The development of calcium and potassium currents during oogenesis in the starfish, Leptasterias hexactis

Ion Channel Development, Spontaneous Activity, and Activity-Dependent Development in Nerve and Muscle Cells

At specific stages of development, nerve and muscle cells generate spontaneous electrical activity that is required for normal maturation of intrinsic excitability and synaptic connectivity. The patterns of this spontaneous activity are not simply immature versions of the mature activity, but rather are highly specialized to initiate and control many aspects of neuronal development. The configuration of voltage- and ligand-gated ion channels that are expressed early in development regulate the timing and waveform of this activity. They also regulate Ca2+influx during spontaneous activity, which is the first step in triggering activity-dependent developmental programs. For these reasons, the properties of voltage- and ligand-gated ion channels expressed by developing neurons and muscle cells often differ markedly from those of adult cells. When viewed from this perspective, the reasons for complex patterns of ion channel emergence and regression during development become much clearer.

Expression of Kv1.1, a Shaker-like potassium channel, is temporally regulated in embryonic neurons and glia

Kv1.1, a Shaker-like voltage-gated potassium channel, is strongly expressed in a variety of neurons in adult rodents, in which it appears to be involved in regulating neuronal excitability. Here we show that Kv1.1 is also expressed during embryonic development in the mouse, exhibiting two transient peaks of expression around embryonic day 9.5 (E9.5) and E14.5. Using both in situ hybridization and immunocytochemistry, we have identified several cell types and tissues that express Kv1.1 RNA and protein. At E9.5, Kv1.1 RNA and protein are detected transiently in non-neuronal cells in several regions of the early CNS, including rhombomeres 3 and 5 and ventricular zones in the mesencephalon and diencephalon. At E14.5, several cell types in both the CNS and peripheral nervous system express Kv1.1, including neuronal cells (sensory ganglia and outer aspect of cerebral hemispheres) and glial cells (radial glia, satellite cells, and Schwann cell precursors). These data show that Kv1.1 is expressed transiently in a variety of neuronal and non-neuronal cells during restricted periods of embryonic development. Although the functional roles of Kv1.1 in development are not understood, the cell-specific localization and timing of expression suggest this channel may play a role in several developmental processes, including proliferation, migration, or cell-cell adhesion.

Ion channels and early development of neural cells

In this review we underscore the merits of using voltage-dependent ion channels as markers for neuronal differentiation from the early stages of uncommitted embryonic blastomeres. Furthermore, a fairly large part of the review is devoted to the descriptions of the establishment of a simple model system for neural induction derived from the cleavage-arrested eight-cell ascidian embryo by pairing a single ectodermal with a single vegetal blastomere as a competent and an inducer cell, respectively. The descriptions are focused particularly on the early developmental processes of various ion channels in neuronal and other excitable membranes observed in this extraordinarily simple system, and we compare these results with those in other significant and definable systems for neural differentiation. It is stressed that this simple system, for which most of the electronic and optical methods and various injection experiments are applicable, may be useful for future molecular physiological studies on the intracellular process of differentiation of the early embryonic cells. We have also highlighted the importance of suppressive mechanisms for cellular differentiation from the experimental results, such as epidermal commitment of the cleavage-arrested one-cell Halocynthia embryos or suppression of epidermal-specific transcription of inward rectifier channels by neural induction signals. It was suggested that reciprocal suppressive mechanisms at the transcriptional level may be one of the key processes for cellular differentiation, by which exclusivity of cell types is maintained.

The development of voltage-gated ion channels and its relation to activity-dependent development events

Spontaneous activity is an essential feature in the development of the nervous system. The patterns of activity and the waveform and ionic dependence of the action potentials that occur during such activity are fine-tuned to carry out certain developmental functions, and are therefore generally not compatible with the mature physiological function of the cell. For this reason, the patterns of ion channel development that create spontaneous activity early in the development of a given cell type are complex and not easily predicted from the mature properties of that same cell. Ion channels are often found that are specific to early stages of development, and that either are not retained in the mature cell or whose properties are greatly changed during later differentiation. The exact significance of such patterns of channel development is just now becoming clear, as we understand more about the mechanisms linking spontaneous activity to later developmental events.

Voltage-gated calcium channels in Pleurodeles oocytes: classification, modulation and functional roles

In unfertilised Pleurodeles oocytes, two distinct types of high voltage-activated Ca2+ channels are expressed: a slowly inactivating Ca2+ channel and a transient one. The first is dihydropyridine-sensitive and is referred to as the L-type Ca2+ channel. The transient channel is highly sensitive to Ni2+. Phosphorylation through protein kinases G and A facilitates and inhibits the L-type Ca2+ channel respectively. The transient type channel is insensitive to stimulation by protein kinases (A and G). The functional expression of L-type and transient Ca2+ channels is modulated by the two maturation seasons. The transient Ca2+ currents are only observed during the resting season, while the L-type current is observed either alone during the breeding season or in association with the transient current during the resting season. Moreover, the current density of the L-type Ca2+ channel is much greater during the breeding season than the resting season. Thus, the wide distribution of L-type Ca2+ channels in Pleurodeles oocytes during the two seasons suggests that the roles of these channels may be important in the regulation of the maturation process.

Meiosis reinitiation in Ruditapes philippinarum (Mollusca): involvement of L-calcium channels in the release of metaphase I block

Prophase-arrested oocytes of Ruditapes philippinarum cannot be fertilised or stimulated by excess KCl, in contrast to the situation found in other bivalve species such as Barnea and Spisula. However, these oocytes can be triggered to reinitiate meiosis following treatment by serotonin or several pharmacological agents (calcium ionophores, thapsigargin, weak bases) which promote an intracellular calcium surge. Ruditapes oocytes further arrest in metaphase I, at which stage they can be activated either by sperm or by excess KCl. This suggests that functional voltage-operated calcium channels are expressed in this species during the course of maturation. Using pharmacological tools and direct binding of specific dihydropyridines, we demonstrate that these channels are L-type calcium channels which become functional after serotonin stimulation, their number increasing before germinal vesicle breakdown. Moreover we establish that: (1) the addition of 20 microM S(-)BayK8644, an agonist of L-type calcium channels, to metaphase-arrested oocytes releases them from metaphase block; (2) incubating these oocytes with PN200-110, a potent blocker of L-type calcium channels, inhibits their activation by both excess KCl and fertilisation. Taken together these data suggest that the absence of L-type calcium channels in the membrane of prophase-arrested oocytes of Ruditapes may account for their inability to be fertilised.

Cation channels in oocytes and early states of development: a novel type of nonselective cation channel activated by adrenaline in a clonal mesoderm-like cell line (MES-1)

The expression of receptors and ion channels alters during growth, maturation, and after fertilization of oocytes reflecting functional changes. Besides voltage-dependent ion channels, oocyte membranes possess an IP3-activated cation channel mediating a prolonged Ca2+ influx. The Ca2+ is thought to be involved in maturation and fertilization. Alternatively, mono- and divalent cations can enter oocytes via stretch-activated channels. The oocyte channel population is further modified during subsequent embryogenesis, suggesting that ionic channels obviously become expressed at specific states of embryological differentiation and in tissue-specific manner. The resulting differences in functional ion channel populations of adult cells underlie the large diversity of cells and their function. Conversely, differentiation and cell proliferation themselves depend on ion transport. Ca2+ ions have been shown to play a pivotal role in these processes. Nonselective cation channels represent one possible pathway for Ca2+ entry into the cell and, therefore, might be involved in the regulation of embryological development. Undifferentiated embryonal carcinoma cells (P19), visceral endoderm-like cells (END-2), epithelioid ectoderm-like cells (EPI-7), mesoderm-like cells (MES-1), and parietal yolk sac cells (PYS-2) have been used as a model to study the expression of ionic channels during early development. In MES-1 cells a nonselective cation current was activated by adrenaline. Interestingly, the intracellular pathway for activation of these channels involved the cascade of activation of the cAMP-dependent protein kinase (PKA) resulting in protein phosphorylation. This mechanism is well known for Ca2+ channel stimulation in cardiac and skeletal muscle both originating from the mesoderm.

A review of echinoderm oogenesis

This review of the anatomical, histological, biochemical, and molecular biological literature on echinoderm oogenesis includes the entire developmental history of oocytes; from their inception to the time they become ova. This is done from a comparative perspective, with reference to members of the five extant echinoderm classes; crinoids, holothurians, asteroids, ophiuroids, and echinoids. I describe the anatomy and fine structure of the echinoderm ovary, with emphasis on both the cellular relationships of the germ line cells to the somatic cells of the inner epithelium, and on the neuromuscular systems. I review the literature on the growth of oogonia into fully formed oocytes, including the process of vitellogenesis, presenting an ultrastructural analysis of the organelles and extracellular structures found in fully formed echinoderm oocytes. Echinoderm oocyte maturation is reviewed and a description of the ultrastructural, biochemical and molecular biological changes thought to occur during this process is presented. Finally, I discuss oocyte ovulation, the severing of cellular connections between the oocyte and its surrounding somatic epithelial cells.

Activation by serotonin of starfish eggs expressing the rat serotonin 1c receptor

Starfish oocytes were injected with mRNA for the serotonin 1c receptor or with rat brain poly A+ mRNA, incubated to allow expression of the membrane protein, then matured to eggs by addition of 1-methyladenine. Applying serotonin to these eggs caused cortical granule exocytosis like that occurring at fertilization. Because the serotonin 1c receptor specifically activates a G-protein, these results provide support for the hypothesis that sperm activate eggs by way of a receptor-G-protein interaction. The starfish oocyte may be a generally useful system for expression of exogenous mRNA for membrane proteins.

Changes in voltage-dependent currents and membrane area during maturation of starfish oocytes: species differences and similarities

Full grown starfish oocytes are arrested at meiotic prophase I in the ovary. The natural hormone 1-methyladenine triggers oocyte maturation which involves meiosis reinitiation along with a variety of morphological, biochemical, and electrical changes. In studying oocytes of two species, Henricia leviuscula and Asterina miniata, using the voltage-clamp technique, we found interesting differences and similarities in the electrophysiological changes which occurred during maturation. Oocytes of both species have three major voltage-dependent currents: an inward Ca2+ current, an inwardly rectifying K+ current, and a transient outward K+ current (A-current). The Ca2+ current and the A-current were similar in the two species but the inward rectifier in Henricia had activation kinetics that were more than 10-fold slower than in Asterina. Nonetheless, all three currents were affected similarly during maturation: the inward Ca2+ currents remained constant in both species, while the two K+ currents decreased in amplitude. In Henricia the membrane surface area decreased substantially during maturation, while in Asterina it remained constant. This may be explained by the more highly infolded state of the membrane in the immature Henricia oocyte. The selective loss of K+ current followed the time course of the area decrease in Henricia, but the same percentage decrease in current occurred in Asterina without a net membrane loss.

Some properties of the membrane currents underlying the fertilization potential in sea urchin eggs

1. The ionic currents that underly the fertilization potential of sea urchin eggs were studied in Lytechinus pictus using a single-electrode voltage clamp technique. 2. In unfertilized eggs, a transient inward current was activated at membrane potentials more positive than -45 mV. The maximum amplitude of the current was 0.56 +/- 0.35 nA (mean +/- S.D., n = 33) at a membrane potential of -35 to -25 mV. 3. The amplitude of this transient inward current was decreased by reducing the external concentration of calcium ions and by substituting barium or strontium ions for calcium in the external medium. Cobalt (10-20 mM) and gadolinium (200-500 microM) ions reduced the amplitude of this current in the presence of calcium ions. 4. A transient outward current was activated in unfertilized eggs at membrane potentials more positive than -10 mV. This current inactivates with a time constant of 16 ms at a membrane potential of -9 mV and re-activates over a period of several seconds at a membrane potential of -72 mV. 5. When unfertilized eggs were treated with the calcium ionophore A23187 under voltage clamp conditions, an inward current developed. It reached a maximum 30 s after its onset and declined thereafter. By 90 s it had become constant at 10% of its peak value. 6. The inward current induced by A23187 was voltage dependent. It was maximal at -25 mV in the steady state. 7. When eggs were fertilized under voltage clamp conditions, the fertilization current, If, was recorded. At a holding potential of -50 or -70 mV If had the following characteristics: (a) an initial inward shoulder with a duration ranging from 12 to 30 s; (b) an inward current peak that was attained between 40 and 100 s after the onset of the shoulder current and declined over the next 60 s; (c) an outward current that appeared after the inward current had declined. 8. Current-voltage relations obtained during If showed that the late component of the inward current was voltage dependent. It was maximal at -25 mV in the steady state and resembled the late component of the inward current recorded in A23187-activated eggs. 9. These results indicate that the form of the action potential in unfertilized eggs is due to the activation of a transient inward current and an inactivating outward current. The sustained depolarization after fertilization is due to the activation of a voltage-dependent inward current by the increase in intracellular free calcium concentration that occurs at fertilization.

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.

Changes in sodium, calcium and potassium currents during early embryonic development of the ascidian Boltenia villosa

1. The whole-cell variation of the patch clamp was used to study ion channel properties in the unfertilized oocyte, and in surgically isolated blastomeres from 2-, 4-, and 8-cell embryos of the ascidian, Boltenia villosa. 2. The unfertilized oocyte has three major voltage-dependent currents: a transient, inward Na+ current; a transient, inward Ca2+ current; and an inwardly rectifying K+ current. 3. The total surface area of the embryo, either measured by capacitance or calculated from cell diameters, increased about 2.5-fold between fertilization and the 8-cell stage. 4. The Na+ current almost completely disappeared from the embryo by the time of first cleavage and was undetectable in any of the blastomeres at the 8-cell stage. This loss was too large to be explained by the dilution of channels in the oocyte due to newly added membrane. 5. Both the Ca2+ current and the inwardly rectifying K+ current were maintained at constant or slightly increased density through the first three cleavage cycles. This suggests that these channels are added along with new membrane during these stages. 6. No differences in mean current densities of blastomeres of different developmental fates were detected through the 8-cell stage. 7. Continuous recordings in single egg cells between fertilization and first cleavage, using two-microelectrode voltage clamp, revealed the increase in capacitance, Ca2+ current amplitude, and K+ current amplitude, and the loss of Na+ current predicted from the blastomere studies.

A calcium-activated sodium conductance produces a long-duration action potential in the egg of a nemertean worm

1. The egg of the nemertean worm Cerebratulus lacteus produced an action potential having a duration of about 9 min. We investigated the ionic conductances which accounted for this long-duration action potential. 2. The peak of the action potential was about +50 mV and depended on extracellular Ca2+, while the plateau potential was about +25 mV and depended on extracellular Na+. 3. Under voltage-clamp conditions, depolarization produced two temporally separate inward currents: a fast current which reached a peak at about 10 ms, and a slow current which took up to 1 min to reach its peak and lasted for several min. 4. The fast current was independent of extracellular Na+, but was blocked by removal of extracellular Ca2+. 5. The slow current was not seen when extracellular Na+ was replaced by choline+ or K+. 6. The slow current did not develop in Ca2+-free sea water, and was reduced to about half if Ca2+ was removed after the current had been initiated. 7. Microinjection of EGTA blocked the slow current, and reduced the action potential duration to about 1 min. 8. We concluded that a voltage-activated Ca2+ conductance produced the peak of the action potential, while a Ca2+-activated Na+ conductance produced its plateau.

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.

Hormone-induced loss of surface membrane during maturation of starfish oocytes: differential effects on potassium and calcium channels

Prior to fertilization, starfish oocytes undergo meiotic maturation, triggered by the hormone 1-methyladenine (1-MA). Maturation involves a variety of complex biochemical, morphological, and electrical changes, many of which are similar to those caused by progesterone in vertebrates. Using voltage-clamp and ultrastructural techniques to study maturation in starfish, we have discovered a novel process by which 1-MA alters the electrical properties of the oocyte. The surface area of the oocyte decreases by more than 50% during the first hour of maturation, due to the elimination of microvilli, but the calcium and potassium currents present are affected differently by the loss of membrane. The amplitudes of both the transient K current ("A-current") and the inwardly rectifying K current decrease, following the time course of the decrease in surface area, while the Ca current amplitude remains virtually unaffected, and may even increase in some oocytes. The kinetics of the currents do not change. This selective removal of K channels results in a larger and more rapidly rising action potential in the mature egg, which may aid in the fast block to polyspermy. The differential accessibility of various ion channels to mechanisms of membrane removal and insertion may play an important role in the development of excitable cells.