The wave of activation current in the Xenopus egg

Ionic currents in morphogenesis

Morphogenetic fields must be generated by mechanisms based on known physical forces which include gravitational forces, mechanical forces, electrical forces, or some combination of these. While it is unrealistic to expect a single force, such as a voltage gradient, to be the sole cause of a morphogenetic event, spatial and temporal information about the electrical fields and ion concentration gradients in and around a cell or embryo undergoing morphogenesis can take us one step further toward understanding the entire morphogenetic mechanism. This is especially true because one of the handful of identified morphogens is Ca2+, an ion that will not only generate a current as it moves, but which is known to directly influence the plasma membrane's permeability to other ions, leading to other transcellular currents. It would be expected that movements of this morphogen across the plasma membrane might generate ionic currents and gradients of both electrical potential and intracellular concentration. Such ionic currents have been found to be integral components of the morphogenetic mechanism in some cases and only secondary components in other cases. My goal in this review is to discuss examples of both of these levels of involvement that have resulted from investigations conducted during the past several years, and to point to areas that are ripe for future investigation. This will include the history and theory of ionic current measurements, and a discussion of examples in both plant and animal systems in which ionic currents and intracellular concentration gradients are integral components of morphogenesis as well as cases in which they play only a secondary role. By far the strongest cases for a direct role of ionic currents in morphogenesis is the polarizing fucoid egg where the current is carried in part by Ca2+ and generates an intracellular concentration gradient of this ion that orients the outgrowth, and the insect follicle in which an intracellular voltage gradient is responsible for the polarized transport from nurse cell to oocyte. However, in most of the systems studied, the experiments to determine if the observed ionic currents are directly involved in the morphogenetic mechanism are yet to be done. Our experience with the fucoid egg and the fungal hypha of Achlya suggest that it is the change in the intracellular ion concentration resulting from the ionic current that is critical for morphogenesis.

Primary and secondary messengers in the activation of ascidian eggs

Two early events of activation in the ascidian egg, the surface contraction and the fertilization current, were studied. Ca ionophore induces contraction without generating a fertilization current, whereas microinjection of IP3 or soluble fractions of homogenized spermatozoa trigger both a contraction and a current. This suggests that the primary trigger of activation in ascidian eggs is a soluble component of spermatozoa that may be released into the egg subsequent to gamete fusion. IP3, or other intermediates in phosphoinositide metabolism, is a putative second messenger that activates fertilization channels directly (probably a Ca-independent process), and subsequently induces surface contraction by releasing Ca from intracellular stores.

Fertilization alters the spatial distribution and the density of voltage-dependent sodium current in the egg of the ascidian Boltenia villosa

The spatial distribution of voltage-dependent ionic currents was characterized in Boltenia villosa eggs before and after fertilization using two-microelectrode voltage clamp of paired animal-vegetal halves of eggs (merogones) made surgically. Major voltage-dependent conductances in the Boltenia egg are a transient inward Na current, a transient inward Ca current, and an inwardly rectifying K current. These currents were randomly distributed along the animal-vegetal axis in the unfertilized egg. When paired merogones (surgically prepared egg fragments) were made at the vegetal cap stage, 15-30 min after fertilization, Ca and K currents remained randomly distributed along the animal-vegetal axis. In contrast, the relative Na current density was found to be twofold lower in the vegetal vs the animal merogones made at the vegetal cap stage. By making pairs of merogones from unfertilized eggs and subsequently fertilizing one merogone of a pair, we showed that this change in current density ratio was due to a loss of absolute Na current density in the vegetal hemisphere shortly after fertilization. These results also show that this loss was intrinsic to the vegetal hemisphere, rather than being determined solely by the point of sperm entry. A second decrease in Na current was observed during the hour before first cleavage, 60-120 min after fertilization (M.L. Block and W.J. Moody, 1987, J. Physiol. 393, 619-634), both in fertilized eggs and in animal merogones fertilized after isolation. This second loss of Na current was not observed in vegetal merogones fertilized after isolation or in either animal or vegetal merogones made from fertilized eggs at the vegetal cap stage. Possible mechanisms for te rapid (complete by 40 min after fertilization) and the late (occurring from ca. 60 to 120 minutes after fertilization) Na current losses are discussed.

Calcium-dependent events at fertilization of the frog egg: injection of a calcium buffer blocks ion channel opening, exocytosis, and formation of pronuclei

Eggs of Xenopus laevis were injected with a calcium buffer before insemination, to examine the effect of preventing or suppressing the sperm-induced increase in intracellular calcium on the fertilization potential, exocytosis, and pronuclear formation. Microinjection of BAPTA [(1,2-bis(o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid)] at concentrations between 0.2 and 0.7 mM usually suppressed the fertilization potential to a series of transient depolarizations. The fertilization potential was completely inhibited when the final concentration of BAPTA in the egg was greater than 0.7 mM. These observations support the hypothesis that activation of the chloride conductance responsible for the fertilization potential depends on an increase in intracellular calcium. Exocytosis of cortical granules and elevation of the fertilization envelope were prevented by injecting BAPTA at concentrations greater than 0.2 mM. Injection of BAPTA to suppress the rise in calcium did not inhibit sperm entry and BAPTA-injected eggs were highly polyspermic. Examination by light and electron microscopy revealed that sperm decondensation and pronuclear formation were prevented by injection of the calcium buffer before insemination.

Electrical currents associated with rhythmic contractions of the blastoderm of the medaka, Oryzias latipes

1. We used a vibrating probe to measure extracellular electrical currents near the surface of dechorionated Oryzias latipes eggs as contraction waves moved slowly across the blastoderm. 2. Although we found no detectable current outside dechorionated embryos, we recorded large current pulses near the edge of wounds made in the surface of the blastoderm. 3. The maximum net inward current--or in some cases, the least net outward current--correlated temporally with the contraction of cells near the edge of the wound. 4. The current pulses were superimposed on steady currents of variable magnitude and polarity. 5. We discuss possible mechanisms for the initiation and propagation of the contraction wave.

Decay of the oocyte-type heat shock response of Xenopus laevis

Xenopus oocytes have a complex heat shock response. During transition of the oocyte into fertilized egg, the heat shock response undergoes several qualitative and quantitative changes culminating in its complete extinction. Heat shock induces oocytes to synthesize four heat shock proteins (hsps): 83, 76, 70, and 57. After ovulation, two additional proteins (hsps 22 and 16) are inducible. The heat shock response of spawned eggs can be modified by changing the ionic configuration of the external medium and by adding pyruvate and oxaloacetate to the media. Since Xenopus eggs do not synthesize mRNA, these modifications to the external medium apparently alter the utilization of preexisting messenger RNAs in protein synthesis. Artificial activation terminates inducibility of hsps 76, 57, and 16 and diminishes the hsp 70 response. Two new heat shock proteins-66 and 48-are also inducible in artificially activated eggs. Fertilization, on the other hand, terminates the heat shock response; no hsps can be induced. However, hsp 70 appears to be made constitutively in fertilized eggs. RNA blot analyses reveal that oogenic hsp 70 messenger RNA is retained in eggs and early embryos. This messenger is apparently used for heat-induced synthesis of hsp 70 before fertilization and for constitutive synthesis of hsp 70 in zygotes.

The involvement of inositol 1,4,5-trisphosphate and calcium in the two-component response to acetylcholine in Xenopus oocytes

1. The membrane response to acetylcholine (ACh), inositol 1,4,5-trisphosphate (IP3) and intracellular Ca2+ was studied in Xenopus laevis oocytes under voltage-clamp conditions. 2. Shallow, submembranal injections of IP3 in the animal hemisphere of the oocyte evoked a two-component response comprised of a rapid, transient component followed by a slow, sustained component. 3. When the injection pipette was inserted further into the cell (to 300 microns below the cell membrane), the fast component diminished and the slow component remained unchanged or even increased. 4. The rapid component exhibited an apparent higher sensitivity to IP3 compared to the slow component. 5. The two components of the IP3 response were retained in a Ca2+-free environment. 6. Injection of a single large dose (20-50 pmol) of CaCl2 into the oocyte evoked a typical two-component response, whereas repetitive threshold doses (0.1 pmol CaCl2) elicited large current fluctuations which developed into a small depolarization current. 7. The delay in the peak of the slow component of the response to either IP3 or to CaCl2 injections appeared too long to be accounted for by diffusion alone. 8. Depletion of oocyte Ca2+ by the divalent cation ionophore A23187 (greater than 1 microM) inhibited the response to ACh and IP3. Low concentrations of A23187 selectively inhibited the rapid component of the ACh response, though not the rapid component of the IP3 response. 9. Our data suggest that the two-component membrane response to ACh in Xenopus oocytes can be accounted for by ACh-induced elevation of IP3 and subsequent IP3-induced release of intracellular Ca2+.

Fertilization channels in ascidian eggs are not activated by Ca

Using the whole-cell voltage clamp technique, experiments were carried out on ascidian eggs to determine the role of intracellular Ca in the gating of fertilization channels. Raising the level of Ca by adding Ca to the intracellular perfusion medium or by loading the egg cortex (greater than 50 microM) with Ca through voltage gated channels did not lead to the activation of fertilization channels. Alternatively, eggs exposed to low-Ca seawater, perfused with the chelator K-EGTA or Ca channel blocking agents to prevent the release of Ca from intracellular organelles, and subsequently inseminated generated fertilization currents. This argues against Ca as a second messenger in the activation of fertilization channels in the ascidian egg and alternative mechanisms are discussed.

The spike component of the fertilization potential in the toad, Bufo japonicus: changes during meiotic maturation and absence during cross-fertilization

Immature oocytes of the toad, Bufo japonicus, inseminated between first- and second-meiotic metaphase, exhibited polyspermy. Monospermy occurred when the oocytes had reached second-meiotic metaphase. Electrical recording during insemination of the immature oocyte showed fast-rising and slow-rising spikes followed by a gradual shift to a positive membrane potential. The number of fast spikes in each oocyte corresponded well with the number of sperm observed in cytological sections. Mature oocytes elicited one fast spike followed by a rapid rise to a positive plateau. Ion-substitution experiments indicated that, like the plateau, the initial fast spike is mediated mainly by increased permeability of the oocyte plasma membrane to halides such as Cl- or I-. When inseminated with sperm of the newt, Cynops pyrrhogaster, mature Bufo oocytes exhibited polyspermy accompanied by a gradual hyperpolarization and a slowly developing positive plateau, without the fast spike that occurs in self-species fertilization. These results indicated that the spike component of the fertilization potential can be dissociated from the plateau component, and may be elicited by different mechanisms.

The wave of activation current in the egg of the medaka fish

An extracellular vibrating electrode was used to measure the ring-shaped wave of inward current, the activation current, that propagates at 10 micron/sec across the egg of the medaka fish, Oryzias latipes, from the site of sperm-egg fusion at the animal pole to the vegetal pole. This activation wave is due to a localized increase in the conductance to Na+, K+, and Ca2+ and reflects the propagated opening of these ion channels. The earliest detectable current begins to enter the animal pole 20 sec after the initiation of the fertilization potential, so the first ion movements responsible for the fertilization potential are below the resolution of the vibrating probe system. These channels are present in both the animal and vegetal hemispheres, but the magnitude of the activation current is about seven times greater in the animal hemisphere. An outward current of smaller magnitude and spread out over a larger area precedes and follows the inward current except at the point of fertilization where the current is first inward. The current direction is dependent on the external Na+ concentration, and in the more physiological solution of 10% NaCl-Yamamoto's Ringer's, its direction reverses to become outward, apparently carried by K+ efflux. Raising the external Ca2+ in this same low-Na+ medium reverses the current so that it becomes inward again and increases the propagation velocity of the wave, suggesting a Ca2+ component to the inward current. Current enters a given region on the egg's surface about 16 sec before any vesicle fusion occurs in that region. Iontophoresis of inositol-1,4,5,-trisphosphate immediately triggers egg activation with a minimum activating charge of 0.6 nC.

Further characterization of the slow muscarinic responses in Xenopus oocytes

In immature follicular oocytes of the frog Xenopus laevis, application of muscarinic agonists evokes a complex response consisting of a fast and a slow Cl currents (the dominant responses), Cl current fluctuations, and a less prominent slow K current. The characteristics of the slow ACh-evoked potassium current were studied using the two-electrode voltage clamp method, and compared to those of the ACh-evoked Cl currents. In experiments designed to study the K current response separately, without the interference of ACh-evoked Cl currents, the holding potential was set close or equal to Cl equilibrium potential (measured as the reversal potential of the ACh-evoked Cl current). The Cl current responses were studied in cells that had negligible K current response. The dose-response curve of the potassium response followed classical Michaelis-Menten kinetics. The dose-response characteristics of the slow ACh-evoked Cl current displayed a positive cooperativity of at least 3. In spite of this difference, kinetic analysis revealed that these two responses, as well as the fast Cl current response that was characterized earlier (Dascal and Landau 1982), had almost identical apparent equilibrium dissociation constants (0.29-0.39 microM), suggesting involvement of a single receptor class. Both K and Cl currents were reduced (to 32-56% of control) by millimolar concentrations of phosphodiesterase (PDE) inhibitors, theophylline and isobutylmethylxanthine. Elevation of extracellular Ca concentration from 1 to 10 mM doubled the K current; depletion of external Ca caused a partial inhibition of this response. The K current was potentiated by 0.1 microM 4-phorbol 12,13-dibutyrate (PDBu).(ABSTRACT TRUNCATED AT 250 WORDS)

A rise in cytosolic calcium is not necessary for maturation of Xenopus laevis oocytes

Cytoplasmic free calcium levels during progesterone-induced meiotic maturation in Xenopus laevis oocytes were measured using the photoprotein aequorin. The resting level of [Ca2+]i was 92.6 +/- 30 nM. No significant changes were observed after progesterone addition, although a large pulse of [Ca2+]i was observed upon activation of matured oocytes. These findings are discussed in terms of the role of calcium in maturation and it is concluded that calcium is not the second messenger for progesterone. This conclusion is further supported by the finding that 100 microM TMB-8, a blocker of intracellular calcium release, had no effect on progesterone-induced maturation.

Loss of functional sperm entry into Xenopus eggs after activation correlates with a reduction in surface adhesivity

In Xenopus, the plasma membrane of the unactivated egg is receptive to sperm only in the animal hemisphere (R. Grey, M. Bastiani, D. Webb, and E. Schertel, 1982, Dev. Biol. 89, 475-487). The reinsemination experiments of investment-free eggs reported in this paper demonstrate that functional sperm entry is lost after activation. Supernumerary sperm were excluded even though the fertilization envelope was absent and the membrane potential had returned to the level found in the unfertilized egg. Even when the electrical block to polyspermy was suppressed by 40 mM NaI (which reduces the membrane potential), polyspermy could be induced only if denuded eggs were initially inseminated in this medium. We estimate that the loss of functional sperm entry, independent of the electrical block, occurs during the first 10 min following fertilization. Sperm readily adhere to the surface of the animal hemisphere of unactivated eggs divested of their extracellular coats, but they do not adhere to the surface of activated eggs. Denuded eggs also adhere to each other, with the surface of the animal hemisphere of unactivated eggs exhibiting the greatest degree of adhesivity. We used electric field-induced fusion (EFIF), without prior dielectrophoresis, to quantify the regional and temporal adhesiveness of eggs. At electric field strengths greater than 8 V/cm, the probability of fusion during EFIF is highest with the animal hemisphere of unactivated eggs, moderate with both the vegetal hemisphere of unactivated eggs and the animal hemisphere of activated eggs, and lowest with the vegetal hemisphere of activated eggs. When pairs of eggs are constructed with different hemispheres in contact, the fusion characteristics of the pair are similar to the more adhesive member of the pair. The regional and temporal differences in the adhesiveness of the Xenopus egg surface correlate with its receptivity to sperm and could possibly account for the plasma membrane's activation-induced loss of functional sperm entry.

Cortical activity in vertebrate eggs. I: The activation waves

We present a physical model for the propagation of chemical and mechanical waves on the surface of vertebrate eggs. As a first step we analyzed the propagation of the calcium wave observed to sweep over the surface of the Medaka egg (Gilkey et al., 1978). It has been assumed that this wave is driven by a mechanism of calcium-stimulated-calcium-release. By formulating this hypothesis mathematically we can use the observed wavefront data to obtain a map of cortical reactivity. This map indicates a gradient of reactivity along the egg: highest in the animal hemisphere and tapering off towards the vegetal hemisphere. The cortex of Xenopus eggs is also capable of propagating a calcium wave (Busa & Nuccitelli, 1985). At about the same time a wave of expansion followed by a wave of contraction sweeps across the egg surface (Takeichi et al., 1984). We have proposed a mechanism for this wave pair based on the physical chemistry of actomyosin gels. The calcium wave activates solation factors which sever some of the actin chains which leads to an osmotic swelling of the gel. Calcium also activates the contractile machinery of the actomyosin system which causes the gel to contract. The contraction lags the swelling because of the nature of the kinetics: solation and swelling is a more rapid process than contraction. By writing the equations for gel expansion and contraction we can mimic the mechanical and chemical wave propagation by a computer simulation. If the model is correct this provides a method for using the waves as a diagnostic of the mechanochemical properties of the egg cortex.

The use of Xenopus oocytes for the study of ion channels

Recently, in addition to the "traditional" research on meiotic reinitiation and fertilization mechanisms, the oocytes of the African frog Xenopus laevis have been exploited for the study of numerous aspects of ion channel function and regulation, such as the properties of several endogenous voltage-dependent channels and the involvement of second messengers in mediation of neurotransmitter-evoked membrane responses. In addition, injection of these cells with exogenous messenger RNA results in production and functional expression of foreign membranal proteins, including various voltage- and neurotransmitter-operated ion channels originating from brain, heart, and other excitable tissues. This method provides unique opportunities for the study of the structure, function, and regulation of these channels. A multidisciplinary approach is required, involving molecular biology, electrophysiology, biochemistry, pharmacology, and cytology.

A calcium-activated sodium conductance contributes to the fertilization potential in the egg of the nemertean worm Cerebratulus lacteus

The fertilization potential of the egg of the nemertean worm Cerebratulus lacteus consisted of a rapid shift from a resting potential of about -65 mV to a peak of about +44 mV; the peak was followed by a positive plateau at about +24 mV, lasting an average of 80 min. Reduction of extracellular calcium reduced the peak of the fertilization potential, indicating that the peak resulted from a calcium conductance, while reduction of extracellular sodium reduced the plateau potential, indicating that the plateau resulted from a sodium conductance. Microinjection of ethylene glycol bis(beta-aminoethyl ether)-N,N'-tetraacetic acid (EGTA) or 1,2-bis(o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA)/CaBAPTA buffers, having a free calcium concentration of less than or equal to about 0.1 microM lowered the fertilization potential plateau. Injection of a BAPTA/CaBAPTA mixture with a free calcium concentration of about 1 microM resulted in a prolonged positive potential at the level of the fertilization potential plateau. These observations indicated that the fertilization potential of the Cerebratulus egg depended on a calcium-activated sodium conductance. The plateau potential was reduced little, if any, when calcium-free seawater was perfused through the bath during the fertilization potential; nor was it reduced in seawater containing cadmium. These observations suggested the possibility that intracellular calcium stores could be important in producing the fertilization potential.