Characteristics of multiple Ca(2+)-activated K+ channels in acutely dissociated chick ciliary-ganglion neurones

The cellular building blocks of breathing

Respiratory brainstem neurons fulfill critical roles in controlling breathing: they generate the activity patterns for breathing and contribute to various sensory responses including changes in O2 and CO2. These complex sensorimotor tasks depend on the dynamic interplay between numerous cellular building blocks that consist of voltage-, calcium-, and ATP-dependent ionic conductances, various ionotropic and metabotropic synaptic mechanisms, as well as neuromodulators acting on G-protein coupled receptors and second messenger systems. As described in this review, the sensorimotor responses of the respiratory network emerge through the state-dependent integration of all these building blocks. There is no known respiratory function that involves only a small number of intrinsic, synaptic, or modulatory properties. Because of the complex integration of numerous intrinsic, synaptic, and modulatory mechanisms, the respiratory network is capable of continuously adapting to changes in the external and internal environment, which makes breathing one of the most integrated behaviors. Not surprisingly, inspiration is critical not only in the control of ventilation, but also in the context of "inspiring behaviors" such as arousal of the mind and even creativity. Far-reaching implications apply also to the underlying network mechanisms, as lessons learned from the respiratory network apply to network functions in general.

Neph1 regulates steady-state surface expression of Slo1 Ca(2+)-activated K(+) channels: different effects in embryonic neurons and podocytes

Large-conductance Ca(2+)-activated K(+) (BK(Ca)) channels encoded by the Slo1 gene are often components of large multiprotein complexes in excitable and nonexcitable cells. Here we show that Slo1 proteins interact with Neph1, a member of the immunoglobulin superfamily expressed in slit diaphragm domains of podocytes and in vertebrate and invertebrate nervous systems. This interaction was established by reciprocal coimmunoprecipitation of endogenous proteins from differentiated cells of a podocyte cell line, from parasympathetic neurons of the embryonic chick ciliary ganglion, and from HEK293T cells heterologously expressing both proteins. Neph1 can interact with all three extreme COOH-terminal variants of Slo1 (Slo1(VEDEC), Slo1(QEERL), and Slo1(EMVYR)) as ascertained by glutathione S-transferase (GST) pull-down assays and by coimmunoprecipitation. Neph1 is partially colocalized in intracellular compartments with endogenous Slo1 in podocytes and ciliary ganglion neurons. Coexpression in HEK293T cells of Neph1 with any of the Slo1 extreme COOH-terminal splice variants suppresses their steady-state expression on the cell surface, as assessed by cell surface biotinylation assays, confocal microscopy, and whole cell recordings. Consistent with this, small interfering RNA (siRNA) knockdown of endogenous Neph1 in embryonic day 10 ciliary ganglion neurons causes an increase in steady-state surface expression of Slo1 and an increase in whole cell Ca(2+)-dependent K(+) current. Surprisingly, a comparable Neph1 knockdown in podocytes causes a decrease in surface expression of Slo1 and a decrease in whole cell BK(Ca) currents. In podocytes, Neph1 siRNA also caused a decrease in nephrin, even though the Neph1 siRNA had no sequence homology with nephrin. However, we could not detect nephrin in ciliary ganglion neurons.

Neuregulin-1 isoform induces mitogenesis, KCa and Ca2+ currents in PC12 cells. A comparison with sciatic nerve conditioned medium

Neuregulin-1 (NRG-1) is an active component found in sciatic nerve conditioned medium (CM). NRG-1 is a growth and differentiation factor shown to have an effect on neuritogenesis and survival of neural cells. PC12 cells chronically treated with NRG-1 (beta1 isoform) show an increase in proliferation under low-serum condition (2.5% fetal bovine serum and 1.25% horse serum) and serum deprivation, without visible morphological changes. NRG-1 and CM treatments of PC12 cells induced an increase of voltage-activated Ca2+ currents and large-conductance calcium-activated K+ currents (KCa). AG825, a specific inhibitor for erbB2 receptor, abolishes KCa current, though Ca2+ currents were not inhibited. These results showed that NRG-1 is capable of inducing functional changes but is not sufficient on its own to have an effect on cell morphology.

Growth Factors Mobilize Multiple Pools ofKCaChannels in Developing Parasympathetic Neurons: Role of ADP-Ribosylation Factors and Related Proteins

In developing ciliary ganglion (CG) neurons, movement of functional large-conductance (BK type) Ca2+-activated K+( KCa) channels to the cell surface is stimulated by the endogenous growth factors TGFβ1 and β-neuregulin-1 (NRG1). Here we show that a brief NRG1 treatment (0.5–1.5 h) mobilizes KCachannels in a post-Golgi compartment, but longer treatments (>3.5 h) mobilize KCachannels located in the endoplasmic reticulum or Golgi apparatus. Specifically, the effects of 3.5 h NRG1 treatment were completely blocked by treatments that disrupt Golgi apparatus function. These include inhibition of microtubules, or inhibition of the ADP-ribosylation factor-1 (ARF1) system by brefeldin A, by over-expression of dominant-negative ARF1, or over-expression of an ARF1 GTPase-activating protein that blocks ARF1 cycling between GTP- and GDP-bound states. These treatments had no effect on stimulation of KCaevoked by 1.5 h treatment with NRG1, indicating that short-term responses to NRG1 do not require an intact Golgi apparatus. By contrast, both the acute and sustained effects of NRG1 were inhibited by treatments that block trafficking processes that occur close to the plasma membrane. Thus mobilization of KCawas blocked by treatments than inhibit ADP-ribosylation factor-6 (ARF6) signaling, including overexpression of dominant-negative ARF6, dominant-negative ARNO, or dominant-negative phospholipase D1. TGFβ1, the effects of which on KCaare much slower in onset, is unable to selectively mobilize channels in the post-Golgi pool, and its effects on KCaare completely blocked by inhibition of microtubules, Golgi function and also by plasma membrane ARF6 and phospholipase D1 signaling.

Akt Activation Is Necessary for Growth Factor–Induced Trafficking of Functional KCaChannels in Developing Parasympathetic Neurons

The protein kinase Akt is a crucial regulator of neuronal survival and apoptosis. Here we show that Akt activation is necessary for mobilization of large-conductance KCachannels in ciliary ganglion (CG) neurons evoked by β-neuregulin-1 (NRG1) and transforming growth factor-β1 (TGFβ1). Application of NRG1 to embryonic day 9 (E9) CG neurons increased Akt phosphorylation, as observed previously for TGFβ1. NRG1- and TGFβ1-evoked stimulation of KCais blocked by inhibitors of PI3K by overexpression of a dominant-negative form of Akt, by overexpression of CTMP, an endogenous negative regulator of Akt, and by application of the Akt inhibitor 1L-6-hydroxymethyl-chiro-inositol 2-( R)-2- O-methyl-3- O-octadecylcarbonate (HIMO). Conversely, overexpression of a constitutively-active form of Akt was sufficient by itself to increase mobilization of functional KCachannels. NRG1 and TGFβ1 evoked an Akt-dependent increase in cell-surface SLO α-subunits. These procedures have no effect on voltage-activated Ca2+currents. Thus Akt plays an essential role in the developmental regulation of excitability in CG neurons.

SK channels and the varieties of slow after-hyperpolarizations in neurons

Action potentials and associated Ca2+ influx can be followed by slow after-hyperpolarizations (sAHPs) caused by a voltage-insensitive, Ca2+-dependent K+ current. Slow AHPs are a widespread phenomenon in mammalian (including human) neurons and are present in both peripheral and central nervous systems. Although, the molecular identity of ion channels responsible for common membrane potential mechanisms has been largely determined, the nature of the channels that underlie the sAHPs in neurons, both in the brain and in the periphery, remains unresolved. This short review discusses why there is no clear molecular candidate for sAHPs.

A K(+) channel activated by cholinergic muscarinic receptors in chick ciliary ganglion neurons at early developmental stage

Embryonic chick ciliary ganglion (CG) neurons obtained from E7-E8 ganglia maintained in serum-free medium were stimulated with 50 microM muscarine. A fast hyperpolarization of the membrane potential was observed in 25% of the cells tested, that in some cases was associated with a slower depolarization. Accordingly, in voltage clamp experiments, either an outward current or a biphasic current response could be observed. Single-channel experiments provide evidence that these signals can be associated to the activation of a K(+) channel whose conductance is 20 pS.

Localization of the Slack potassium channel in the rat central nervous system

The Slack gene encodes a voltage-dependent K(+) channel that has a unitary conductance of approximately 60 pS. Evidence from heterologous expression studies suggests that Slack channel subunits can also combine with the Slo subunit to generate Ca(2+)-activated K(+) channels of larger conductances. Nonetheless, the function of Slack in the brain remains to be identified. We have now generated an affinity-purified antibody against the N-terminal of rat Slack, for biochemical and immunohistochemical studies. The antibody recognized Slack in transiently transfected CHO cells both by immunocytochemistry and by Western blot analysis. The antibody also detected a single band in rat brain membranes. The localization of Slack in rat brain slices was then determined using the antibody. Most prominent Slack immunoreactivity occurs in the brainstem, in particular the trigeminal system and reticular formation, where very intense staining was found in both cell bodies and axonal fibers of associated nuclei. Labeling was also very strong in the vestibular and oculomotor nuclei. Within the auditory system, the medial nucleus of the trapezoid had a robust signal consistent with staining of the giant presynaptic terminals. Strong Slack immunoreactivity was present in the olfactory bulb, red nucleus, and deep cerebellar nuclei. There was labeling also in the thalamus, substantia nigra, and amygdala. The only cortical region in which Slack immunoreactivity was detected was the frontal cortex. The subcellular and regional distribution of Slack differs from that previously reported for the Slo channel subunit and suggests that Slack may also have an autonomous role in regulating the firing properties of neurons.

Activity- and target-dependent regulation of large-conductance Ca2+-activated K+ channels in developing chick lumbar motoneurons

The functional expression of large-conductance (BK-type) Ca2+-activated K+ (K(Ca)) channels was examined in developing chick lumbar motoneurons (LMNs) between embryonic day 6 (E6) and E13 using patch-clamp recording techniques. The macroscopic K(Ca) current of E13 LMNs is inhibited by iberiotoxin and resistant to apamin. The average macroscopic K(Ca) density was low before E8 and increased 3.3-fold by E11, with an additional 1.8-fold increase occurring by E13. BK-type K(Ca) channels could not be detected in inside-out patches from E8 LMNs but were readily detected at E11. The density of voltage-activated Ca2+ currents did not change between E8 and E11. Surgical ablation of target tissues at E5 caused a significant reduction in average K(Ca) density in LMNs measured at E11. Conversely, chronic in ovo administration of d-tubocurarine, which causes an increase in motoneuron branching on the surface of the muscle target tissue, evoked a 1.8-fold increase in average LMN K(Ca) density measured at E11. Electrical activity also contributed to developmental regulation of LMN K(Ca) density. A significant reduction in E11 K(Ca) density was found after chronic in ovo treatment with the neuronal nicotinic antagonist mecamylamine or the GABA receptor agonist muscimol, agents that reduce activation of LMNs in ovo. Moreover, 3 d exposure to depolarizing concentrations of external K+ to LMNs cultured at E8 caused an increase in K(Ca) expression. Conversely, tetrodotoxin caused a decrease in K(Ca) expression in cultured E8 LMNs developing for 3 d in the presence of neurotrophic factors that promote neuronal survival in the absence of target tissues.

Activity- and target-dependent regulation of large-conductance Ca2+-activated K+ channels in developing chick lumbar motoneurons

The functional expression of large-conductance (BK-type) Ca2+-activated K+ (K(Ca)) channels was examined in developing chick lumbar motoneurons (LMNs) between embryonic day 6 (E6) and E13 using patch-clamp recording techniques. The macroscopic K(Ca) current of E13 LMNs is inhibited by iberiotoxin and resistant to apamin. The average macroscopic K(Ca) density was low before E8 and increased 3.3-fold by E11, with an additional 1.8-fold increase occurring by E13. BK-type K(Ca) channels could not be detected in inside-out patches from E8 LMNs but were readily detected at E11. The density of voltage-activated Ca2+ currents did not change between E8 and E11. Surgical ablation of target tissues at E5 caused a significant reduction in average K(Ca) density in LMNs measured at E11. Conversely, chronic in ovo administration of d-tubocurarine, which causes an increase in motoneuron branching on the surface of the muscle target tissue, evoked a 1.8-fold increase in average LMN K(Ca) density measured at E11. Electrical activity also contributed to developmental regulation of LMN K(Ca) density. A significant reduction in E11 K(Ca) density was found after chronic in ovo treatment with the neuronal nicotinic antagonist mecamylamine or the GABA receptor agonist muscimol, agents that reduce activation of LMNs in ovo. Moreover, 3 d exposure to depolarizing concentrations of external K+ to LMNs cultured at E8 caused an increase in K(Ca) expression. Conversely, tetrodotoxin caused a decrease in K(Ca) expression in cultured E8 LMNs developing for 3 d in the presence of neurotrophic factors that promote neuronal survival in the absence of target tissues.

beta -Neuregulin-1 is required for the in vivo development of functional Ca2+-activated K+ channels in parasympathetic neurons

The development of functional Ca(2+)-activated K(+) channels (K(Ca)) in chick ciliary ganglion (CG) neurons requires interactions with afferent preganglionic nerve terminals. Here we show that the essential preganglionic differentiation factor is an isoform of beta-neuregulin-1. beta-Neuregulin-1 transcripts are expressed in the midbrain preganglionic Edinger-Westphal nucleus at developmental stages that coincide with or precede the normal onset of macroscopic K(Ca) in CG neurons. Injection of beta-neuregulin-1 peptide into the brains of developing embryos evoked a robust stimulation of functional K(Ca) channels at stages before the normal appearance of these channels in CG neurons developing in vivo. Conversely, injection of a neutralizing antiserum specific for beta-neuregulin-1 inhibited the development of K(Ca) channels in CG neurons. Low concentrations of beta-neuregulin-1 evoked a robust increase in whole-cell K(Ca) in CG neurons cocultured with iris target tissues. By contrast, culturing CG neurons with iris cells or low concentrations of beta-neuregulin-1 by themselves was insufficient to stimulate K(Ca). These data suggest that the preganglionic factor required for the development of K(Ca) in ciliary ganglion neurons is an isoform of beta-neuregulin-1, and that this factor acts in concert with target-derived trophic molecules to regulate the differentiation of excitability.

BK-Type K(Ca) channels in two parasympathetic cell types: differences in kinetic properties and developmental expression

The intrinsic electrical properties of identified choroid and ciliary neurons of the chick ciliary ganglion were examined by patch-clamp recording methods. These neurons are derived from a common pool of mesencephalic neural crest precursor cells but innervate different target tissues and have markedly different action potential waveforms and intrinsic patterns of repetitive spike discharge. Therefore it is important to determine whether these cell types express different types of plasma membrane ionic channels, and to ascertain the developmental stages at which these cell types begin to diverge. This study has focused on large-conductance Ca(2+)-activated K(+) channels (K(Ca)), which are known to regulate spike waveform and repetitive firing in many cell types. Both ciliary ganglion cell types, identified on the basis of size and somatostatin immunoreactivity, express a robust macroscopic K(Ca) carried by a kinetically homogeneous population of large-conductance (BK-type) K(Ca) channels. However, the kinetic properties of these channels are different in the two cell types. Steady-state fluctuation analyses of macroscopic K(Ca) produced power spectra that could be fitted with a single Lorentzian curve in both cell types. However, the resulting corner frequency was significantly lower in choroid neurons than in ciliary neurons, suggesting that the underlying K(Ca) channels have a longer mean open-time in choroid neurons. Consistent with fluctuation analyses, significantly slower gating of K(Ca) channels in choroid neurons was also observed during macroscopic activation and deactivation at membrane potentials positive to -30 mV. Differences in the kinetic properties of K(Ca) channels could also be observed directly in single-channel recordings from identified embryonic day 13 choroid and ciliary neurons. The mean open-time of large-conductance K(Ca) channels was significantly greater in choroid neurons than in ciliary neurons in excised inside-out patches. The developmental expression of functional K(Ca) channels appears to be regulated differently in the two cell types. Although both cell types acquire functional K(Ca) at the same developmental stages (embryonic days 9-13), functional expression of these channels in ciliary neurons requires target-derived trophic factors. In contrast, expression of functional K(Ca) channels proceeds normally in choroid neurons developing in vitro in the absence of target-derived trophic factors. Consistent with this, extracts of ciliary neuron target tissues (striated muscle of the iris/ciliary body) contain K(Ca) stimulatory activity. However, K(Ca) stimulatory activity cannot be detected in extracts of the smooth muscle targets of choroid neurons.

kappa- and mu-opioids reverse the somatostatin inhibition of Ca2+ currents in ciliary and dorsal root ganglion neurons

Neuromodulators, including transmitters and peptides, modify neuronal excitability. In most neurons, multiple neuromodulator receptors are present on a single cell. Previous work has demonstrated either occlusive or additive effects when two neuromodulators that target the same ion channel are applied together. In this study, we characterize the modulation of Ca2+ and K+ channels in embryonic chick ciliary ganglion neurons by somatostatin (Som) and opioids, including the effects of these neuromodulators when applied in combination. We report a modulation of calcium current by kappa- or mu-opioids that can prevent Som effects when applied before Som and can replace Som effects when applied after Som. We term these effects demodulation because they do not have the characteristics of simple occlusion but rather represent a dominant effect of opioid-mediated modulation of calcium channels over Som-mediated modulation. These opioid effects persist in the presence of kinase and phosphatase inhibitors, as well as after alteration of the intracellular Ca2+ concentration. Furthermore, they are present in both whole-cell and perforated-patch recording configurations. These effects of opioids on Som-mediated modulation do not seem to be mediated by a general uncoupling of Som receptors from G-protein-coupled signaling systems because K+ current modulation by Som can persist in the presence of opioids. Demodulation by opioids was also observed in dorsal root ganglion neurons on the modulation of calcium current by GABA and norepinephrine (NE). In both preparations, this demodulatory interaction occurred between voltage-independent (opioids) and voltage-dependent (Som, GABA, and NE) modulatory pathways.

kappa- and mu-opioids reverse the somatostatin inhibition of Ca2+ currents in ciliary and dorsal root ganglion neurons

Neuromodulators, including transmitters and peptides, modify neuronal excitability. In most neurons, multiple neuromodulator receptors are present on a single cell. Previous work has demonstrated either occlusive or additive effects when two neuromodulators that target the same ion channel are applied together. In this study, we characterize the modulation of Ca2+ and K+ channels in embryonic chick ciliary ganglion neurons by somatostatin (Som) and opioids, including the effects of these neuromodulators when applied in combination. We report a modulation of calcium current by kappa- or mu-opioids that can prevent Som effects when applied before Som and can replace Som effects when applied after Som. We term these effects demodulation because they do not have the characteristics of simple occlusion but rather represent a dominant effect of opioid-mediated modulation of calcium channels over Som-mediated modulation. These opioid effects persist in the presence of kinase and phosphatase inhibitors, as well as after alteration of the intracellular Ca2+ concentration. Furthermore, they are present in both whole-cell and perforated-patch recording configurations. These effects of opioids on Som-mediated modulation do not seem to be mediated by a general uncoupling of Som receptors from G-protein-coupled signaling systems because K+ current modulation by Som can persist in the presence of opioids. Demodulation by opioids was also observed in dorsal root ganglion neurons on the modulation of calcium current by GABA and norepinephrine (NE). In both preparations, this demodulatory interaction occurred between voltage-independent (opioids) and voltage-dependent (Som, GABA, and NE) modulatory pathways.

Developmental regulation of neuronal K+ channels by target-derived TGF beta in vivo and in vitro

The functional expression of Ca2+-activated K+ channels (KCa) in developing chick ciliary ganglion (CG) neurons requires interactions with target tissues and preganglionic innervation. Here, we show that the stimulatory effects of target tissues are mediated by an isoform of TGFbeta. Exposure of cultured CG neurons to TGFbeta1, but not TGFbeta2 or TGFbeta3, caused robust stimulation of KCa. The KCa stimulatory effects of target tissue extracts were blocked by a neutralizing pan-TGFbeta antiserum but not by specific TGFbeta2 or TGFbeta3 antisera. Intraocular injection of TGFbeta1 caused robust stimulation of KCa, whereas intraocular injection of pan-TGFbeta antiserum inhibited expression of KCa in CG neurons developing in vivo. The effects of TGFbeta1 were potentiated by beta-neuregulin-1, a differentiation factor expressed in preganglionic neurons.

Formation of intermediate-conductance calcium-activated potassium channels by interaction of Slack and Slo subunits

Large-conductance calcium-activated potassium channels (maxi-K channels) have an essential role in the control of excitability and secretion. Only one gene Slo is known to encode maxi-K channels, which are sensitive to both membrane potential and intracellular calcium. We have isolated a potassium channel gene called Slack that is abundantly expressed in the nervous system. Slack channels rectify outwardly with a unitary conductance of about 25-65 pS and are inhibited by intracellular calcium. However, when Slack is co-expressed with Slo, channels with pharmacological properties and single-channel conductances that do not match either Slack or Slo are formed. The Slack/Slo channels have intermediate conductances of about 60-180 pS and are activated by cytoplasmic calcium. Our findings indicate that some intermediate-conductance channels in the nervous system may result from an interaction between Slack and Slo channel subunits.

Role of cell-cell interactions in the developmental regulation of Ca2+-activated K+ currents in vertebrate neurons

The functional expression of the Ca2+-activated K+ current (IK[Ca]) is dependent on cell-cell interactions in developing chick autonomic neurons. In chick ciliary ganglion (CG) neurons, expression of macroscopic IK[Ca] coincides with the formation of synapses with target tissues. CG neurons that develop in vivo in the absence of normal target tissues fail to express functional IK[Ca], although voltage-activated Ca2+ currents and most other ionic currents are expressed at normal amplitudes and densities. CG neurons placed in cell culture prior to formation of synapses with target tissues also fail to express macroscopic IK[Ca]. However, CG neurons cultured in the presence of a heat- and trypsin-sensitive extract of target tissues express IK[Ca] at normal levels. Similarly, interactions with target tissue appear to regulate the expression of whole-cell IK[Ca] in developing chick sympathetic ganglion neurons, although the relevant trophic factors appear to be different from those required by CG neurons. In addition to target tissue interactions, an intact preganglionic innervation is required for the normal in vivo development of IK[Ca] in chick CG neurons. The trophic effects of the afferent innervation do not require synaptic activation of the CG neurons, indicating secretion of a trophic factor, possibly an isoform of beta-neuregulin. The results are consistent with the hypothesis that target- and nerve terminal-derived trophic factors interact at a posttranslational level in the regulation of a functional IK[Ca]. Together, this body of data demonstrates an essential role for cell-cell interactions in the differentiation of neuronal excitability.

Developmental changes of potassium currents of embryonic leech ganglion cells in primary culture

The expression of calcium-activated potassium currents (IK(Ca)), delayed outward rectifier potassium currents (IK(slow)), and transient outward currents (IA) was studied during the development of the nervous system of the leech using the whole-cell patch-clamp recording technique. Dissociated cells were isolated from leech embryos between stage E7 and E16 and maintained in primary culture. K+ currents were recorded at E7, when only few anterior ganglia had formed beneath the primordial mouth. IK(slow) was present in all cells tested, while IK(Ca) was expressed in only 67% of the cells studied. Even as early as E7, different types of IK(Ca) have been found. Neither frequency of occurrence nor the charge density of IK(Ca) showed significant changes between E7 and E16. The density of IK(slow), however, increased by a factor of two between E7 and E8, which resulted in a significant increase in the total K+ current of these cells. This rise in potassium outward current developed in parallel with the appearance of Na+ and Ca2+ inward currents (Schirrmacher and Deitmer: J Exp Biol 155:435-453, 1991) during early development, shaping the electrical excitability in embryonic leech neurones. I(A) could be separated by its voltage-dependence and pharmacological properties. The current was detected at stage E9, when all 32 ganglia are formed in the embryo. The frequency of occurrence of I(A) increased from 16% at E9 to 70% at E15. The channel density, steady state inactivation, and kinetics showed no significant changes during development.

Neuregulins stimulate the functional expression of Ca2+-activated K+ channels in developing chicken parasympathetic neurons

The developmental expression of macroscopic Ca2+-activated K+ currents (IK[Ca]) in chicken ciliary ganglion (CG) neurons is dependent in part on trophic factors released from preganglionic nerve terminals. Neuregulins are expressed in the preganglionic neurons that innervate the chicken CG and are therefore plausible candidates for this activity. Application of 1 nM beta1-neuregulin peptide for 12 hr evokes a large (7- to 10-fold) increase in IK[Ca] in embryonic day 9 CG neurons, even in the presence of a translational inhibitor. A similar posttranslational effect is produced by high concentrations (10 nM) of epidermal growth factor and type alpha transforming growth factor but not by 10 nM alpha2-neuregulin peptide or by neurotrophins at 40 ng.ml-1. beta1-neuregulin treatment for 12 hr also confers Ca2+ sensitivity onto large-conductance (285 pS) K+ channels observed in inside-out patches. beta-Neuregulins have no effect on voltage-activated Ca2+ currents of CG neurons. These data support the hypothesis that beta-neuregulins mediate the trophic effects of preganglionic nerve terminals on the electrophysiological differentiation of developing CG neurons.

Posttranslational regulation of Ca(2+)-activated K+ currents by a target-derived factor in developing parasympathetic neurons

Macroscopic IK[Ca is not expressed in normal levels in chick ciliary ganglion (CG) neurons prior to synapse formation with target tissues, or in neurons developing in vitro or in situ in the absence of target tissues. Here, two chick CG slo partial cDNAs encoding IK[Ca channels were isolated, cloned, and sequenced. Both slo transcripts were readily detected in developing CG neurons prior to or in the absence of target tissue interactions. When CG neurons developed in vitro in the presence of target tissue (iris) extracts, a normal whole-cell IK[Ca was expressed. These effects did not require protein synthesis, and the activity was detectable throughout the stages of synapse formation in the iris. The active component has an apparent molecular weight of 40-60 kDa.

Ca(2+)-activated K+ currents in neurones: types, physiological roles and modulation

Action potentials in neurones are followed by a hyperpolarization, which can last up to several seconds. This hyperpolarization has several phases that are mediated by the activation of different types of Ca(2+)-activated K+ currents. Patch-clamp studies have revealed two families of Ca(2+)-activated K+ channels of small (SKCa) and high (BKCa) conductance. Activation of BKCa channels contributes to action-potential repolarization, while SKCa channels are thought to underlie the afterhyperpolarization (AHP). In addition, AHPs in neurones can be divided into two distinct types that are easily separated by kinetic and pharmacological criteria. It is now clear that only one type of AHP can be explained by activation of SKCa channels while a new type of Ca(2+)-activated K+ channel underlies the other. Modulation of this channel by a range of transmitters is a key determinant of the excitability of many neurones.

The effects of innervation on the developmental expression of Ca(2+)-activated K+ currents in embryonic parasympathetic neurons are not activity-dependent

Chronic blockade of synaptic transmission in ovo using mecamylamine, a neuronal nicotinic receptor antagonist, caused a large increase in naturally occurring cell death in the embryonic chick ciliary ganglion. However, the Ca(2+)-activated K+ currents in embryonic day 13 mecamylamine-treated ciliary ganglion neurons were indistinguishable from those of saline-treated controls. Therefore, the trophic effect of preganglionic innervation on the developmental expression of Ca(2+)-activated K+ current is not dependent upon intact nicotinic cholinergic synaptic transmission and may instead be mediated by a nerve terminal-derived differentiation factor.

Target-derived factors regulate the expression of Ca(2+)-activated K+ currents in developing chick sympathetic neurones

1. The functional expression of Ca(2+)-activated K+ currents (IK(Ca)) and voltage-activated Ca2+ currents (ICa) was examined using whole-cell recordings from chick lumbar sympathetic neurones developing in situ and under various conditions in vitro. 2. Macroscopic IK(Ca) was expressed at low current density (< 0.01 mA cm-2) in neurones isolated at embryonic days 9-16 (E9-16). IK(Ca) was expressed at high densities (> 0.04 mA cm-2) at E17-19. By contrast, there was no significant difference in ICa density between sympathetic neurones isolated at E13 and E18. 3. When sympathetic neurones were isolated at E13 and maintained in vitro for 5 days, IK(Ca) was expressed at a significantly lower density (< 0.01 mA cm-2) than in neurones isolated acutely at E18 (> 0.04 mA cm-2). There was no difference in ICa density between neurones that developed in vitro and in situ. 4. When E13 sympathetic neurones were cultured for 5 days in the presence of a confluent layer of ventricular myocytes, they expressed IK(Ca) at a high density (> 0.04 mA cm-2), similar to that of E18 neurones that developed entirely in situ. Cardiac cell-conditioned medium produced similar effects. However, co-culture of sympathetic neurones with spinal cord explants did not allow for normal IK(Ca) expression in vitro. 5. Culturing sympathetic neurones in the presence of 5 ng ml-1 nerve growth factor (NGF) caused a significant increase in IK(Ca) density but this effect was only seen in 50% of cells examined. 6. The largest developmental changes in macroscopic IK(Ca) occur several days after other K+ currents and ICa are expressed at maximal density. The normal developmental expression of IK(Ca) is dependent upon extrinsic factors, including target-derived differentiation factors.

ATP responses in the embryo chick ciliary ganglion cells

The ATP responses in ciliary neurons acutely dissociated from chick ciliary ganglia were investigated using the nystatin perforated patch recording mode. ATP induced a transient inward current at a holding potential of -50 mV in a concentration-dependent manner. The half-maximum effective concentration of ATP was 8.2 microM and the Hill coefficient was 0.9. The current-voltage relationship of the ATP response revealed a strong inward rectification at potentials more positive than -30 mV and the reversal potential was near 0 mV. The relative potencies of purinoceptor agonists were in the order of ATP > 2-methylthio-ATP > ADP. Neither adenosine, AMP nor alpha, beta-methylene-ATP induced any response. The ATP-induced inward current was blocked by suramin, a selective P2 purinoceptor antagonist, in a concentration-dependent manner. The half-maximum inhibitory concentration was 4.5 microM. The cytosolic Ca2+ concentration was increased by ATP and suramin inhibited the increase in a concentration-dependent manner. These results suggest that ATP operates non-selective cation channels by acting on P2y purinoceptors and has a role in the excitation of ciliary neurons.

Nitric oxide release and long term potentiation at synapses in autonomic ganglia

1. Long-term potentiation (LTP) of synaptic transmission in autonomic ganglia is reviewed, together with the possible role of nitric oxide (NO) in this process. 2. Calcium levels in preganglionic nerve terminals are elevated during at least the induction phase of LTP following a tetanus as well as during LTP induced by transmitter substances acting on the nerve terminals. Of the large number of calcium-dependent processes in the nerve terminal that might affect transmitter release, only calcium-calmodulin has been shown to be important in both the induction and maintenance of LTP. 3. The possibility that there is a decrease in the open time of nerve-terminal potassium channels following a tetanus, leading to an increase in duration of the terminal action potential and hence an increase in calcium influx and transmitter release is considered. There is little evidence for such an effect as yet for preganglionic nerve terminals. 4. Phosphorylation of potassium channels by cAMP-dependent protein kinase can lead to their inactivation with consequent action potential broadening in some systems. Exogenous cAMP enhances synaptic efficacy at preganglionic nerve terminals. Whether this occurs through an inactivation of potassium channels is not known. 5. Nitric oxide (NO) synthase is present in both sympathetic ganglia and the ciliary ganglia. NO increases synaptic efficacy in both ganglia. In at least the case of ciliary ganglion this is due to elevation of quantal secretion. 6. NO can in some conditions increase the terminal action potential duration in ciliary ganglia, probably through decrease in the Ic potassium current. There is evidence that this happens through cGMP modulating cAMP phosphodiesterases, thereby affecting cAMP phosphorylation of the Ic channel. 7. Blocking NO synthase markedly decreases LTP following a tetanus in the ciliary ganglion. The possibility is considered that NO is released from the terminal during a tetanus and through altering cAMP phosphorylation of Ic enhances transmitter release.

Nicotinic and muscarinic acetylcholine responses in the embryo chick ciliary ganglion cells

Nicotinic and muscarinic acetylcholine (ACh) responses were investigated in acutely dissociated chick ciliary ganglion neurons using the nystatin perforated patch clamp technique. ACh-induced a rapid transient inward current in 100% of the neurons at a holding potential of -60 mV. This rapid inward current was mimicked by nicotine but not by muscarine. The reversal potential of the rapid inward current was +10.5 mV and the current was inhibited by d-tubocurarine and hexamethonium in a dose-dependent manner. In 57.6% of neurons, a slow inward current was also induced by ACh at a holding potential of -20 mV. This slow inward current was mimicked by muscarine but not by nicotine. The slow inward current became smaller at a hyperpolarized potential but not reversed, being consistent with the fact that this current was elicited by the inhibition of M-current. p-Fluorohexa-hydrosiladifenidol (P-F-HHSiD) strongly inhibited the slow inward current, suggesting that the current was elicited by the activation of M3 receptors.

Calcium-activated potassium channels in goldfish hair cells

1. Characteristics of Ca(2+)-activated K+ channels in the basolateral membrane of hair cells isolated from the caudal part of the goldfish saccular macula were studied mainly with the inside-out mode of the patch clamp method. 2. Several types of Ca(2+)-activated K+ channels differing in unitary conductance were identified. The conductances (n = 156) ranged from 130 to 320 pS (when measured in symmetrical 125 mM KCl) and could be roughly separated into four groups, centred on values of 150, 200, 250 and 300 pS. The pharmacological profile, assessed by, for example, tetraethylammonium blockade, and the relatively large conductance indicated that these channels can be classified as large-conductance Ca(2+)-activated K+ channels (BK channels). The relative permeability of these channels to different ion species was in the order K+ (1.0) > Rb+ (0.8) > NH4+ (0.14) > Na+, Cs+ (< 0.05). 3. Curves relating open state probability to [Ca2+]i, for membrane potentials between -50 and +50 mV, were similar to those observed for BK channels of rat muscle. However, the maximum open state probability (100-1000 microM [Ca2+]i and 50 mV membrane potential) was 0.4-0.9, and always less than 1. 4. These channels had a short arithmetic mean open time ranging from 0.08 to 1.2 ms (0.08-0.5 ms in 88% of cases) and an arithmetic mean shut time ranging from 0.24 to 1.2 ms (10 microM [Ca2+]i and 50 mV membrane potential). The shut intervals were more sensitive to changes in [Ca2+]i and membrane potential than were the open intervals. 5. The distribution of individual open and shut intervals was fitted with the sum of exponential functions. Except for the slowest shut component, which only accounted for less than 1% of shut events, all other components had time constants shorter than 1 ms. As a result of these short open and shut intervals, the current trace had a flickery pattern rather than a burst-interburst pattern. 6. There was a rough correlation between unitary conductance and mean open time, i.e. channels with a large unitary conductance had a longer mean open time. 7. The sensitivity to [Ca2+]i of the Ca(2+)-activated K+ channel in goldfish hair cells was one to two orders of magnitude lower than that of BK channels in rat muscle. Channels with a longer mean open time had a higher Ca2+ sensitivity. 8. The stability of the single Ca(2+)-activated K+ channel kinetics was studied by measuring the 'moving' mean duration of open and shut intervals.(ABSTRACT TRUNCATED AT 400 WORDS)

Functional dependence of Ca(2+)-activated K+ current on L- and N-type Ca2+ channels: differences between chicken sympathetic and parasympathetic neurons suggest different regulatory mechanisms

The influx of Ca2+ ions controls many important processes in excitable cells, including the regulation of the gating of Ca(2+)-activated K+ channels (the current IK[Ca]). Various IK[Ca] channels contribute to the regulation of the action-potential waveform, the repetitive discharge of spikes, and the secretion of neurotransmitters. It is thought that large-conductance IK[Ca] channels must be closely colocalized with Ca2+ channels (ICa) to be gated by Ca2+ influx. We now report that IK[Ca] channels can be preferentially colocalized with pharmacologically distinct subtypes of voltage-activated Ca2+ channel and that this occurs differently in embryonic chicken sympathetic and parasympathetic neurons. The effects of various dihydropyridines and omega-conotoxin on voltage-activated Ca2+ currents (ICa) and Ca(2+)-activated K+ currents (IK[Ca]) were examined by using perforated-patch whole-cell recordings from embryonic chicken ciliary and sympathetic ganglion neurons. Application of nifedipine or omega-conotoxin each caused a 40-60% reduction in ICa, whereas application of S-(-)-BAY K 8644 potentiated ICa in ciliary ganglion neurons. But application of omega-conotoxin had little or no effect on IK[Ca], whereas nifedipine and S-(-)-BAY K 8644 inhibited and potentiated IK[Ca], respectively. These results indicate that IK[Ca] channels are preferentially coupled to L-type, but not to N-type, Ca2+ channels on chicken ciliary ganglion neurons. Chicken sympathetic neurons also express dihydropyridine-sensitive and omega-conotoxin-sensitive components of ICa. However, in those cells, application of omega-conotoxin caused a 40-60% reduction in IK[Ca], whereas nifedipine reduced IK[Ca] but only in a subpopulation of cells. Therefore, IK[Ca] in sympathetic neurons is either coupled to N-type Ca2+ channels or is not selectively coupled to a single Ca(2+)-channel subtype. The preferential coupling of IK[Ca] channels with distinct ICa subtypes may be part of a mechanism to allow for selective modulation of neurotransmitter release. Preferential coupling may also be important for the differentiation and development of vertebrate neurons.

An intermediate conductance calcium-activated potassium channel in rat visceral sensory afferent neurons

Whole-cell and single channel recordings were used to characterize an intermediate conductance calcium-activated potassium (KCa) channel in sensory neurons of the nodose ganglion. From a -80 mV holding potential, the total outward current in these neurons was increased when extracellular calcium was raised from 0.02 to 5 mM. This calcium-evoked outward current was not blocked by either charybdotoxin (50 nM) or apamine (40 nM). In the inside-out patch configuration, the current-voltage relationship for this channel was linear between -60 and +60 mV in symmetrical 145 mM potassium aspartate (KAsp) and possessed a conductance of approximately 60 picosiemens (pS). Increasing [Ca2+]i from 0.01 microM to 1.0 microM markedly increased the cumulative open probability of this channel and the effect of increasing [Ca2+]i on these channels was not voltage dependent. In the outside-out patch configuration, neither tetraethylammonioum (TEA), (1 mM), apamine (40 nM) or charybdotoxin (ChTx) (50 nM) had any effect on the activity of this channel. These results provide new evidence for the existence of pharmacologically distinct intermediate conductance KCa channel in sensory afferent neurons.

Regulation of A-currents by cell-cell interactions and neurotrophic factors in developing chick parasympathetic neurones

1. The developmental regulation of ion channel expression was studied in parasympathetic neurones isolated from the chick ciliary ganglion. Whole-cell patch clamp recordings were made from ciliary ganglion neurones that were removed from the embryo on the ninth embryonic day (E9) and maintained in dissociated cell culture for an additional 4 days. Previous studies have shown that the expression of a transient voltage-activated K+ current (IA) is regulated by unidentified environmental stimuli during these developmental stages. 2. The effect of interactions between neurones and target tissue on the expression of IA was tested by co-culturing ciliary ganglion neurones with chick striated muscle cells. Neurones from the nerve-muscle co-cultures expressed normal amplitudes of IA, but the neurones did not express normal levels of IA when they were plated onto lysed muscle fibres. 3. The effect of interactions between ganglionic neurones and non-neuronal ganglionic cells was tested by culturing ganglia as explants rather than as dissociated cells. Neurones isolated from the explant cultures did not express normal levels of IA. Similarly, when dissociated ganglionic neurones were co-cultured with fibroblasts isolated from embryonic chick skin, they did not express normal amplitudes of IA. 4. Chronic depolarization caused by growing ciliary ganglion neurones in the presence of elevated K+ concentrations did not allow for the normal expression of IA, although it did promote the survival of these neurones in vitro. 5. Addition of 40 ng ml-1 of recombinant human ciliary neurotrophic factor (CNTF) or basic fibroblast growth factor (bFGF) to the cell culture medium had no effect on IA expression in developing chick ciliary ganglion neurones. However, 40 ng ml-1 of acidic fibroblast growth factor (aFGF) stimulated the expression of IA. All trophic factors promoted the growth and survival of ciliary ganglion neurones in vitro. 6. Dissociated ciliary ganglion neurones were maintained in a culture medium containing an aqueous extract of the whole brain. Neurones developing under these conditions expressed normal levels of IA. The stimulatory activity of the brain extract was destroyed by heating. 7. The expression of IA in chick ciliary ganglion neurones developing in vitro can be regulated by soluble growth factors and by interactions with certain other cell types. Similar interactions may regulate the expression of IA in ciliary ganglion neurones developing in situ.

Neuronal acetylcholine receptors that bind alpha-bungarotoxin with high affinity function as ligand-gated ion channels

Neuronal membrane components that bind alpha-bungarotoxin with high affinity can increase intracellular levels of free calcium, demonstrating the components function as nicotinic receptors. Though such receptors often contain the alpha 7 gene product, which by itself can produce ionotropic receptors in Xenopus oocytes, numerous attempts have failed to demonstrate an ion channel function for the native receptors on neurons. Using rapid application of agonist, we show here that the native receptors are ligand-gated ion channels which are cation selective, prefer nicotine over acetylcholine, and rapidly desensitize. Much of the calcium increase caused in neurons by the receptors under physiological conditions appears to result from their depolarizing the membrane sufficiently to trigger calcium influx through voltage-gated channels.

Nitric oxide modulation of calcium-activated potassium channels in postganglionic neurones of avian cultured ciliary ganglia

1. A study has been made of the modulation of calcium-activated potassium channels in cultured neurones of avian ciliary ganglia by sodium nitroprusside and L-arginine. 2. Sodium nitroprusside (100 microM) reduced the net outward current by 22 +/- 1% at 4.8 ms (mean +/- s.e. mean) and 25 +/- 1% at 350 ms during a test depolarization to +40 mV from a holding potential of -40 mV. The outward current remained reduced for the duration of the recording following a single application of sodium nitroprusside. These effects did not occur if the influx of calcium ions was first blocked with Cd2+ (500 microM). Application of ferrocyanide (100 microM) reduced the net outward current by only 6 +/- 3% at 350 ms during a test depolarization to +40 mV. 3. L-Arginine (270 microM) reduced the net outward current on average by 19 +/- 2% at 4.8 ms and 22 +/- 2% at 350 ms during a test depolarization to +40 mV. The current remained in this reduced state for the duration of the recording following a single application of L-arginine. These effects were reduced to 11 +/- 1% at 4.8 ms and 11 +/- 2% at 350 ms in the presence of N omega-nitro-L-arginine methyl ester (L-NAME, 100 microM). 4. In order to alleviate the dependence of calcium-activated potassium channels (Ik(Ca)) on the inward flux of calcium ions, the patch-clamp pipettes were filled with a solution containing 100 microM CaCl2, and the Ca2+ in the bathing solution was replaced with EGTA. Under these conditions sodium nitroprusside reduced the total outward current during a depolarizing pulse of + 40 mV by 9 +/_ 1% at 4.8 ms and by 36 +/- 3% at 350 ms. L-Arginine (270 microM) reduced this current under the same conditions by 9 +/- 1% at 4.8 ms and by 35 +/- 2% at 350 ms.5. Calcium-activated potassium currents were sensitive to apamin (50 nM), as this reduced the outward current by 23 +/- 3% at 350 ms when a high calcium-containing pipette was used during a depolarizing command to + 40 mV. L-Arginine still decreased the outward current in the presence of apamin(50 nM), by 5 +/- 1% at 4.8 ms and by 19 +/- 2% at 350 ms, indicating that L-arginine could reduce an apamin-insensitive Ik(Ca)6. Calcium-activated potassium currents were also sensitive to charybdotoxin (10 nM), as this reduced the outward current by 34 +/- 4% at 350 ms when a high calcium-containing pipette was used during a depolarizing command to + 40 mV. L-Arginine still decreased the outward current in the presence of charybdotoxin, by 6 +/- 1% at 4.8 ms and 12 +/- 4% at 350 ms, showing that L-arginine could reduce a charybdotoxin-insensitive Ik(Ca).7. The present results indicate that NO-synthase in ciliary ganglia can modulate Ik(Ca) by a method which is independent of the action of NO on the calcium channels. The Ik(ca) is decreased significantly at 4.8 ms into a depolarizing pulse, at a time that would decrease the rate of repolarization of the action potential. Ik(Ca) is also reduced at longer times (350 ms), indicating an affect on the inactivating process.

Characteristics of multiple voltage-activated K+ currents in acutely dissociated chick ciliary ganglion neurones

1. The properties of voltage-activated K+ currents were examined using whole-cell recording techniques in acutely isolated chick ciliary ganglion neurones. 2. Application of depolarizing voltage pulses from a holding potential of -60 mV evoked sustained outward currents that inactivated with time constants of hundreds of milliseconds (IDR). Bath application of 10 mM tetraethylammonium (TEA) caused a 70-90% reduction of IDR. Application of depolarizing voltage steps from a holding potential of -120 mV revealed a second class of TEA-resistant outward currents. These currents activated quickly but inactivated completely within tens of milliseconds (IA). IA activated at more negative command potentials than IDR. However, IDR exhibited a steeper voltage dependence of activation than IA. 3. The midpoint of the steady-state inactivation curve of IA was between -95 and -110 mV. By contrast the midpoint of the steady-state inactivation curve of IDR was between -80 and -90 mV. It was not possible to produce a complete inactivation of IDR using prepulses of up to 2 s duration. 4. The time course of IA inactivation could only be fitted with double-exponential curves with time constants of 5-18 ms and 30-60 ms at membrane potentials positive to -30 mV. The inactivation of IA was slower at more positive membrane potentials because of a greater contribution of the long time constant. The individual time constants were not markedly voltage dependent. 5. Bath application of 5 mM 4-aminopyridine (4-AP) caused a 70-100% block of IA whereas 1 mM 4-AP was ineffective. Bath application of 560 nM alpha-dendrotoxin (DTX) produced a 50-70% reduction of IA, but application of 280 nM DTX had no effect on IA. 6. Application of 1 mM 4-AP produced a reversible 55-80% block of IDR measured at the end of a 500 ms depolarizing pulse. The 4-AP-sensitive components of IDR activated rapidly and exhibited a gradual inactivation with continued depolarization. The 4-AP-resistant components of IDR activated much more slowly and showed very little tendency to inactivate. Significant blockade of IDR was produced by 10 microM 4-AP. 7. The decay of IDR tail currents could only be fitted with double exponential curves with time constants of 3-6 and 40-60 ms, respectively. The fast and slow components of the tail currents behaved independently with respect to the duration of the depolarizing voltage step. 8. Application of 1 mM 4-AP eliminated the fast, but not the slow component of IDR tail currents.(ABSTRACT TRUNCATED AT 400 WORDS)

Large conductance Ca(2+)-activated K+ channels are involved in both spike shaping and firing regulation in Helix neurones

1. The role of BK-type calcium-dependent K+ channels (K+Ca) in cell firing regulation was evaluated by performing whole-cell voltage clamp and patch clamp experiments on the U cell neurones in the snail Helix pomatia. These cells were selected because most of the repolarizing K+ current flowed through K+Ca channels. 2. U cells generated overshooting Ca(2+)-dependent spikes in Na(+)-free saline. In response to prolonged depolarizing current, they fired a limited number of spikes of decreasing amplitude, and behaved like fast-adapting or phasic neurones. 3. Under voltage clamp conditions, the K+Ca current had a slow onset at voltages that induced small Ca2+ entries. By manipulating the Ca2+ entry (either with appropriate voltage programmes or by changing the Ca2+ content of the bath), the K+Ca channel opening was found to be rate limited by the Ca2+ binding step and not by the voltage-dependent conformational change to the open state. 4. Despite the slow activation rate observed in voltage-clamped cells, 25-30% of the available K+Ca current was found to be active during isolated spikes. These data were based on patch clamp, spike-like voltage clamp and hybrid current clamp-voltage clamp experiments. 5. The fact that spikes led the slowly rising K+Ca current to shift into a fast activating mode was accounted for by the large surge of Ca2+ current concomitant with spike upstroke. The early calcium surge resulted in local increases in cytosolic calcium, which speeded up the binding of calcium ions to the closed K+Ca channels. From changes in the null Ca2+ current voltage, it was calculated that the submembrane [Ca2+]i increase to 50-80 microM during the spike. 6. Due to their fast voltage dependence, K+Ca channels appeared to play no role in shaping the interspike trajectory. 7. Even in the fast activating mode, the K+Ca current had a finite rate of rise and was not involved in repolarizing short duration Na(+-dependent action potentials. The current became more and more active, however, when voltage-gated K+ channels were progressively inactivated during firing. 8. The fast adaptation exhibited by U cells upon sustained depolarization was not paralleled by a recruitment of K+Ca channels because of the cumulative Ca2+ entries. During a spike burst, the K+Ca current progressively overlapped the depolarizing Ca2+ current, which ultimately stopped the firing. The early opening of K+Ca channels was ascribed to residual Ca2+ accumulation that kept part of the channels in the Ca(2+)-bound state ready to be opened quickly by cell depolarization.(ABSTRACT TRUNCATED AT 400 WORDS)

Divalent cations selectively alter the voltage dependence of inactivation of A-currents in chick autonomic neurons

A-currents were studied in acutely dissociated chick autonomic neurons. Switching from salines containing 4 mM Mg2+ to salines containing 4 mM Ca2+ caused a large positive shift in the voltage dependence of steady-state inactivation, but had no effect on the voltage dependence or kinetics of activation, deactivation, the rate at which channels became inactivated, or the rate at which channels recovered from inactivation. This effect saturated with increasing concentrations of Ca2+. Other group IIA divalent cations were less effective than Ca2+, in the order Ca2+ > Ba2+ > Mg2+ = Sr2+. Application of 4 mM Mg2+ partially antagonized the effects of 4 mM Ca2+. The results suggest that divalent cations selectively alter the voltage dependence of steady-state inactivation by acting at sites accessible from the outside of the cell.

Cyclic GMP-activated channels of the chick pineal gland: effects of divalent cations, pH, and cyclic AMP

Chick pineal cells maintained in dissociated cell culture express an intrinsic photosensitive circadian oscillator, but the mechanisms of phototransduction in avian pinealocytes are not fully understood. In this study, we have used inside-out patches to examine the characteristics of cyclic GMP-activated channels of chick pinealocytes in more detail, concentrating on the effects of factors known to modulate the secretion of melatonin and/or the function of circadian pacemakers. In most patches, the predominant conductance state was 19 pS in symmetrical 145 mM NaCl. But in some patches, a second cyclic GMP-activated channel with a unitary conductance of 29 pS was also present. The current flowing through cyclic GMP-activated channels was not affected by application of salines containing 1 microM Ca2+ to the cytoplasmic face of the patch membrane. By contrast, application of 1 mM Ca2+ caused a partial reduction in cyclic GMP-activated current at all membrane potentials. Application of 1-5 mM Mg2+ ions caused a virtually complete blockade of current at positive membrane potentials, but caused only a small decrease in current at negative membrane potentials. No obvious differences in the gating of cyclic GMP-activated channels were observed in pH 8.2, 7.4 or 6.2 salines. Application of salines containing 100 microM, 500 microM, or 1 mM cyclic AMP did not cause activation of the channels, but 5 mM cyclic AMP evoked a low level of channel activity. Application of 5 mM but not 100 microM cyclic AMP decreased the probability of channel activation caused by 20-100 microM cyclic GMP and also increased the percentage of openings to an 11 pS subconductance state. Thus, cyclic AMP acts as a weak partial agonist. Nevertheless, the gating of these channels does not seem to be controlled directly by physiologically relevant changes in intracellular Ca2+, pH, or cyclic AMP.

Properties of single Na(+)-activated K+ channels in cultured central neurons of the chick embryo

Na(+)-activated K+ channels (IK[Na]) of cultured chick brainstem neurons do not run down following excision of inside-out patches, but this occurs within seconds to minutes in cultured chick olfactory bulb neurons. IK[Na] channels of chick brainstem neurons exhibit a main conductance state of 95-105 pS, and also express multiple sub-conductance states. These channels have complex kinetics, with multiple closed and main conductance states. The average lifetime of the main conductance state is not dependent on the Na+ concentration used to activate the channels.

Spontaneous miniature hyperpolarizations of presynaptic nerve terminals in the chick ciliary ganglion

Intracellular recordings from presynaptic nerve terminals in the chick ciliary ganglion revealed the presence of spontaneous miniature hyperpolarizations in virtually all (approximately 86%) nerve terminals examined. These spontaneous events appeared as small, brief hyperpolarizations at resting potential and were observed to increase or decrease as the membrane potential was depolarized or hyperpolarized from rest, respectively. The hyperpolarizing potentials were sensitive to blockade by tetraethylammonium and Ba2+, while caffeine increased then abolished these events. The voltage fluctuations were unaffected by tetrodotoxin, low Ca2+ external solution or the synaptic blockers, picrotoxin and strychnine. These spontaneous, transient, miniature hyperpolarizations may be due to the brief and co-ordinated activation of between 15-60 Ca(2+)-dependent K+ channels following the release of Ca2+ from internal stores.

Changes in the electrical properties of chick ciliary ganglion neurones during embryonic development

1. Whole-cell recording techniques were used to examine the expression of ionic currents in chick ciliary ganglion neurones dissociated acutely at various stages of embryonic development. Currents were also examined in dissociated cells that had been maintained in vitro for several days. 2. Voltage-activated, tetrodotoxin (TTX)-sensitive Na+ currents (INa) could be detected in all cells tested between stage 25 and stage 40 (embryonic days 4.5-14). INa increased in both amplitude and density throughout development, but no obvious changes in kinetics or sensitivity to TTX were observed. 3. High-threshold Ca2+ currents (ICa) were also detectable between stage 25 and stage 40. ICa increased in both amplitude and density throughout this time. No obvious changes in kinetics or voltage dependence were observed. 4. Delayed rectifier K+ currents (IDR) and A-currents (IA) could be detected in Ca(2+)-free salines, and distinguished on the basis of differences in kinetics, voltage dependence, and sensitivity to tetraethylammonium (TEA). IA was either absent, or present at very low densities at stages 26-30, but showed a sharp increase in density thereafter. In contrast, IDR was detectable as early as stage 25, and did not display a significant increase in density during development. 5. Ca(2+)-activated K+ currents (IK(Ca)) were either undetectable or present at very low density between stage 26 and stage 30 (embryonic days 5-9) but showed a large increase in amplitude and density thereafter. 6. Ionic currents were examined in age-matched cells dissociated acutely on embryonic day 13, or isolated on embryonic day 9 and maintained in vitro for an additional 4 days. Most of the cells maintained in culture for 4 days did not express detectable IK(Ca), and had significantly reduced IA compared to acutely isolated controls. The cultured cells expressed normal densities of IDR, ICa and INa. 7. All ionic currents increased in amplitude during normal embryonic development, and all but IDR increased in density. The largest change in density generally occurred between stages 30 and 40, during which time ciliary ganglion neurones form synapses with target tissues. 8. Isolation of ciliary neurones from the in ovo environment prevented the normal development of IA and IK(Ca), suggesting that the expression of these channels is controlled by one or more extrinsic environmental factors. In contrast, the normal expression of INa, ICa and IDR is not dependent upon extrinsic factors.