the Na+-K+ pump at fertilization has an absolute requirement for the Na+-H+ exchange; (2) the alkalinization of eggs resulting from the acid efflux is a prerequisite for the enhancement of the Na+-K+ pump; (3) the amount of Na+ entering eggs at fertilization determines the intensity of the Na+-K+ exchange; (4) early events of fertilization such as exocytosis and calcium release which may be involved in the stimulation of the Na+-K+ pump must necessarily be coupled to cell alkalinization.     

Intracellular pH of sea urchin eggs measured by the dimethyloxazolidinedione (DMO) method

Intracellular pH (pH1) of sea urchin eggs and embryos was determined using DMO (5,5-dimethyl-2,4-oxazolidinedione). By this method, the pH1 of Lytechinus pictus eggs increased after fertilization from 6.86 to 7.27, and this higher pHi was maintained thereafter, as has been previously observed with pH microelectrodes. The same general result was obtained with the eggs of Strongylocentrotus purpuratus, in contrast to previous estimates of the pH of egg homogenates from this species, which had indicated a rise and then fall of pHi after fertilization. pHi did not significantly change during early cell divisions. Studies of treatments that alter pHi confirmed that ammonia alkalizes and acetate acidifies the cells. The regulation of pHi by embryos in the acidic seawater is impaired if sodium is absent, whereas unfertilized eggs can regulate pHi in acidic, sodium-free seawater.     

Involvement of calcium signaling and the actin cytoskeleton in the membrane block to polyspermy in mouse eggs

This study examines the effects of actin microfilament-disrupting drugs on events of fertilization, with emphasis on gamete membrane interactions. Mouse eggs, freed of their zonae pellucidae, were treated with drugs that perturb the actin cytoskeleton by different mechanisms (cytochalasin B, cytochalasin D, jasplakinolide, latrunculin B) and then inseminated. Cytochalasin B, jasplakinolide, and latrunculin B treatments resulted in a decrease in the percentage of eggs fertilized and the average number of sperm fused per egg. However, cytochalasin D treatment resulted in an increase in the average number of sperm fused per egg and the percentage of polyspermic eggs. This increase in polyspermy occurred despite the observation that cytochalasin D treatment caused a decrease in sperm-egg binding and did not affect spontaneous acrosome reactions or sperm motility. This suggested that cytochalasin D-treated eggs had an impaired ability to establish a block to polyspermy at the level of the plasma membrane. The effect of cytochalasin D on the block to polyspermy was not due to a general disruption of egg activation because sperm-induced calcium oscillations and cortical granule exocytosis were similar in cytochalasin D-treated and control eggs. However, buffering of intracellular calcium levels with the calcium chelator BAPTA-AM resulted in an increase in polyspermy. Together, these data suggest that a postfertilization decrease in egg membrane receptivity to sperm requires functions of the egg actin cytoskeleton that are disrupted by cytochalasin D. Furthermore, egg activation-associated increased intracellular calcium levels are necessary but not sufficient to affect postfertilization membrane dynamics that contribute to a membrane block to polyspermy.     

Measurement of plasma membrane and mitochondrial potentials in sea urchin sperm. Changes upon activation and induction of the acrosome reaction

The relationship between the plasma membrane potential and activation of sperm motility and respiration, or induction of the acrosome reaction, was explored in sperm of the sea urchin Strongylocentrotus purpuratus. Plasma and mitochondrial membrane potentials were estimated by measuring the uptake of [14C]thiocyanate ( [14C]SCN-) and [3H]tetraphenylphosphonium ( [3H]TPP+) in intact sperm and sperm made permeant with digitonin. Mitochondrial potentials up to-185 mV were found, consistent with data for TPP+ uptake into mitochondria from other cell types. Values for TPP+ uptake corrected for mitochondrial accumulation and estimates of SCN- uptake both indicated that the plasma membrane potential was about -30 mV for actively respiring sperm in seawater and about -60 mV for quiescent sperm in Na+-free seawater. Activation of sperm motility and respiration induced by Na+ increased the intracellular pH and caused a depolarization of both the plasma membrane and mitochondrial potentials. However, membrane potential depolarization did not occur when the activation was induced by increased extracellular pH or by the peptide speract, although activation was always linked to increased intracellular pH. The acrosome reaction, on the other hand, was always associated with sperm plasma membrane potential depolarization, whether it was induced by the physiological effector from the egg surface or by several artificial triggering regimens. Thus, activation of respiration and motility is primarily controlled by increased intracellular pH (Christen, R., Schackmann, R. W., and Shapiro, B. M. (1982) J. Biol. Chem. 257, 14881-14890), whereas the acrosome reaction also requires depolarization of the plasma membrane potential.     

Protein tyrosine kinase activity of eggs of the sea urchin Strongylocentrotus purpuratus: the regulation of its increase after fertilization

Protein tyrosine kinase activity in eggs of the sea urchin, Strongylocentrotus purpuratus, increased two- to fourfold as early as several min after fertilization at 8-10 degrees C. Artificial activation of eggs with the divalent cation ionophore, A23187, or with butyric acid induced the increase in enzyme activity. The transfer of eggs to seawater containing either no Na+ or 50 mM Na+ and 10(-4) M amiloride immediately after fertilization did not block the increases in enzyme activity. When eggs were activated with seawater containing NH4OH, enzyme activity did not increase at 1 hr after activation, although the increased activity was detected at 3 hr after activation. Increased enzyme activity also was observed in enucleated egg fragments activated with butyric acid. Puromycin and emetine, inhibitors of protein synthesis, also did not inhibit the initial increases of enzyme activity after fertilization. These results demonstrated that the increased protein tyrosine kinase activity observed after fertilization of S. purpuratus eggs can be initiated independent of various other known events such as fusion with sperm cells and protein and DNA synthesis.     

A depolarization can trigger Ca2+ uptake and the acrosome reaction when preceded by a hyperpolarization in L. pictus sea urchin sperm.

The acrosome reaction (AR) is an exocytotic event that allows sperm to recognize and fuse with the egg. In the sea urchin sperm this reaction is triggered by the outer investment of the egg, the jelly, which induces ionic movements leading to increases in intracellular Ca2+ ([Ca2+]i) and intracellular pH (pHi), a K(+)-dependent transient hyperpolarization which may involve K+ channels, and a depolarization which depends on external Ca2+. The present paper explores the role of the hyperpolarization in the triggering of the acrosome reaction. The artificial hyperpolarization of Lytechinus pictus sperm with valinomycin in K(+)-free seawater raised the pHi, caused a small increase in 45Ca2+ uptake, and triggered some AR. When the cells were depolarized with KCl (30 mM) 40-60 sec after the induced hyperpolarization, the pHi decreased and there was a significant increase in 45Ca2+ uptake, [Ca2+]i, and the AR. This waiting time was necessary in order to allow the pHi change required for the AR to occur. Thus, the jelly-induced hyperpolarization may lead to the intracellular alkalinization required to trigger the AR, and, on its own or via pHi, may regulate Ca2+ transport systems involved in this process. Because of the key role played by K+ in the triggering of the AR, the presence and characteristics of ion channels in L. pictus isolated sperm plasma membranes are being explored. Planar lipid bilayers into which these membranes were incorporated by fusion displayed 85 pS single channel transitions which were cation selective.     

High molecular weight polymers block cortical granule exocytosis in sea urchin eggs at the level of granule matrix disassembly

Recently, we have shown that high molecular weight polymers inhibit cortical granule exocytosis at total osmolalities only slightly higher than that of sea water (Whitaker, M., and J. Zimmerberg. 1987. J. Physiol. 389:527-539). In this study, we visualize the step at which this inhibition occurs. Lytechinus pictus and Strongylocentrotus purpuratus eggs were exposed to 0.8 M stachyose or 40% (wt/vol) dextran (average molecular mass of 10 kD) in artificial sea water, activated with 60 microM of the calcium ionophore A23187, and then either fixed with glutaraldehyde and embedded or quick-frozen and freeze-fractured. Stachyose (2.6 osmol/kg) appears to inhibit cortical granule exocytosis by eliciting formation of a granule-free zone (GFZ) in the egg cortex which pushes granules away from the plasma membrane thus preventing their fusion. In contrast, 40% dextran (1.58 osmol/kg) does not result in a GFZ and cortical granules undergo fusion. In some specimens, the pores joining granule and plasma membranes are relatively small; in other cases, the exocytotic pocket has been stabilized in an omega configuration and the granule matrix remains intact. These observations suggest that high molecular weight polymers block exocytosis because of their inability to enter the granule matrix: they retard the water entry that is needed for matrix dispersal.     

Activation of sea urchin eggs by inositol phosphates is independent of external calcium.

We investigated the contribution of external calcium ions to inositol phosphate-induced exocytosis in sea urchin eggs. We show that: (a) inositol phosphates activate eggs of the sea urchin species Lytechinus pictus and Lytechinus variegatus independently of external calcium ions; (b) the magnitude and duration of the inositol phosphate induced calcium changes are independent of external calcium; (c) in calcium-free seawater, increasing the volume of inositol trisphosphate solution injected decreased the extent of egg activation; (d) eggs in calcium-free sea water are more easily damaged by microinjection; microinjection of larger volumes increased leakage from eggs pre-loaded with fluorescent dye. We conclude that inositol phosphates do not require external calcium ions to activate sea urchin eggs. This is entirely consistent with their role as internal messengers at fertilization. The increased damage caused to eggs in calcium-free seawater injected with large volumes may allow the EGTA present in the seawater to enter the egg and chelate any calcium released by the inositol phosphates. This may explain the discrepancy between this and earlier reports.     

Activation of Na+-dependent transport at fertilization in the sea urchin: requirements of both an early event associated with exocytosis and a later event involving increased energy metabolism

Transport of glycine, phosphate, and thymidine has been studied in parallel in eggs and embryos of Strongylocentrotus purpuratus. Uptake of each of these substrates is shown to be sodium dependent and expressed at fertilization in this species. The data indicate that activation of unfertilized eggs by ammonia does not result in significant expression of any of these transport systems compared to fertilized eggs. Activation of unfertilized eggs by sperm or by ionophore A-23187 in seawater results in complete development of these transport systems. However, if eggs are activated by ionophore in sodium-free seawater or fertilized by sperm in complete seawater and transferred to sodium-free seawater, Na+-dependent transport does not develop. Ammonia reverses the inhibitory effect of sodium-free seawater on development of these transport systems. This reversal is sensitive to 2,4-dinitrophenol. The data suggest that transport of glycine, phosphate, and thymidine share a common mechanism of activation. Moreover, this activation requires both an early event (less than 5 min postinsemination) and a later event involving increased energy metabolism.     

Changing localizations of site-specific sperm surface antigens during sea urchin fertilization

Indirect immunofluorescence studies show that monoclonal antibody (mAb) J18/2 binds site-specifically to surface antigens localized over the acrosome and tail regions of mature Strongylocentrotus purpuratus spermatozoa. Within 5 min after induction of the acrosome reaction by exposure to egg jelly or ionophore A23187, these surface antigens become detectable over the lateral region of the head so that the entire surface of the spermatozoon is labeled. Polyspermically fertilized S. purpuratus eggs fixed at varying times after insemination and exposed to mAb J18/2 reveal that these surface antigens are quickly incorporated into the egg plasma membrane and begin to disperse as early as 1.5 min after insemination. At subsequent times, they undergo further dispersal so that by 45 min they are distributed over the entire surface of the egg. These results suggest that the sperm surface components recognized by mAb J18/2 gain the ability to disperse laterally during the acrosome reaction and proceed to do so in the egg plasma membrane after fertilization.     

Activation of amino acid uptake at fertilization in the sea urchin egg. Requirement for proton compartmentalization during cytosolic alkalosis

The comparative importance of the release of intracellular ionic calcium, Na+/H+ exchange and cytosolic alkalosis as activator signals was studied on the development of amino acid uptake at fertilization in sea urchin eggs. We show that, once stimulated, the rate of valine uptake is greatly dependent upon intracellular pH. Suppression of the Na+/H+ exchange at the time of activation, by applying ionophore (A23187) in sodium-free artificial sea water (ONaASW), inhibits the development of valine influx. This cannot be restored by a further (30 min later) alkalosis by transferring eggs into sea water. Suppressing the alkalosis in the presence of Na+/H+ exchange at fertilization by simultaneous addition of acid into sea water results in activation of the amino acid carrier which exhibits an increased rate of transport as soon as the eggs are replaced in sea water at pH 8.0. The absence of alkalosis in eggs activated in ONaASW can be counterbalanced either by adding NH4Cl 10 mM or by transfer into ASW at pH 9.0 at activation. Ammonia-treated eggs absorbed amino acid as controls, whereas eggs in sea water at pH 9.0 failed to develop a valine uptake system, suggesting that ammonia can completely replace the effect of Na+/H+ exchange. Furthermore, addition of NH4Cl immediately before fertilization conceals the Na+/H+ exchange but stimulates valine uptake as in controls. These data suggest that: the occurrence of the intracellular calcium increase alone is not sufficient for the develpment of the amino acid transport system; cell alkalinization at fertilization derives from the cytoplasmic membrane-located Na+/H+ exchange and an inward movement of protons into a cortical acidic compartment, which is discussed.     

Monoclonal antibodies to the sea urchin egg vitelline layer inhibit fertilization by blocking sperm adhesion

Thirty-one mouse hybridomas were produced against the vitelline layer (VL) of the egg of the sea urchin S. purpuratus. Ascites fluids of eight of the 31 bound to the VL surface in the high ionic strength conditions of sea water. Binding was specific to the VL, since immunofluorescence showed that the antibodies elevated from the egg surface with the fertilization envelope after activation with ionophore A23187. Antibody binding was strictly species-specific, the eggs of L. pictus showing no reaction. An immunoperoxidase surface-binding assay showed a wide range in the amount of each monoclonal antibody binding to the VL surface at saturation. All eight monoclonals inhibit fertilization by inhibiting the binding of sperm to the VL. None of the eight ascites fluids reacted with egg jelly. The inhibition of fertilization correlates positively with amount of antibody binding the egg surface. In contrast to the effects of polyclonal rabbit antisera raised against whole eggs or egg cortices, these eight monoclonal antibodies to the VL do not induce the wrinkling of the egg, the cortical granule reaction, the centering of pronuclei, or any other visual indication of metabolic activation.     

The GTP-binding protein RhoA localizes to the cortical granules of Strongylocentrotus purpuratas sea urchin egg and is secreted during fertilization

The sea urchin egg has thousands of secretory vesicles known as cortical granules. Upon fertilization, these vesicles undergo a Ca2+-dependent exocytosis. G-protein-linked mechanisms may take place during the egg activation. In somatic cells from mammals, GTP-binding proteins of the Rho family regulate a number of cellular processes, including organization of the actin cytoskeleton. We report here that a crude membrane fraction from homogenates of Strongylocentrotus purpuratus sea urchin eggs, incubated with C3 (which ADP-ribosylates specifically Rho proteins) and [32P]NAD, displayed an [32P]ADP-ribosylated protein of 25 kDa that had the following characteristics: i) identical electrophoretic mobility in SDS-PAGE gels as the [32P]ADP-ribosylated Rho from sea urchin sperm; ii) identical mobility in isoelectro focusing gels as human RhoA; iii) positive cross-reactivity by immunoblotting with an antibody against mammalian RhoA. Thus, unfertilized S. purpuratus eggs contain a mammalian RhoA-like protein. Immunocytochemical analyses indicated that RhoA was localized preferentially to the cortical granules; this was confirmed by experiments of [32P]ADP-ribosylation with C3 in isolated cortical granules. Rho was secreted and retained in the fertilization membrane after insemination or activation with A23187. It was observed that the Rho protein present in the sea urchin sperm acrosome was also secreted during the exocytotic acrosome reaction. Thus, Rho could participate in those processes related to the cortical granules, i.e., in the Ca2+-regulated exocytosis or actin reorganization that accompany the egg activation.     

Physiological responses of sea urchin eggs to stimulation by calcium ionophore A23187 analysed with protease inhibitors

Protease inhibitors were used to study certain physiological responses (secretion of the cortical granule protease, altered resceptively to sperm penetration, initiation of cell division and embryogenesis) of sea urchin eggs to stimulation by calcium ionophore A23187. Protease activity in the secretory product released from the eggs 5 min after insemination or parthenogenetic activation with ionophore was completely inhibited by soybean trypsin inhibitor (SBTI), antipain (Ap), and leupeptin (Lp). A barrier was established to prevent subsequently added sperm from penetrating (fertilizing) ionophore-activated eggs, co-incident with the elevation of the fertilization membrane. These processes were retarded by inhibitors of the cortical granule protease in ionophore-activated eggs, just as they are when eggs are initially stimulated by sperm at fertilization. A23187-activated eggs did not divide unless they had been secondarily fertilized by sperm, even if the ionophore was subsequently removed by extensive washing. However, ionophore-activated eggs that were penetrated by a single spermatozoan in SBTI developed into normal larvae under similar conditions. These results suggest that A23187 may be an incomplete parthenogenetic agent because it cannot stimulate eggs to assemble centrioles required to organize the mitotic apparatus. The centrioles are normally provided by the sperm during fertilization. A23187 may also be toxic to the eggs. Furthermore, since cortical granules are secretory organelles, the data suggest a possible functional relationship between calcium ions and protease activation in stimulus-secretion coupling in sea urchin eggs at fertilization.     

Fertilization stimulates lipid peroxidation in the sea urchin egg

Arachidonic acid is rapidly taken-up by Strongylocentrotus purpuratus eggs and eventually incorporated into cellular lipids. During the first few minutes following fertilization the arachidonic acid that has not been incorporated into other lipid forms is oxidized to a hydroxy-fatty acid. In vivo, the time of arachidonic acid conversion coincides with the transient period of increased intracellular free calcium after fertilization. In vitro, this lipid peroxidizing activity has been shown to be initiated by micromolar calcium. Taken together with the presence of Ca2+-stimulated lipase, these results suggest that calcium regulates both the release of polyunsaturated fatty acids from cellular lipids and their subsequent oxidation. The physiological function of lipid hydroxides or hydroperoxides in sea urchin fertilization is unknown. A possibility is that they may be important in regulating the many membrane permeability changes occurring within minutes after fertilization.     

Antispectrin antibodies stain the oocyte nucleus and the site of fertilization channels in the egg of Discoglossus pictus (Anura).

In Discoglossus pictus eggs, only the dimple contains ionic channels active at fertilization; in particular, chloride channels are found in the central portion of the dimple, which is also the site of sperm penetration. Moreover the dimple hosts an imposing cytoskeleton, consisting of a cortical network and bundles of microfilaments extending from the microvilli. Since spectrin cross links actin and is connected through ankyrin to anion transporters in the plasma membrane of erythrocytes as well as to anion channels in other cells, we studied, in D. pictus egg, the relationship between the localization of spectrin and the high polarization of ionic channels and cytoskeletal organization. By means of immunocytochemistry, we localized spectrin exclusively in the egg dimple. In an attempt to trace back the source of spectrin localization, we immunostained sections of D. pictus ovary and localized spectrin in the nuclei of previtellogenic oocytes, where actin is also present. Antispectrin staining remained until germinal vesicle breakdown. By contrast, a cortical localization was found only when the oocytes divided into two hemispheres and into the germinative area (GA), which, after germinal vesicle breakdown, gives rise to the dimple. At this stage the antispectrin signal was particularly strong in the GA. Using Rho-pialloidin, we also established that spectrin is generally present where F-actin is found. However, spectrin and F-actin do not have the same pattern of fluorescence. In conclusion, our data suggest that spectrin may play a role in oocyte and egg polarity. In eggs, it could be instrumental in anchoring to the cytoskeleton membrane proteins such as receptors and ionic channels, including chloride-permeable channels.     

A peptide associated with eggs causes a mobility shift in a major plasma membrane protein of spermatozoa

A peptide (resact) associated with the eggs of the sea urchin, Arbacia punctulata, which stimulates sperm respiration rates by 5-10-fold, was purified and its amino acid sequence was determined. The sequence was found to be Cys-Val-Thr-Gly-Ala-Pro-Gly-Cys-Val-Gly-Gly-Gly-Arg-Leu-NH2. The peptide was subsequently synthesized by solid phase methods, amidated at the carboxyl-terminal Leu, and shown to be identical to the isolated, native material. The peptide half-maximally stimulated A. punctulata spermatozoan respiration at 0.5 nM and half-maximally elevated cyclic GMP concentrations at 25 nM at an extracellular pH of 6.6. The increase in oxygen consumption was coupled with a stimulation of motility. However, at elevated extracellular pH (pH 8.0), resact failed to appreciably stimulate respiration while the elevations of cyclic GMP continued to occur. Resact did not cross-react with sperm cells obtained from Lytechinus pictus or Strongylocentrotus purpuratus; a peptide (speract) obtained from S. purpuratus eggs (Gly-Phe-Asp-Leu-Asn-Gly-Gly-Gly-Val-Gly) which activates S. purpuratus sperm respiration did not stimulate A. punctulata spermatozoa. Resact caused a shift in the apparent molecular weight (160,000-150,000) of a major sperm plasma membrane protein; as with cyclic GMP elevations, this response was evident at extracellular pH values of both 6.6 and 8.0. The protein exists in the cell as a phosphoprotein and 32P is released coincident with the molecular weight change. Approximately 115 nM resact caused one-half-maximal conversion of the 160,000-dalton protein after 1 min of incubation. Resact caused the apparent molecular weight conversion of the protein within 5 s and appeared to do so in an irreversible manner. The molecular weight change of the protein was also observed after the addition of monensin A (25 microM) and NH4Cl (40 mM), two agents known to elevate intracellular pH and to increase sperm respiration rates. The membrane protein appears to be the enzyme guanylate cyclase, but since concentrations of resact causing one-half-maximal conversion of the Mr = 160,000 form of the enzyme are about 250 times higher than those causing one-half-maximal stimulation of respiration, the relationship of the apparent molecular weight conversion to a subsequent physiological event remains unclear.     

Changes in intracellular acidic compartments in sea urchin eggs after activation

Acridine orange (AO) was used as a vital probe for looking at acidic intracellular compartments in sea urchin eggs. This weak base is concentrated by acidic compartments, shifting its fluorescence from green to red due to the formation of dye aggregates. Fertilization or parthenogenetic activation with ionophore A23187 resulted in the appearance of orange fluorescent granules of sizes ranging from 1 to 2 microns at the cortical region of the egg. In one species of sea urchin (Lytechinus pictus), these granules migrate inward before cell division and associate with the forming mitotic apparatus. Treatments that discharge the transmembrane pH gradient (NH4Cl, nigericin, monensin, and acidic external pH) eliminate the orange fluorescence, indicating they are acidic compartments. Spectrofluorimetric measurements showed a decrease in monomer fluorescence accompanying egg activation which is reversible by similar treatments as seen with the fluorescence microscopic observations. Stratified eggs which were subsequently fertilized had acidic granules concentrated at the centripetal pole. This allowed the electron microscopic identification of the granules and showed they are present in the unfertilized egg, although not able to concentrate the AO. Activation of eggs in the absence of Na+ prevented the cytoplasmic alkalinization and also inhibited the appearance of acidic granules. The results indicate that the internal pH rises after egg activation triggers the acidification of these granules. Their possible functions, as in intracellular pH regulation, are discussed.