Development of ion channels in early embryos

Zebrafish Embryos Display Characteristic Bioelectric Signals during Early Development

Bioelectricity is defined as endogenous electrical signaling mediated by the dynamic distribution of charged molecules. Recently, increasing evidence has revealed that cellular bioelectric signaling is critical for regulating embryonic development, regeneration, and congenital diseases. However, systematic real-time in vivo dynamic electrical activity monitoring of whole organisms has been limited, mainly due to the lack of a suitable model system and voltage measurement tools for in vivo biology. Here, we addressed this gap by utilizing a genetically stable zebrafish line, Tg (ubiquitin: ASAP1), and ASAP1 (Accelerated sensor of action potentials 1), a genetically encoded voltage indicator (GEVI). With light-sheet microscopy, we systematically investigated cell membrane potential (Vm) signals during different embryonic stages. We found cells of zebrafish embryos showed local membrane hyperpolarization at the cleavage furrows during the cleavage period of embryogenesis. This signal appeared before cytokinesis and fluctuated as it progressed. In contrast, whole-cell transient hyperpolarization was observed during the blastula and gastrula stages. These signals were generally limited to the superficial blastomere, but they could be detected within the deeper cells during the gastrulation period. Moreover, the zebrafish embryos exhibit tissue-level cell Vm signals during the segmentation period. Middle-aged somites had strong and dynamic Vm fluctuations starting at about the 12-somite stage. These embryonic stage-specific characteristic cellular bioelectric signals suggest that they might play a diverse role in zebrafish embryogenesis that could underlie human congenital diseases.

The genetic factors of bilaterian evolution

The Cambrian explosion was a unique animal radiation ~540 million years ago that produced the full range of body plans across bilaterians. The genetic mechanisms underlying these events are unknown, leaving a fundamental question in evolutionary biology unanswered. Using large-scale comparative genomics and advanced orthology evaluation techniques, we identified 157 bilaterian-specific genes. They include the entire Nodal pathway, a key regulator of mesoderm development and left-right axis specification; components for nervous system development, including a suite of G-protein-coupled receptors that control physiology and behaviour, the Robo-Slit midline repulsion system, and the neurotrophin signalling system; a high number of zinc finger transcription factors; and novel factors that previously escaped attention. Contradicting the current view, our study reveals that genes with bilaterian origin are robustly associated with key features in extant bilaterians, suggesting a causal relationship.

Large conductance voltage- and calcium-gated potassium channels (BK) in cerebral artery myocytes of perinatal fetal primates share several major characteristics with the adult phenotype

Large conductance voltage- and calcium-gated channels (BK) control fundamental processes, including smooth muscle contractility and artery diameter. We used a baboon (Papio spp) model of pregnancy that is similar to that of humans to characterize BK channels in the middle cerebral artery and its branches in near-term (165 dGa) primate fetuses and corresponding pregnant mothers. In cell-attached patches (K+pipette = 135 mM) on freshly isolated fetal cerebral artery myocytes, BK currents were identified by large conductance, and voltage- and paxilline-sensitive effects. Their calcium sensitivity was confirmed by a lower Vhalf (transmembrane voltage needed to reach half-maximal current) in inside-out patches at 30 versus 3 μM [Ca2+]free. Immunostaining against the BK channel-forming alpha subunit revealed qualitatively similar levels of BK alpha protein-corresponding fluorescence in fetal and maternal myocytes. Fetal and maternal BK currents recorded at 3 μM [Ca2+]free from excised membrane patches had similar unitary current amplitude, and Vhalf. However, subtle differences between fetal and maternal BK channel phenotypes were detected in macroscopic current activation kinetics. To assess BK function at the organ level, fetal and maternal artery branches were pressurized in vitro at 30 mmHg and probed with the selective BK channel blocker paxilline (1 μM). The degree of paxilline-induced constriction was similar in fetal and maternal arteries, yet the constriction of maternal arteries was achieved sooner. In conclusion, we present a first identification and characterization of fetal cerebral artery BK channels in myocytes from primates. Although differences in BK channels between fetal and maternal arteries exist, the similarities reported herein advance the idea that vascular myocyte BK channels are functional near-term, and thus may serve as pharmacological targets during the perinatal-neonatal period.

Ion currents in embryo development

Ion channels are proteins expressed in the plasma membrane of electrogenic cells. In the zygote and blastomeres of the developing embryo, electrical modifications result from ion currents that flow through these channels. This phenomenon implies that ion current activity exerts a specific developmental function, and plays a crucial role in signal transduction and the control of embryogenesis, from the early cleavage stages and during growth and development of the embryo. This review describes the involvement of ion currents in early embryo development, from marine invertebrates to human, focusing on the occurrence, modulation, and dynamic role of ion fluxes taking place on the zygote and blastomere plasma membrane, and at the intercellular communication between embryo cell stages.

GABAergic and glycinergic interneuron expression during spinal cord development: dynamic interplay between inhibition and excitation in the control of ventral network outputs

A key objective of neuroscience research is to understand the processes leading to mature neural circuitries in the central nervous system (CNS) that enable the control of different behaviours. During development, network-constitutive neurons undergo dramatic rearrangements, involving their intrinsic properties, such as the blend of ion channels governing their firing activity, and their synaptic interactions. The spinal cord is no exception to this rule; in fact, in the ventral horn the maturation of motor networks into functional circuits is a complex process where several mechanisms cooperate to achieve the development of motor control. Elucidating such a process is crucial in identifying neurons more vulnerable to degenerative or traumatic diseases or in developing new strategies aimed at rebuilding damaged tissue. The focus of this review is on recent advances in understanding the spatio-temporal expression of the glycinergic/GABAergic system and on the contribution of this system to early network function and to motor pattern transformation along with spinal maturation. During antenatal development, the operation of mammalian spinal networks strongly depends on the activity of glycinergic/GABAergic neurons, whose action is often excitatory until shortly before birth when locomotor networks acquire the ability to generate alternating motor commands between flexor and extensor motor neurons. At this late stage of prenatal development, GABA-mediated excitation is replaced by synaptic inhibition mediated by glycine and/or GABA. At this stage of spinal maturation, the large majority of GABAergic neurons are located in the dorsal horn. We propose that elucidating the role of inhibitory systems in development will improve our knowledge on the processes regulating spinal cord maturation.

Cellular magnesium acquisition: an anomaly in embryonic cation homeostasis

The intracellular dominance of magnesium ion makes clinical assessment difficult despite the critical role of Mg(++) in many key functions of cells and enzymes. There is general consensus that serum Mg(++) levels are not representative of the growing number of conditions for which magnesium is known to be important. There is no consensus method or sample source for testing for clinical purposes. High intracellular Mg(++) in vertebrate embryos results in part from interactions of cations which influence cell membrane transport systems. These are functionally competent from the earliest stages, at least transiently held over from the unfertilized ovum. Kinetic studies with radiotracer cations, osmolar variations, media lacking one or more of the four biological cations, Na(+), Mg(++), K(+), and Ca(++), and metabolic poison 0.05 mEq/L NaF, demonstrated that: (1) all four cations influence the behavior of the others, and (2) energy is required for uptake and efflux on different time scales, some against gradient. Na(+) uptake is energy dependent against an efflux gradient. The rate of K(+) loss is equal with or without fluoride, suggesting a lack of an energy requirement at these stages. Ca(++) efflux took twice as long in the presence of fluoride, likely due in part to intracellular binding. Mg(++) is anomalous in that early teleost vertebrate embryos have an intracellular content exceeding the surrounding sea water, an isolated unaffected yolk compartment, and a clear requirement for energy for both uptake and efflux. The physiological, pathological, and therapeutic roles of magnesium are poorly understood. This will change: (1) when (28)Mg is once again generally available at a reasonable cost for both basic research and clinical assessment, and (2) when serum or plasma levels are determined simultaneously with intracellular values, preferably as part of complete four cation profiles. Atomic absorption spectrophotometry, energy-dispersive x-ray analysis, and inductively coupled plasma emission spectroscopy on sublingual mucosal and peripheral blood samples are potential methods of value for coordinated assessments.

Cell Renewing in Neuroblastoma: Electrophysiological and Immunocytochemical Characterization of Stem Cells and Derivatives

We explored the stem cell compartment of the SH-SY5Y neuroblastoma (NB) clone and its development by a novel approach, integrating clonal and immunocytochemical investigations with patch-clamp measurements of ion currents simultaneously expressed on single cells. The currents selected were the triad IHERG, IKDR, INa, normally expressed at varying mutual ratios during development of neural crest stem cells, from which NB derives upon neoplastic transformation. These ratios could be used as electrophysiological clusters of differentiation (ECDs), identifying otherwise indistinguishable stages in maturation. Subcloning procedures allowed the isolation of highly clonogenic substrate-adherent (S-type) cells that proved to be p75- and nestinpositive and were characterized by a nude electrophysiological profile (ECDS0). These cells expressed negligible levels of the triad and manifested the capacity of generating the two following lineages: first, a terminally differentiating, smooth muscular lineage, positive for calponin and smooth muscle actin, whose electrophysiological profile is characterized by a progressive diminution of IHERG, the increase of IKDR and INa, and the acquisition of IKIR (ECDS2); second, a neuronal abortive pathway (NF-68 positive), characterized by a variable expression of IHERG and IKDR and a low expression of INa (ECDNS). This population manifested a vigorous amplification, monopolizing the stem cell compartment at the expense of the smooth muscular lineage to such an extent that neuronal-like (N-type) cells must be continuously removed if the latter are to develop.

Membrane currents in the oocyte of the toad Bufo arenarum

The amphibian oocyte cell model is widely used for heterologous expression of ionic channels and receptors. Little is known, however, about the physiology of oocyte cell models other than Xenopus laevis. In this study, the two-electrode voltage clamp technique was used to assess the most common electrical patterns of oocytes of the South American toad Bufo arenarum. Basal membrane resistance, resting potential, and ionic currents were determined in this cell model. The oocyte transmembrane resistance was 0.35 M(Omega), and the resting potential in normal saline was about -33 mV with a range between -20 mV and -50 mV. This is, to our knowledge, the first attempt to begin an understanding of the ion transport mechanisms of Bufo arenarum oocytes. This cell model may provide a viable alternative to the expression of ion channels, in particular those endogenously observed in Xenopus laevis oocytes.

The effect of GABA receptor ligands in experimental spina bifida occulta

BACKGROUND

The pathophysiology behind spina bifida and other neural tube defects (NTDs) is unclear. Folic acid is one variable, but other factors remain. Studies suggest that substances active at the GABA receptor may produce NTDs. To test this hypothesis pregnant rats were exposed to either the GABA a agonist muscimol (1, 2 or 4 mg/kg), the GABA a antagonist bicuculline (.5, 1, or 2 mg/kg), the GABA b agonist baclofen (15, 30, 60 mg/kg), or the GABA b antagonist hydroxysaclofen (1, 3, or 5 mg/kg) during neural tube formation. Normal saline was used as a control and valproic acid (600 mg/kg) as a positive control. The embryos were analyzed for the presence of a spina bifida like NTD.

RESULTS

After drug administration the pregnancies were allowed to proceed to the 21st day of gestation. Then embryos were removed and skeletons staining and cleared. Vertebral arch closure was measured. Results indicate that the GABAa receptor agonist muscimol, the GABAa receptor antagonist bicuculline, and the GABAb agonist baclofen produced NTDs characterized by widening of the vertebral arch. Oppositely the GABAb antagonist hydroxysaclofen produced narrowing of the vertebral arches.

CONCLUSIONS

The findings indicate that GABA a or b ligands are capable of altering neural formation. GABA may play a greater than appreciated role in neural tube formation and may be important in NTDs. The narrowing of the vertebral arch produced by the GABA b antagonist hydroxysalcofen suggests that GABA b receptor may play an undefined role in neural tube closure that differs from the GABA a receptor.

Dual video microscopic imaging of membrane potential and cytosolic calcium of immunoidentified embryonic rat cortical cells

Membrane potential (MP) and cytosolic Ca2+ (Ca2+(c)) constitute important components involved in the physiological regulation of a myriad of cell functions in eukaryotic organisms. In particular, during development of the central nervous system, both properties are thought to be important in the regulation of cell cycle, cell migration, cell differentiation, cell-cell communication, and naturally occurring cell death. However, obtaining insight into the precise relationship between these two parameters of cell function is relatively limited either by technical difficulties inherent in using electrical recordings of membrane properties in conjunction with optical imaging of single cells or by employing optical imaging of either one or another property alone. Here, we describe in detail a novel strategy to record changes in both MP and Ca2+(c) from many intact single cells in a noninvasive manner using digital video microscopy. This method involves double-loading the cells with voltage- and calcium-sensitive fluorescent indicator dyes, green oxonol, and fura-2, which can be sequentially excited with a mercury arc lamp filtered at appropriate wavelengths and their resulting emissions can be captured with an intensified charged-coupled device camera at 1-s intervals. As an example of the utility of dual-recording strategy, we present data on a distinct functional expression of excitable membrane and cytoplasmic calcium properties in proliferating and differentiating embryonic rat cerebral cortical cells.

Control of spontaneous activity during development

Electrical activity participates in the development of the nervous system and comes in two general forms. Use-dependent or experience-driven activity occurs relatively late in development, and is important in events of terminal nervous system differentiation, such as stabilization of synaptic connections. Earlier in development, activity is spontaneous, occurring independently of normal sensory input and motor output. Spontaneous activity participates in many of the initial events of axon outgrowth, pruning of synaptic connections, and maturation of neuronal signaling properties. Despite its importance, the genesis of spontaneous activity is poorly understood. What is clear is that spontaneous activity must be regulated by the patterns with which voltage- and ligand-gated ion channels develop in individual neurons. This review explores how that regulation most likely occurs.

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.

Potentiometric study of resting potential, contributing K+ channels and the onset of Na+ channel excitability in embryonic rat cortical cells

Resting membrane potential (RMP), K+ channel contribution to RMP and the development of excitability were investigated in the entire population of acutely dissociated embryonic (E) rat cortical cells over E11-22 using a voltage-sensitive fluorescent indicator dye and flow cytometry. During the period of intense proliferation (E11-13), two cell subpopulations with distinct estimated RMPs were recorded: one polarized at approximately -70 mV and the other relatively less-polarized at approximately -40 mV. Ca2+o was critical in sustaining the RMP of the majority of less-polarized cells, while the well-polarized cells were characterized by membrane potentials exhibiting a approximately Nernstian relationship between RMP and [K+]o. Analysis of these two subpopulations revealed that > 80% of less-polarized cells were proliferative, while > 90% of well-polarized cells were postmitotic. Throughout embryonic development, the disappearance of Ca2+o-sensitive, less-polarized cells correlated with the disappearance of the proliferating population, while the appearance of the K+o-sensitive, well-polarized population correlated with the appearance of terminally postmitotic neurons, immuno-identified as BrdU-, tetanus toxin+ cells. Differentiating neurons were estimated to contain increased K+i relative to less-polarized cells, coinciding with the developmental expression of Cs+/Ba2+-sensitive and Ca2+-dependent K+ channels. Both K+ channels contributed to the RMP of well-polarized cells, which became more negative toward the end of neurogenesis. Depolarizing effects of veratridine, first observed at E11, progressively changed from Ca2+o-dependent and tetrodotoxin-insensitive to Na+o-dependent and tetrodotoxin-sensitive response by E18. The results reveal a dynamic development of RMP, contributing K+ channels and voltage-dependent Na+ channels in the developing cortex as it transforms from proliferative to primarily differentiating tissue.

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.

Asymmetrical distribution of Ca-activated Cl channels in Xenopus oocytes

Xenopus oocytes are a popular model system for studying Ca signaling. They endogenously express two kinds of Ca-activated Cl currents, I(Cl-1), and I(Cl-2). I(Cl-1) is activated by Ca released from internal stores and, with appropriate voltage protocols, by Ca influx. In contrast, I(Cl-2) activation is dependent on Ca influx. We are interested in understanding how these two different Cl channels are activated differently by Ca from different sources. One could hypothesize that these channels are activated differently because they are differentially localized near the corresponding Ca source. As an initial investigation of this hypothesis, we examined the distribution of I(Cl-1) and I(Cl-2) channels in the oocyte. We conclude that both I(Cl-1) and (Cl-2) channels are primarily localized to the animal hemisphere of the oocyte, but that capacitative Ca influx occurs over the entire oocyte membrane. Evidence supporting this view includes the following observations: 1) Injection of IP3 into the animal hemisphere produced larger and faster I(Cl-1) responses than injection into the vegetal hemisphere. 2) Exposure of the animal hemisphere to Cl-free solution almost completely abolished I(Cl-1) produced by IP3-induced release of Ca from internal stores or by capacitative Ca entry. 3) Loose macropatch recording showed that both I(Cl-1) and I(Cl-2) currents were approximately four times and approximately three times, respectively, more dense in the animal than in the vegetal hemisphere. 4) Confocal imaging of oocytes loaded with fluorescent Ca-sensitive dyes showed that the time course of activation of I(Cl-1) corresponded to the appearance of the wave of Ca release at the animal pole. 5) Ca release and Ca influx, although twofold higher in the animal pole, were evident over the entire oocyte.

HERG- and IRK-like inward rectifier currents are sequentially expressed during neuronal development of neural crest cells and their derivatives

Quail neural crest cells were cultured in a differentiative medium to study the inward K+ channel profile in neuronal precursors at various stages of maturation. Between 12 and 24 h of culture, neural crest-derived neurons displayed, in addition to the previously described outward depolarization-activated K+ currents, an inward current enhanced in high K+ medium. A biophysical and pharmacological analysis led us to conclude that this inward K+ current is identical to that previously demonstrated in mouse and human neuroblastoma cell lines (I[IR]). This current (quail I[IR] or ql[IR]), which is active at membrane potentials positive to -35 mV, was blocked by Cs+ and by class III antiarrhythmic drugs, thus resembling the K+ current encoded by the human ether-a-gò-gò-related gene (HERG). At later stages of incubation (>48 h), neural crest-derived neurons underwent morphological and biochemical differentiation and expressed fast Na+ currents. At this stage the cells lost qI[IR], displaying instead a classical inward rectifier K+ (IRK) current (quail I[IRK] = qI[IRK]). This substitution was reflected in the resting potential (VREST), which became hyperpolarized by >20 mV compared with the 24 h cells. Neurons were also harvested from peripheral ganglia and other derivatives originating from the migration of neural crest cells, viz. ciliary ganglia, dorsal root ganglia, adrenal medulla and sympathetic chain ganglia. After brief culture following harvesting from young embryos, ganglionic neurons always expressed qI(IR). On the other hand, when ganglia were explanted from older embryos (7-12 days), briefly cultured neurons displayed the IRK-like current. Again, in all the above derivatives the qI(IR) substitution by qI(IRK) was accompanied by a 20 mV hyperpolarization of VREST. Together, these data indicate that the VREST of normal neuronal precursors is sequentially regulated by HERG- and IRK-like currents, suggesting that HERG-like channels mark an immature and transient stage of neuronal differentiation, probably the same stage frozen in neuroblastomas by neoplastic transformation.

Potassium current expression during prenatal corticogenesis in the rat

Using in situ patch-clamp techniques, we have studied K current expression in rat telencephalon from embryonic day 12 to 21. For cells recorded in the ventricular zone, the K current consisted of a delayed rectifier and a large-conductance calcium-activated component, and displayed little variation from embryonic day 12 to 21. Cells recorded in pial regions could be separated into two classes: radially oriented, putatively migrating cells, and cells tangentially oriented in layer I, which were assumed to be Cajal-Retzius cells. When using a voltage-clamp protocol that included a prepulse to -120 mV, Cajal-Retzius cells displayed a larger density of total K current than radial cells, and both types revealed an inactivating component (IA). The proportion of this component increased from embryonic day 18 to 21 in both cell types, although the amplitude of total K current, in the respective cell type, did not vary. This suggested a concomitant decrease in delayed rectifier current, which was verified directly with an appropriate protocol. The activation rate of the delayed rectifier current was slower for ventricular zone cells than for radial or Cajal-Retzius cells. IA was studied in Cajal-Retzius cells and displayed a strikingly negative (approximately -100 mV) voltage of half-maximal steady-state inactivation. Tetraethylammonium ions only blocked the non-inactivating component(s) of K current whereas 4-aminopyridine appeared to decrease both inactivating and non-inactivating components. The quantitative changes in K current expression are likely to underlie the overall increase in excitability of differentiating cells. On the other hand, the observation of qualitative differences among channel properties opens an interesting area of investigation into their physiological significance.

Expression of potassium channels in gerbil outer hair cells during development does not require neural induction

Mammalian outer hair cells (OHCs) contain Ca and K channels in their synaptic pole. We questioned if the ontogeny of potassium currents of OHCs depends on the neural induction of early afferent contact. By recording whole-cell currents of OHCs grown in organotypic cultures deprived of afferent innervation, we show that a Ca-activated K channel is expressed in these cells, suggesting that the ontogeny of the K channel is an intrinsic process.

Co-ordinated modulation of Ca2+ and K+ currents during ascidian muscle development

1. The development of Ca2+ and K+ currents was studied in ascidian muscle cells at twelve embryonic stages from gastrulation to the mature cell, a period of 24 h. A high degree of co-ordination occurs between the development of the inwardly rectifying K+ current (IK(IR)), which sets the resting potential, and Ca2+ and outward K+ currents, which determine action potential waveform. 2. At neurulation IK(IR), which had been present since fertilization, begins to decrease, reaching 12% of its previous density in 6 h. IK(IR) then immediately begins to increase again, reaching its previous density in another 6 h. 3. When IK(IR) begins to decrease, a high-threshold inactivating Ca2+ current and a slowly activating voltage-gated K+ current appear. 4. When IK(IR) returns to its previous density, two new currents appear: a sustained Ca2+ current with the same voltage dependence, but different conotoxin sensitivity than the inactivating Ca2+ current; and a Ca(2+)-dependent K+ current, which activates 8-10 times faster and at potentials 20-30 mV more negative than the voltage-dependent K+ current. 5. The transient downregulation of IK(IR) destabilizes the resting potential and causes spontaneous action potentials to occur. Because IK(IR) is absent when only a slowly activating high-threshold outward K+ current is present, these action potentials are long in duration. 6. The return of IK(IR) and the appearance of the rapidly activating Ca(2+)-dependent K+ current eventually terminate this activity. The action potentials of the mature cell occur only on stimulation, and are 10 times shorter in duration than those in the immature cell.

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.

Potassium inward rectifier and acetylcholine receptor channels in embryonic Xenopus muscle cells in culture

Embryonic muscle cells of the frog Xenopus laevis were isolated and grown in culture and single-channel recordings of potassium inward rectifier and acetylcholine (ACh) receptor currents were obtained from cell-attached membrane patches. Two classes of inward rectifier channels, which differed in conductance, were apparent. With 140 mM potassium chloride in the electrode, one channel class had a conductance of 28.8 +/- 3.4 pS (n = 21), and, much more infrequently, a smaller channel class with a conductance of 8.6 +/- 3.6 pS (n = 7) was recorded. Both channel classes had relatively long mean channel open times, which decreased with membrane hyperpolarization. The probability of finding a patch of membrane with an inward rectifier channel was high (66%) and many membrane patches contained more than one inward rectifier channel. The open state probability (with no applied potential) was high for both inward rectifier channel classes so that 70% of the time there was a channel open. Seventy-three percent of the membrane patches with ACh receptor channels (n = 11) also had at least one inward rectifier channel present when the patch electrode contained 0.1 mu M ACh. Inward rectifier channels were also found at 71% of the sites of high ACh receptor density (n = 14), which were identified with rhodamine-conjugated alpha-bungarotoxin. The results indicate that the density of inward rectifier channels in this embryonic skeletal muscle membrane was relatively high and includes sites of membrane that have synaptic specializations.

Distinct temporal patterns of expression of sodium channel-like immunoreactivity during the prenatal development of the monkey and cat retina

Polyclonal and monoclonal antibodies prepared against the alpha-subunit of the voltage-gated sodium channel (alpha NaCh) were used to examine the distribution of sodium channel-like immunoreactivity during the prenatal development of the cat and rhesus monkey (Macaca mulatta) retina. At all prenatal ages studied, beginning on embryonic day 29 (E29) in the cat and E52 in the monkey, both antibodies labelled optic axons. With the polyclonal antibodies, the appearance of positive cells largely mirrored the onset of their morphological maturation. Immunoreactivity appeared first in the somata of ganglion cells, and subsequently the inner plexiform layer could be distinguished by its intense immunolabelling. A few weeks later horizontal cells displayed immunolabelling that extended to their dendrites in the developing outer plexiform layer. This was followed by immunoreactive cones, with bipolar cells labelled only postnatally. By contrast, with the monoclonal antibody some cells were found to be immunoreactive while their somata were still in the ventricular layer (E33 in cat and E52 in monkey). Many of these cells appeared to migrate to the outer portion of the prospective inner nuclear layer, where they gradually acquired the morphological appearance of bipolar cells. Transient expression of immunolabelling with monoclonal sodium channel antibody was found in the cones of the cat and cones and rods of the monkey. These results indicate that different types of alpha NaCh-like proteins are expressed in the mammalian retina at distinct developmental periods. Their presence at very early stages during development suggests that these proteins could play a specific role in the commitment and/or differentiation of specific retinal cell types.

Neural expression of a sodium channel gene requires cell-specific interactions

In the protochordate Halocynthia roretzi, voltage-activated sodium current undergoes a change in kinetics within 48 hr of fertilization. Molecular cloning and microinjection of antisense DNA into single cells suggest that the kinetic changes are due to the increased expression of a putative neural-specific sodium channel gene, TuNa I. TuNa I gene transcription is first induced in late stage gastrulae, preceding the appearance of the rapidly inactivating sodium current unique to neural cells. In cleavage-arrested and intact embryos, cell interactions between specific animal and vegetal blastomeres are required for induction of TuNa I gene expression. Our results implicate cell contact, prior to neurulation, as a mechanism for selectively activating the TuNa I gene expressed in cells of the neural lineage.

Reciprocal expression of cell-cell coupling and voltage-dependent Na current during embryogenesis of rat telencephalon

Using whole-cell patch-clamp techniques in situ (whole-tissue and tissue slices), we have studied two aspects of rat telencephalic cell development during the period of embryogenesis starting at E12. The first aspect was related to junctional coupling as revealed by low input resistance, intercellular dye spread and pharmacologic blockade. Coupling appeared to decrease with time, both in extent and occurrence. The second aspect dealt with cell excitability as revealed by voltage-dependent Na current (INa) expression. Immature action potentials and their underlying INaS were present in a small proportion of E12 cells. These currents were blocked 36% and 78% by 10(-7) M and 10(-6) M tetrodotoxin (TTX), respectively. From then onward, INaS got larger and more prevalent while no obvious changes in kinetics were observed. At E21, INaS were abolished by 10(-7) M TTX and channel density apparently was sufficient to support overshooting yet still immature action potentials.

The ascidian embryo as a prototype of vertebrate neurogenesis

Ascidian tadpole larvae, composed of only about 2500 cells, have a primitive nervous system which is derived from the neural plate. The stereotyped cell cleavage pattern and well characterized cell lineage in these animals allow the isolation and culture of identified blastomeres in variable combinations. Ascidian embryos express cell-type-specific markers corresponding to their cell fates, even when cultured under cleavage-arrest by cytochalasin B. This system provides us with a unique opportunity to study the roles of cell lineage and cell contact in early neuronal differentiation in the absence of events associated with complex morphogenesis. In addition, the isolated, cleavage-arrested blastomeres are ideally suited to electrical recording, permitting the use of ionic channels as specific markers for differentiation. In the cleavage-arrested embryos, suppression of one type of K+ channel, and induction of two types of Na+ channels, occur following cell contact with the vegetal blastomere. The combination of molecular and electrophysiological analyses on this simple animal system may provide insights into the nature of the cell interactions important in early neurogenesis, both in ascidians and in vertebrates.

Cell-cycle control of a large-conductance K+ channel in mouse early embryos

There have been few investigations into the role of ion channels in mammalian early embryonic development, despite studies showing that changes in ion channel activity accompany the early embryonic development of non-mammalian species and the proliferation of mammalian cells. Here we report that a large-conductance, voltage-activated K+ channel is active in unfertilized mouse oocytes but is rarely observed in later embryos. The channel activity is linked to the cell cycle, being active throughout M and G1 phases, and switching off during the G1-to-S transition. These changes in channel activity are accompanied by corresponding shifts in membrane potential. Inactivation of the channel during S/G2 can be prevented by exposing the oocytes to dibutyryl cyclic AMP or forskolin, an activator of adenylyl cyclase. Inhibition of protein synthesis with puromycin did not prevent inactivation of the channel at the end of G1 or its subsequent reactivation at the end of G2, indicating that the channel activity is not regulated by mitosis-promoting factor or cyclins.

Symmetrical segregation of potassium channels at cytokinesis

To determine how voltage-gated ion channels segregate between sibling cells at cytokinesis, we used a whole-cell patch clamp to measure the electrophysiological phenotypes of siblings within 45 min of division. Recently born siblings in an immortalized line of embryonic retinal cells were identified as pairs of spherical cells adhering to one another. All siblings were electrically coupled when cells were simultaneously voltage clamped, whereas nonsiblings were not coupled. Twelve pairs of siblings were electrically isolated by mechanical separation so that their phenotypes could be measured independently. Cells expressed two principal membrane conductances, delayed rectifier-like (IK) and inward rectifier (IK(IR)) potassium currents. Despite qualitative and quantitative variability in IK and IK(IR) expression within the population, each cell of a given pair expressed similar steady-state current densities between -110 and +50 mV. We estimated IK(IR) slope conductance by blocking the current specifically with 5 mM Cs and calculated IK(IR) ratios in siblings and nonsiblings. Three pairs of siblings expressed IK(IR) ratios of approximately 1.2, while ratios in three pairs of adhered nonsiblings varied between 1.6 and 5.4. When currents were sampled continuously through cytokinesis by using the perforated-patch recording mode, current amplitude showed no net change within 30 min of division. Because channel number did not appear to change in siblings during this interval, parental channels were inherited by each daughter in proportion to the area of membrane received. Heterogeneity therefore arises after siblings reenter interphase and is not due to the asymmetrical segregation of channels at cytokinesis.

Regulation of potassium conductance in the cellular membrane at early embryogenesis

At the early stages of development of the fresh water fish loach (Misgurnus fossilis) the resting membrane potential (Er) of cleaving cells oscillates periodically with an amplitude of 8-12 mV. Er oscillation correlates with the cell cycle and is accompanied by changes of K+ conductivity. Two types of K(+)-selective ionic channels with conductance of approximately 70 and 25 pS in symmetrical (150 mM KCl) solution were observed in the membrane of cleaving loach embryos. 'High' conductance and 'low' conductance channels were recorded in approximately 90% and 10% of patches investigated (n = 275), respectively? The activity of 'high' conductance channels was regulated by the application of pressure to the membrane, ie these channels were stretch-activated (SA). The activity of SA channels changes dramatically during the cell-cleavage cycle. At the beginning of interphase the probability of SA channels being in the open state (P0) was minimal, while at prometaphase the probability was increased 10-100-fold. Application of ATP to the cytoplasmic inside-out patches induced a reversible elevation of stretch sensitivity of the SA channels in 50% of the patches, while the non-hydrolyzable analogue of ATP was not effective. Combined application of ATP, cAMP and cAMP-dependent protein kinase (PK) induced a reversible elevation in the SA channel activity while inhibitors of PK prevented its activating effects. Phosphatase inhibitors prolonged the activating effect of PK on SA channels. We propose that oscillations of the resting potential during the cell-cleavage cycle arise due to modulation of SA channel sensitivity to stretch through cAMP-dependent phosphorylation.