Drosophila mutants reveal two components of fast outward current

Synaptic excitation is regulated by the postsynaptic dSK channel at the Drosophila larval NMJ

In the mammalian central nervous system, the postsynaptic small-conductance Ca(2+)-dependent K(+) (SK) channel has been shown to reduce postsynaptic depolarization and limit Ca(2+) influx through N-methyl-d-aspartate receptors. To examine further the role of the postsynaptic SK channel in synaptic transmission, we studied its action at the Drosophila larval neuromuscular junction (NMJ). Repetitive synaptic stimulation produced an increase in postsynaptic membrane conductance leading to depression of excitatory postsynaptic potential amplitude and hyperpolarization of the resting membrane potential (RMP). This reduction in synaptic excitation was due to the postsynaptic Drosophila SK (dSK) channel; synaptic depression, increased membrane conductance and RMP hyperpolarization were reduced in dSK mutants or after expressing a Ca(2+) buffer in the muscle. Ca(2+) entering at the postsynaptic membrane was sufficient to activate dSK channels based upon studies in which the muscle membrane was voltage clamped to prevent opening voltage-dependent Ca(2+) channels. Increasing external Ca(2+) produced an increase in resting membrane conductance and RMP that was not seen in dSK mutants or after adding the glutamate-receptor blocker philanthotoxin. Thus it appeared that dSK channels were also activated by spontaneous transmitter release and played a role in setting membrane conductance and RMP. In mammals, dephosphorylation by protein phosphatase 2A (PP2A) increased the Ca(2+) sensitivity of the SK channel; PP2A appeared to increase the sensitivity of the dSK channel since PP2A inhibitors reduced activation of the dSK channel by evoked synaptic activity or increased external Ca(2+). It is proposed that spontaneous and evoked transmitter release activate the postsynaptic dSK channel to limit synaptic excitation and stabilize synapses.

Excitable properties of adult skeletal muscle fibres from the honeybeeApis mellifera

In the hive, a wide range of honeybees tasks such as cell cleaning,nursing, thermogenesis, flight, foraging and inter-individual communication(waggle dance, antennal contact and trophallaxy) depend on proper muscle activity. However, whereas extensive electrophysiological studies have been undertaken over the past ten years to characterize ionic currents underlying the physiological neuronal activity in honeybee, ionic currents underlying skeletal muscle fibre activity in this insect remain, so far, unexplored. Here, we show that, in contrast to many other insect species, action potentials in muscle fibres isolated from adult honeybee metathoracic tibia,are not graded but actual all-or-none responses. Action potentials are blocked by Cd2+ and La3+ but not by tetrodotoxin (TTX) in current-clamp mode of the patch-clamp technique, and as assessed under voltage-clamp, both Ca2+ and K+ currents are involved in shaping action potentials in single muscle fibres. The activation threshold potential for the voltage-dependent Ca2+ current is close to–40 mV, its mean maximal amplitude is –8.5±1.9 A/F and the mean apparent reversal potential is near +40 mV. In honeybees, GABA does not activate any ionic membrane currents in muscle fibres from the tibia, but L-glutamate, an excitatory neurotransmitter at the neuromuscular synapse induces fast activation of an inward current when the membrane potential is voltage clamped close to its resting value. Instead of undergoing desensitization as is the case in many other preparations, a component of this glutamate-activated current has a sustained component, the reversal potential of which is close to 0 mV, as demonstrated with voltage ramps. Future investigations will allow extensive pharmacological characterization of membrane ionic currents and excitation–contraction coupling in skeletal muscle from honeybee, a useful insect that became a model to study many physiological phenomena and which plays a major role in plant pollination and in stability of environmental vegetal biodiversity.

Genetic modifications of seizure susceptibility and expression by altered excitability in Drosophila Na(+) and K(+) channel mutants

A seizure-paralysis repertoire characteristic of Drosophila "bang-sensitive" mutants can be evoked electroconvulsively in tethered flies, in which behavioral episodes are associated with synchronized spike discharges in different body parts. Flight muscle DLMs (dorsal longitudinal muscles) display a stereotypic sequence of initial and delayed bouts of discharges (ID and DD), interposed with giant fiber (GF) pathway failure and followed by a refractory period. We examined how seizure susceptibility and discharge patterns are modified in various K(+) and Na(+) channel mutants. Decreased numbers of Na(+) channels in nap(ts) flies drastically reduced susceptibility to seizure induction, eliminated ID, and depressed DD spike generation. Mutations of different K(+) channels led to differential modifications of the various components in the repertoire. Altered transient K(+) currents in Sh(133) and Hk mutants promoted ID induction. However, only Sh(133) but not Hk mutations increased DD seizure and GF pathway failure durations. Surprisingly, modifications in sustained K(+) currents in eag and Shab mutants increased thresholds for DD induction and GF pathway failure. Nevertheless, both eag and Shab, like Sh(133), increased DD spike generation and recovery time from GF pathway failure. Interactions between channel mutations with the bang-sensitive mutation bss demonstrated the role of membrane excitability in stress-induced seizure-paralysis behavior. Seizure induction and discharges were suppressed by nap(ts) in bss nap double mutants, whereas Sh heightened seizure susceptibility in bss Sh(133) and bss Sh(M) double mutants. Our results suggest that individual seizure repertoire components reflect different neural network activities that could be differentially altered by mutations of specific ion channel subunits.

Calcium-activated potassium channel of the tobacco hornworm, Manduca sexta: molecular characterization and expression analysis

Large-conductance calcium- and voltage-gated potassium channels (BK or Slowpoke) serve as dynamic integrators linking electrical signaling and intracellular activity. These channels can mediate many different Ca2+-dependent physiological processes including the regulation of neuronal and neuroendocrine cell excitability and muscle contraction. To gain insights into the function of BK channels in vivo, we isolated a full-length cDNA encoding the alpha subunit of a Slowpoke channel from the tobacco hornworm, Manduca sexta (msslo). Amino acid sequence comparison of the deduced Manduca protein revealed at least 80% identity to the insect Slo channels. The five C-terminal alternative splice regions are conserved, but the cloned cDNA fragments contained some unique combinations of exons E, G and I. Our spatial profile revealed that transcript levels were highest in skeletal muscle when compared with the central nervous system (CNS) and visceral muscle. The temporal profile suggested that msslo expression is regulated developmentally in a tissue- and regional-specific pattern. The levels of msslo transcripts remain relatively constant throughout metamorphosis in the CNS, transiently decline in the heart and are barely detectable in the gut except in adults. A dramatic upregulation of msslo transcript levels occurs in thoracic but not abdominal dorsal longitudinal body wall muscles (DLM), suggesting that the msSlo current plays an important role in the excitation or contractile properties of the phasic flight muscle. Our developmental profile of msslo expression suggests that msSlo currents may contribute to the changes in neural circuits and muscle properties that produce stage-specific functions and behaviors.

Calcium influx via L- and N-type calcium channels activates a transient large-conductance Ca2+-activated K+ current in mouse neocortical pyramidal neurons

Ca2+-activated K+ currents and their Ca2+ sources through high-threshold voltage-activated Ca2+ channels were studied using whole-cell patch-clamp recordings from freshly dissociated mouse neocortical pyramidal neurons. In the presence of 4-aminopyridine, depolarizing pulses evoked transient outward currents and several components of sustained currents in a subgroup of cells. The fast transient current and a component of the sustained currents were Ca2+ dependent and sensitive to charybdotoxin and iberiotoxin but not to apamin, suggesting that they were mediated by large-conductance Ca2+-activated K+ (BK) channels. Thus, mouse neocortical neurons contain both inactivating and noninactivating populations of BK channels. Blockade of either L-type Ca2+ channels by nifedipine or N-type Ca2+ channels by omega-conotoxin GVIA reduced the fast transient BK current. These data suggest that the transient BK current is activated by Ca2+ entry through both N- and L-type Ca2+ channels. The physiological role of the fast transient BK current was also examined using current-clamp techniques. Iberiotoxin broadened action potentials (APs), indicating a role of BK current in AP repolarization. Similarly, both the extracellular Ca2+ channel blocker Cd2+ and the intracellular Ca2+ chelator BAPTA blocked the transient component of the outward current and broadened APs in a subgroup of cells. Our results indicate that the outward current in pyramidal mouse neurons is composed of multiple components. A fast transient BK current is activated by Ca2+ entry through high-threshold voltage-activated Ca2+ channels (L- and N-type), and together with other voltage-gated K+ currents, this transient BK current plays a role in AP repolarization.

Non-synaptic ion channels in insects--basic properties of currents and their modulation in neurons and skeletal muscles

Insects are favoured objects for studying information processing in restricted neuronal networks, e.g. motor pattern generation or sensory perception. The analysis of the underlying processes requires knowledge of the electrical properties of the cells involved. These properties are determined by the expression pattern of ionic channels and by the regulation of their function, e.g. by neuromodulators. We here review the presently available knowledge on insect non-synaptic ion channels and ionic currents in neurons and skeletal muscles. The first part of this article covers genetic and structural informations, the localization of channels, their electrophysiological and pharmacological properties, and known effects of second messengers and modulators such as neuropeptides or biogenic amines. In a second part we describe in detail modulation of ionic currents in three particularly well investigated preparations, i.e. Drosophila photoreceptor, cockroach DUM (dorsal unpaired median) neuron and locust jumping muscle. Ion channel structures are almost exclusively known for the fruitfly Drosophila, and most of the information on their function has also been obtained in this animal, mainly based on mutational analysis and investigation of heterologously expressed channels. Now the entire genome of Drosophila has been sequenced, it seems almost completely known which types of channel genes--and how many of them--exist in this animal. There is much knowledge of the various types of channels formed by 6-transmembrane--spanning segments (6TM channels) including those where four 6TM domains are joined within one large protein (e.g. classical Na+ channel). In comparison, two TM channels and 4TM (or tandem) channels so far have hardly been explored. There are, however, various well characterized ionic conductances, e.g. for Ca2+, Cl- or K+, in other insect preparations for which the channels are not yet known. In some of the larger insects, i.e. bee, cockroach, locust and moth, rather detailed information has been established on the role of ionic currents in certain physiological or behavioural contexts. On the whole, however, knowledge of non-synaptic ion channels in such insects is still fragmentary. Modulation of ion currents usually involves activation of more or less elaborate signal transduction cascades. The three detailed examples for modulation presented in the second part indicate, amongst other things, that one type of modulator usually leads to concerted changes of several ion currents and that the effects of different modulators in one type of cell may overlap. Modulators participate in the adaptive changes of the various cells responsible for different physiological or behavioural states. Further study of their effects on the single cell level should help to understand how small sets of cells cooperate in order to produce the appropriate output.

A novel mechanical dissociation technique for studying acutely isolated maturing Drosophila central neurons

A novel mechanical method, for studying acutely isolated maturing Drosophila central neurons, has been developed. Electrophysiological experiments have been carried out to assess the quality of these acutely dissociated neurons. The mechanically dissociated Drosophila central neurons were divided into three categories depending on their size and morphological features. Four types of whole-cell K(+) currents were identified in these neurons, based on their kinetic properties. Moreover, the K(+) currents in the new preparation were found to have similar electrophysiological and pharmacological properties to those reported in the cultured neurons. The new technique, however, was more rapid and convenient. Furthermore, this new system was successfully applied to the isolation of neurons from the adult Drosophila, a process that is extremely difficult by routinely used methods. Thus, this new preparation would be very reliable and applicable to preparing Drosophila central neurons for biophysical and physiological studies.

Mutations affecting the delayed rectifier potassium current in Drosophila

Mutations and pharmacological agents have been used to resolve and analyze several K(+) currents in Drosophila. Mutations that affect channels carrying the voltage-activated I(A) and the Ca(2+) -activated I(CF) have helped greatly in analyzing the structure, function and regulation of these channels. We now report mutations that selectively affect the delayed rectifier current, I(K). Flies mutagenized with ethylmethanesulfonate were screened for temperature-induced paralysis. Paralytic mutants identified in the screen were examined for K(+) currents in the larval body-wall muscles. The z66 mutant larvae showed a significant reduction in I(K). The mutation did not affect other K(+) currents (I(A), I(CF), or I(CS) ) or the Ca(2+) channel current in the muscles. Another mutation, z4, which showed reduced I(K), failed to complement z66. Genetic analysis localized the gene disrupted by z66 and z4 to the left arm of chromosome 3, in the 63A1-63B6 region on polytene chromosomes. The z66 and the z4 mutations, which lie in the Shab K(+) channel gene, provide an opportunity to undertake analysis of the functioning of these channels and to study the role of these channels in membrane excitability.

Molecular separation of two behavioral phenotypes by a mutation affecting the promoters of a Ca-activated K channel

The Drosophila slowpoke gene encodes a BK-type calcium-activated potassium channel. Null mutations in slowpoke perturb the signaling properties of neurons and muscles and cause behavioral defects. The animals fly very poorly compared with wild-type strains and, after exposure to a bright but cool light or a heat pulse, exhibit a "sticky-feet" phenotype. Expression of slowpoke arises from five transcriptional promoters that express the gene in neural, muscle, and epithelial tissues. A chromosomal deletion (ash2(18)) has been identified that removes the neuronal promoters but not the muscle-tracheal cell promoter. This deletion complements the flight defect of slowpoke null mutants but not the sticky-feet phenotype. Electrophysiological assays confirm that the ash2(18) chromosome restores normal electrical properties to the flight muscle. This suggests that the flight defect arises from a lack of slowpoke expression in muscle, whereas the sticky-feet phenotype arises from a lack of expression in nervous tissue.

Unmasking of a novel potassium current in Drosophila by a mutation and drugs

The delayed rectifier potassium current plays a critical role in cellular physiology. This current (I(K)) in Drosophila larvae is believed to be a single current. However, a likely null mutation in the Shab K(+) channel gene (Shab(3)) reduces I(K) but does not eliminate it. This raises a question as to whether or not the entire I(K) passes through channels encoded by one gene. Similarly, an incomplete blockade of I(K) by high concentrations of quinidine, a selective I(K) blocker, raises a question as to whether I(K) consists of two components that are differentially sensitive to quinidine. We have addressed these questions by a combined use of genetics, pharmacology, and physiology. The current component removed by the Shab(3) mutation differed from the remaining component in activation kinetics, inactivation kinetics, threshold of activation, and voltage dependence. The two components showed strong differences in sensitivity to quinidine. Physiological properties of the current component removed by the Shab(3) mutation were similar to those of the quinidine-sensitive fraction of I(K). Complementary to this, properties of the current component remaining in the Shab(3) mutant muscles were similar to those of the quinidine-resistant fraction of I(K). These observations strongly suggest that, in contrast to the current belief, I(K) consists of two components in Drosophila, which are genetically, pharmacologically, and physiologically distinct. These components are being called I(KS) and I(KF). I(KS) is carried via Shab-encoded channels. I(KF) defines a new voltage-activated K(+) current in Drosophila.

Molecular basis for the inactivation of Ca2+- and voltage-dependent BK channels in adrenal chromaffin cells and rat insulinoma tumor cells

Large-conductance Ca2+- and voltage-dependent potassium (BK) channels exhibit functional diversity not explained by known splice variants of the single Slo alpha-subunit. Here we describe an accessory subunit (beta3) with homology to other beta-subunits of BK channels that confers inactivation when it is coexpressed with Slo. Message encoding the beta3 subunit is found in rat insulinoma tumor (RINm5f) cells and adrenal chromaffin cells, both of which express inactivating BK channels. Channels resulting from coexpression of Slo alpha and beta3 subunits exhibit properties characteristic of native inactivating BK channels. Inactivation involves multiple cytosolic, trypsin-sensitive domains. The time constant of inactivation reaches a limiting value approximately 25-30 msec at Ca2+ of 10 microM and positive activation potentials. Unlike Shaker N-terminal inactivation, but like native inactivating BK channels, a cytosolic channel blocker does not compete with the native inactivation process. Finally, the beta3 subunit confers a reduced sensitivity to charybdotoxin, as seen with native inactivating BK channels. Inactivation arises from the N terminal of the beta3 subunit. Removal of the beta3 N terminal (33 amino acids) abolishes inactivation, whereas the addition of the beta3 N terminal onto the beta1 subunit confers inactivation. The beta3 subunit shares with the beta1 subunit an ability to shift the range of voltages over which channels are activated at a given Ca2+. Thus, the beta-subunit family of BK channels regulates a number of critical aspects of BK channel phenotype, including inactivation and apparent Ca2+ sensitivity.

Auxiliary Hyperkinetic beta subunit of K+ channels: regulation of firing properties and K+ currents in Drosophila neurons

Auxiliary Hyperkinetic beta subunit of K+ channels: regulation of firing properties and K+ currents in Drosophila neurons. Molecular analysis and heterologous expression have shown that K+ channel beta subunits regulate the properties of the pore-forming alpha subunits, although how they influence neuronal K+ currents and excitability remains to be explored. We studied cultured Drosophila "giant" neurons derived from mutants of the Hyperkinetic (Hk) gene, which codes for a K+ channel beta subunit. Whole cell patch-clamp recording revealed broadened action potentials and, more strikingly, persistent rhythmic spontaneous activities in a portion of mutant neurons. Voltage-clamp analysis demonstrated extensive alterations in the kinetics and voltage dependence of K+ current activation and inactivation, especially at subthreshold membrane potentials, suggesting a role in regulating the quiescent state of neurons that are capable of tonic firing. Altered sensitivity of Hk currents to classical K+ channel blockers (4-aminopyridine, alpha-dendrotoxin, and TEA) indicated that Hk mutations modify interactions between voltage-activated K+ channels and these pharmacological probes, apparently by changing both the intra- and extracellular regions of the channel pore. Correlation of voltage- and current-clamp data from the same cells indicated that Hk mutations affect not only the persistently active neurons, but also other neuronal categories. Shaker (Sh) mutations, which alter K+ channel alpha subunits, increased neuronal excitability but did not cause the robust spontaneous activity characteristic of some Hk neurons. Significantly, Hk Sh double mutants were indistinguishable from Sh single mutants, implying that the rhythmic Hk firing pattern is conferred by intact Shalpha subunits in a distinct neuronal subpopulation. Our results suggest that alterations in beta subunit regulation, rather than elimination or addition of alpha subunits, may cause striking modifications in the excitability state of neurons, which may be important for complex neuronal function and plasticity.

Contribution of potassium conductances to a time-dependent transition in electrical properties of a cockroach motoneuron soma

Contribution of potassium conductances to a time-dependent transition in electrical properties of a cockroach motoneuron soma. The cell body of the cockroach (Periplaneta americana) fast coxal depressor motoneuron (Df) displays a time-dependent change in excitability. Immediately after dissection, depolarization evokes plateau potentials, but after several hours all-or-none action potentials are evoked. Because K channel blockers have been shown to produce a similar transition in electrical properties, we have used current-clamp, voltage-clamp and action-potential-clamp recording to elucidate the contribution of different classes of K channel to the transition in electrical activity of the neuron. Apamin had no detectable effect on the neuron, but charybdotoxin (ChTX) caused a rapid transition from plateau potentials to spikes in the somatic response of Df to depolarization. In neurons that already produced spikes when depolarized, ChTX increased spike amplitude but did not increase their duration nor decrease the amplitude of their afterhyperpolarization. 4-Aminopyridine (4-AP) (which selectively blocks transient K currents) did not cause a transition from plateau potentials to spikes but did enhance oscillations superimposed on plateau potentials. When applied to neurons that already generated spikes when depolarized, 4-AP could augment spike amplitude, decrease the latency to the first spike, and prolong the afterhyperpolarization. Evidence suggests that the time-dependent transition in electrical properties of this motoneuron soma may result, at least in part, from a fall in calcium-dependent potassium current (IK,Ca), consequent on a gradual reduction in [Ca2+ ]i. Voltage-clamp experiments demonstrated directly that outward K currents in this neuron do fall with a time course that could be significant in the transition of electrical properties. Voltage-clamp experiments also confirmed the ineffectiveness of apamin and showed that ChTX blocked most of IK,Ca. Application of Cd2+ (0.5 mM), however, caused a small additional suppression in outward current. Calcium-insensitive outward currents could be divided into transient (4-AP-sensitive) and sustained components. The action-potential-clamp technique revealed that the ChTX-sensitive current underwent sufficient activation during the depolarizing phase of plateau potentials to enable it to shunt inward conductances. Although the ChTX-sensitive conductance apparently makes little contribution to spike repolarization, the ChTX-resistant IK,Ca does make a significant contribution to this phase of the action potential. The 4-AP-sensitive current began to develop during the rising phase of both action potentials and plateau potentials but had little effect on the electrical activity of the neuron, probably because of its relatively small amplitude.

Long-term effects of prior heat shock on neuronal potassium currents recorded in a novel insect ganglion slice preparation

Brief exposure to high temperatures (heat shock) induces long-lasting adaptive changes in the molecular biology of protein interactions and behavior of poikilotherms. However, little is known about heat shock effects on neuronal properties. To investigate how heat shock affects neuronal properties we developed an insect ganglion slice from locusts. The functional integrity of neuronal circuits in slices was demonstrated by recordings from rhythmically active respiratory neurons and by the ability to induce rhythmic population activity with octopamine. Under these "functional" in vitro conditions we recorded outward potassium currents from neurons of the ventral midline of the A1 metathoracic neuromere. In control neurons, voltage steps to 40 mV from a holding potential of -60 mV evoked in control neurons potassium currents with a peak current of 10.0 +/- 2.5 nA and a large steady state current of 8.5 +/- 2.6 nA, which was still activated from a holding potential of -40 mV. After heat shock most of the outward current inactivated rapidly (peak amplitude: 8.4 +/- 2.4 nA; steady state: 3.6 +/- 2.0 nA). This current was inactivated at a holding potential of -40 mV. The response to temperature changes was also significantly different. After changing the temperature from 38 to 42 degrees C the amplitude of the peak and steady-state current was significantly lower in neurons obtained from heat-shocked animals than those obtained from controls. Our study indicates that not only heat shock can alter neuronal properties, but also that it is possible to investigate ion currents in insect ganglion slices.

Blockade of the delayed rectifier potassium current in Drosophila by quinidine and related compounds

Quinidine is a potent blocker of the delayed rectifier K+ channels (IK). Although it has been used for understanding the physiology of K+ channels in many organisms and for treating cardiac arrhythmia in humans, mechanisms of its interaction with the channel molecule are not well understood. As a first step in understanding these mechanisms, we used the Shaker mutant of Drosophila in which the delayed rectifier can be resolved in complete isolation from other currents and determined the importance of the major groups of quinidine (methoxy, quinoline, quinuclide and the bridge groups) in the blockade of IK. It appears that the quinoline moiety, while possessing little channel-blocking activity by itself, may provide a template for positioning the groups that may be important for affinity and blockade. These groups, in the order of importance in imparting inhibitory activity to quinoline, seemed to be quinuclide > methylene bridge > 6-methoxy group. In particular, the quinoline ring and the quinuclide group, when linked-together by a hydroxymethylene bridge, might be responsible for a major part of the IK blocking activity of quinidine. Action of quinidine was not affected by either quinuclidine, which did not block IK, or by quinoline.

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.

Modulation of the dihydropyridine-sensitive calcium channels in Drosophila by a phospholipase C-mediated pathway

Disruption of phospholipase C-beta (PLC) by the norpA mutations of Drosophila renders flies blind by affecting the light-evoked photoreceptor potential. We report here that the norpA-coded PLC modulates the 1,4-dihydropyridine (DHP)-sensitive Ca2+ channels in larval muscles. The DHP-sensitive current was reduced in the norpA mutants. Application of 1 microM phorbol 12-myristate 13-acetate (TPA) and 1 microM phorbol 12,13-didecanoate (PDD), activators of protein kinase C (PKC), rescued the current in the mutant fibers without significantly affecting the normal current. 4Alpha-phorbol 12,13-didecanoate (4alphaPDD), an inactive analog of PDD, did not affect either the normal or the mutant current. One micromolar bisindolylmaleimide (BIM), an inhibitor of PKC, reduced the current in the normal fibers without affecting the mutant current. 300 microM sn-1,2-dioctanoyl-glycerol (DOG), an analog of diacylglycerol (DAG), increased the current in the mutant fibers. These experiments suggest that the DHP-sensitive Ca2+ channels in Drosophila may be modulated by the PLC-DAG-PKC pathway, and that the same PLC isozyme which is involved in phototransduction in the adult flies may also modulate muscle Ca2+ channels in the larval stage of development.

Presynaptic recordings from Drosophila: correlation of macroscopic and single-channel K+ currents

We have performed direct electrophysiological recordings from Drosophila peptidergic synaptic boutons in situ, taking advantage of a mutation, ecdysone, which causes an increase in size of these terminals. Using patch-clamp techniques, we have analyzed voltage-dependent potassium currents at the macroscopic and single-channel level. The synaptic membrane contained at least two distinct voltage-activated potassium currents with different kinetics and voltage sensitivity: an IA-like current with fast activation and inactivation kinetics and voltage-dependent steady-state inactivation; a complex delayed current that includes a slowly inactivating component, resembling the IK described in other preparations; and a noninactivating component. The IA-like current in these peptidergic boutons is not encoded by the gene Shaker, because it is not affected by null mutations at this locus. Rather, synaptic IA has properties similar to those of the Shal-encoded IA. Single-channel recordings revealed the presence in synaptic membranes of three different potassium channel types (A2, KD, KL), with biophysical properties that could account for the macroscopic currents and resemble those of the Shal, Shab, and Shaw channels described in heterologous expression systems and Drosophila neuronal somata. A2 channels (6-9 pS) have brief open times, and like the macroscopic IA they exhibited voltage-dependent steady-state inactivation and a rapidly inactivating ensemble average current profile. KD channels (13-16 pS) had longer open times, activate and inactivate with much slower kinetics, and may account for the slowly inactivating component of the macroscopic current. KL (44-54 pS) channels produced a noninactivating ensemble average and may contribute to the delayed macroscopic current observed.

In vivo functional role of the Drosophila hyperkinetic beta subunit in gating and inactivation of Shaker K+ channels

The physiological roles of the beta, or auxiliary, subunits of voltage-gated ion channels, including Na+, Ca2+, and K+ channels, have not been demonstrated directly in vivo. Drosophila Hyperkinetic (Hk) mutations alter a gene encoding a homolog of the mammalian K+ channel beta subunit, providing a unique opportunity to delineate the in vivo function of auxiliary subunits in K+ channels. We found that the Hk beta subunit modulates a wide range of the Shaker (Sh) K+ current properties, including its amplitude, activation and inactivation, temperature dependence, and drug sensitivity. Characterizations of the existing mutants in identified muscle cells enabled an analysis of potential mechanisms of subunit interactions and their functional consequences. The results are consistent with the idea that via hydrophobic interaction, Hk beta subunits modulate Sh channel conformation in the cytoplasmic pore region. The modulatory effects of the Hk beta subunit appeared to be specific to the Sh alpha subunit because other voltage- and Ca(2+)-activated K+ currents were not affected by Hk mutations. The mutant effects were especially pronounced near the voltage threshold of IA activation, which can disrupt the maintenance of the quiescent state and lead to the striking neuromuscular and behavioral hyperexcitability previously reported.

Differential expression of membrane currents in dissociated mouse primary sensory neurons

The whole cell configuration of the patch clamp technique has been applied to identify the membrane currents expressed by populations of dissociated mouse primary sensory neurons. Three discrete populations of cells were distinguished on the basis of cell size and the array of currents expressed. Group 1 cells (capacitance 10-30 pF) expressed a Na+ current resistant to tetrodotoxin (1 microM) and a prominent, low threshold, inactivating, K+ current sensitive to 4-aminopyridine (IA). A population (53%) of these small cells responded to capsaicin (10 microM) with an inward current, suggesting a functional correlate with nociceptive "C"-cells. The cells of Group 2 (capacitance 55-85 pF) were characterized by the expression of a Na+ current sensitive to tetrodotoxin and a prominent inward current activated by hyperpolarization (IH). They also showed a variant of the A-type K+ current, which was a low threshold, but sustained K+ current, sensitive to dendrotoxin (30 nM). Group 3 cells, of intermediate size (capacitance 30-55 pF) were similar to Group 2 cells, in that they expressed a tetrodotoxin-sensitive Na+ current and (through reduced in amplitude), IH. The most notable feature of Group 3 cells was the expression of a transient, low threshold Ca2+ current. The differential expression of these conductances was reflected in the behaviour of cells under current clamp control. Each group of cells could thus be distinguished by the selective expression of specific ionic conductances which correlated clearly with cell size, suggesting a correlation with well recognised functional differentiation of sensory neurons. The selective expression of specific subsets of membrane channels may provide valuable markers in studying the developmental regulation of phenotype in this population of cells.

Differential modulation of potassium currents by cAMP and its long-term and short-term effects: dunce and rutabaga mutants of Drosophila

The cAMP concentration in Drosophila is increased by mutations of the dunce (dnc) gene and decreased by mutations of the rutabaga (rut) gene. Such mutants provide a unique means for exploring the role of cAMP in functional and developmental regulation of membrane currents. Four distinct K+ currents have been identified in Drosophila larval muscle fibers, i.e. the voltage-activated transient IA and delayed IK and the Ca(2+)-activated fast ICF and slow ICS. Results from our voltage-clamp studies indicated that both IA and IK were increased in dnc alleles. Normal muscle fibers treated with dibutyryl-cAMP showed a similar increase of IA, but no significant effect on IK. In contrast to the dnc alleles, the rut mutations appeared to enhance ICS greatly while leaving the amplitude of other currents largely unchanged. In addition, the dibutyryl-cAMP-induced increase in IA was not observed in rut fibers. Caffeine and W7, which are known to interfere with several second messenger pathways, also modulated K+ currents in larval muscle fibers. The currents in dnc and rut fibers showed strikingly altered responses to caffeine and W7. The results demonstrate that the various K+ currents in Drosophila muscles are affected by altered cAMP cascades in the mutants. The fact that not all dnc and rut mutant defects can be mimicked or reversed by acute application of cAMP suggests that long-term modulation of K+ currents by cAMP may involve mechanisms distinct from the short-term effect of cAMP.

mSlo, a complex mouse gene encoding "maxi" calcium-activated potassium channels

Complementary DNAs (cDNAs) from mSlo, a gene encoding calcium-activated potassium channels, were isolated from mouse brain and skeletal muscle, sequenced, and expressed in Xenopus oocytes. The mSlo-encoded channel resembled "maxi" or BK (high conductance) channel types; single channel conductance was 272 picosiemens with symmetrical potassium concentrations. Whole cell and single channel currents were blocked by charybdotoxin, iberiotoxin, and tetraethylammonium ion. A large number of variant mSlo cDNAs were isolated, indicating that several diverse mammalian BK channel types are produced by a single gene.

Whole-cell K+ currents in fresh and cultured cells of the human and monkey retinal pigment epithelium

1. Whole-cell potassium currents of freshly isolated human (adult and fetal) and monkey (adult) retinal pigment epithelial (RPE) cells, as well as cultured human and monkey RPE cells were studied using the patch-clamp technique. 2. In freshly isolated adult cells of both species, two currents were observed in the voltage range from -150 to +50 mV: an outwardly rectifying current and an inwardly rectifying current. These currents were also found in cultured cells of both species. 3. The outwardly rectifying current in freshly isolated adult human and monkey cells and some cultured cells was evoked by depolarizing voltage pulses more positive that -30 mV. The current activated with a sigmoidal time course after a brief delay, and was virtually non-inactivating. The conductance associated with the current was half-maximal at -16.4 mV for fresh human cells and -13.5 mV for fresh monkey cells, but was shifted 16.0 and 17.7 mV in the positive direction in cultured human and monkey cells, respectively. The reversal potential of the current in both human and monkey cells matched the potassium equilibrium potential (EK) over a wide range of external potassium concentrations. This current was blocked by 20 mM tetraethylammonium. 4. A membrane current that exhibited inward rectification was observed with hyperpolarizing voltage pulses. The zero-current potential of this current was close to EK. This current was blocked by 2 mM Ba2+ and 2 mM Cs+. In cultured human and monkey cells, but not in fresh cells, this current exhibited an inactivation when voltage pulses were more negative than -120 mV. External Na+ was responsible for the inactivation, as the inactivation was removed in a Na(+)-free solution. 5. Membrane currents in freshly isolated fetal human RPE cells were remarkably different from those in adult cells. A transient outward current resembling the A-type potassium current was observed as the dominant membrane current in freshly isolated fetal human cells. This current activated when voltage pulses were more positive than -30 mV. It inactivated rapidly after reaching a maximal level. Application of 5 mM 4-aminopyridine (4-AP) completely blocked this current. Although this current was never observed in fresh adult cells, it was found in 33% of the cultured adult cells with similar kinetics, ion selectivity, and pharmacological properties. 6. In about 26% of the freshly isolated fetal human cells, a more slowly activating outward current, which resembled the delayed rectifier, was found to co-exist with the transient outward current.(ABSTRACT TRUNCATED AT 400 WORDS)

Ionic channels in cultured Drosophila neurons

Cultured "giant" Drosophila neurons derived from cytokinesis-arrested embryonic neuroblasts express various membrane channels and excitability patterns. Both current- and voltage-clamp recordings could be performed on the same neuron owing to the large cell size, thus making it possible to elucidate the functional role of individual types of channels. This culture system has been used to analyze the mutational perturbations in ion channels and the resultant alterations in membrane excitability.

Transient outward currents in cochlear ganglion neurons of the chick embryo

Cochlear ganglion neurons were isolated from chick embryos and membrane currents recorded using the patch-clamp technique. Depolarizing voltage steps elicited transient outward currents whose inactivation was best fitted by a double-exponential function with time constants < 30 ms and > 100 ms. The fast inactivating transient outward current (Ito,f) had a threshold for activation of -61 +/- 5.5 mV; steady-state inactivation was voltage-dependent between -90 and -60 mV, with half-inactivation near -75 mV. The slowly inactivating outward current (Ito,s) showed an activation threshold of 34 +/- 4 mV. Half-inactivation was at -67 +/- 3 mV. Ito,f was blocked by 4-aminopyridine which did not affect Ito,s. The effect was concentration- and voltage-dependent. Tetraethylammonium had no effect on either fast or slow transient currents but reduced the amplitude of the non-inactivating outward current in a dose-dependent manner. Ito,f was strongly inhibited by removing Ca2+ from the extracellular bathing solution. Cobalt ions inhibited Ito,f in a dose-dependent manner between 2 and 20 mM. The inhibitory effect of Co2+ was voltage-dependent, displaying a bell-shaped inhibition curve as a function of membrane voltage, maximal inhibition occurring between -20 and 0 mV. Ca2+ removal did not affect Ito,s and partially reduced the amplitude of the steady-state current. These results provide kinetic and pharmacological evidence for the presence of two distinct transient outward currents in cochlear neurons. These currents may play a role in the first synaptic relay of sound transmission.

Development of Na(+)- and K(+)-currents in the cochlear ganglion of the chick embryo

The development of Na(+)- and K(+)-currents in the primary afferent neurons of the cochlear ganglion was studied using the patch-clamp technique. Cells were dissociated between days 6 and 17 of development and membrane currents recorded within the following 24 h. Outward currents were the first to appear between days 6 and 7 of embryonic development and their magnitude increased throughout development from 200 pA on day 7 to 900 pA on days 14-16. Threshold for activation decreased by 20 mV between days 8 and 14. Outward currents were absent when Cs+ replaced K+ in the pipette and were partially blocked by external tetraethylammonium. Outward currents contained at least three components: (i) a non-inactivating outward current, similar to the delayed-rectifier, predominating in mature neurons; (ii) a slowly inactivating current (tau about 200 ms), most evident in early and intermediate stages (days 7-10); and (iii) a rapidly inactivating outward current (tau about 20 ms) similar to the A-current (IA) described in other neurons, which was distinctly expressed in mature neurons. Sodium currents were identified as fast transient inward currents, sensitive to tetrodotoxin and extracellular Na(+)-removal. They appeared later than K(+)-currents and increased in size from about 100 pA between days 9-11 to 600 pA by days 13-16. The development of membrane currents in cochlear ganglion neurons corresponded to defined stages of the innervation pattern of the chick cochlea [Whitehead and Morest (1985) Neuroscience 14, 255-276]. These currents could be functionally related to the establishment of synaptic connections between transducing cells and primary afferent neurons.

A component of calcium-activated potassium channels encoded by the Drosophila slo locus

Calcium-activated potassium channels mediate many biologically important functions in electrically excitable cells. Despite recent progress in the molecular analysis of voltage-activated K+ channels, Ca(2+)-activated K+ channels have not been similarly characterized. The Drosophila slowpoke (slo) locus, mutations of which specifically abolish a Ca(2+)-activated K+ current in muscles and neurons, provides an opportunity for molecular characterization of these channels. Genomic and complementary DNA clones from the slo locus were isolated and sequenced. The polypeptide predicted by slo is similar to voltage-activated K+ channel polypeptides in discrete domains known to be essential for function. Thus, these results indicate that slo encodes a structural component of Ca(2+)-activated K+ channels.

Alteration of four identified K+ currents in Drosophila muscle by mutations in eag

Voltage-clamp analysis of Drosophila larval muscle revealed that ether à go-go (eag) mutations affected all identified potassium currents, including those specifically eliminated by mutations in the Shaker or slowpoke gene. Together with DNA sequence analysis, the results suggest that the eag locus encodes a subunit common to different potassium channels. Thus, combinatorial assembly of polypeptides from different genes may contribute to potassium channel diversity.

Two transient potassium currents in layer V pyramidal neurones from cat sensorimotor cortex

1. Two transient outward currents were identified in large pyramidal neurones from layer V of cat sensorimotor cortex ('Betz cells') using an in vitro brain slice preparation and single-microelectrode voltage clamp. Properties of the currents deduced from voltage-clamp measurements were reflected in neuronal responses during constant current stimulation. 2. Both transient outward currents rose rapidly after a step depolarization, but their subsequent time course differed greatly. The fast-transient current decayed within 20 ms, while the slow-transient current took greater than 10 s to decay. Raised extracellular potassium reduced current amplitude. Both currents were present in cadmium-containing or calcium-free perfusate. 3. Tetraethylammonium had little effect on the slow-transient current at a concentration of 1 mM, but the fast-transient current was reduced by 60%. 4-Aminopyridine had little effect on the fast-transient current over the range 20 microM-2 mM, but these concentrations reduced the slow-transient current and altered its time course. 4. Both transient currents were evoked by depolarizations below action potential threshold. The fast-transient current was evoked by a 7 mV smaller depolarization than the slow-transient current, but its chord conductance increased less steeply with depolarization. 5. Voltage-dependent inactivation of the fast-transient was steeper than that of the slow-transient current (4 vs. 7 mV per e-fold change), and half-inactivation occurred at a less negative potential (-59 vs. -65 mV). The activation and inactivation characteristics of each current overlapped, however, implying the existence of a steady 'window current' extending over a range of approximately 14 mV beginning negative to action potential threshold. 6. The fast-transient current displayed a clear voltage dependence of both its activation and inactivation kinetics, whereas the slow-transient current did not. Recovery of either current from inactivation took about 1 s near -70 mV. The recovery of the slow-transient current became faster with hyperpolarization. 7. The contribution of each transient current to repolarization of the action potential was assessed from pharmacological responses. Blockade of calcium influx had little or no effect on the rate of action potential repolarization, whereas the selective reduction of either transient current caused significant slowing of repolarization. 8. We conclude that Betz cells possess at least two transient potassium currents, each a member of the rapidly expanding family of voltage-gated potassium currents that have been identified in various cell types.(ABSTRACT TRUNCATED AT 400 WORDS)

Calcium-dependent transient potassium outward current in the marine ciliate Euplotes vannus

In the marine hypotrichous ciliate Euplotes vannus, the transient K+ outward current, IK fast, was studied by use of a single-microelectrode voltage-clamp equipment. Activation and inactivation kinetics, and steady-state inactivation are comparable to the properties of A-currents. Not typical for this type of current is its insensitivity to either 4-AP or 3,4-AP and its Ca2+ dependence which was derived from its inhibition by either extracellular Cd2+, La3+, D-600, or by intracellular BAPTA. Actual amplitudes of IK fast were obtained from a composite current, by subtraction of early parts of a slowly activating K+ current, IK slow, and of the early, transient Ca2+ inward current, ICa fast, that is typical for ciliates. IK fast counteracts ICa fast during the first milliseconds after onset of depolarization such that the composite current is purely outward directed.

Two transient outward currents in histamine neurones of the rat hypothalamus in vitro

1. The transient outward current exhibited by the histamine neurones of the tuberomammillary nucleus was studied using the single-electrode voltage clamp technique in an in vitro rat hypothalamic slice preparation. 2. The transient outward current exhibited steady-state inactivation at the resting potential. Inactivation was removed by priming hyperpolarization with a V1/2 of -85 +/- 1.2 mV, while the V1/2 for activation was -60.3 +/- 2.1 mV. 3. The decay of the transient outward current was best fitted by two exponentials with time constants of 104 +/- 36 and 568 +/- 128 ms. These two components were provisionally termed IA,f and IA,s for the fast and slowly decaying currents, respectively. 4. Removal of inactivation was time dependent; inactivation was fully removed by hyperpolarizing pulses to -110 mV of 200 ms or greater duration. Removal of inactivation of IA,f was rapid, becoming complete with hyperpolarizing pre-pulses of 50 ms or greater, while removal of inactivation of IA,s was not complete until hyperpolarizing pre-pulses were 200 ms in duration. 5. The fast decaying current IA,f was selectively blocked by 1 mM-4-aminopyridine. Tetraethylammonium chloride (10 mM) had no effect on either IA,f or IA,s. 6. The inactivation curves for IA,s, determined both by using the values obtained from the amplitude of the computed slower exponential function as well as that of the current remaining in 1 mM 4-aminopyridine, were negative to those of IA,f. Similarly derived activation curves for IA,s were positive to those of IA,f. 7. Superfusion with a nominal 0 Ca2+ medium containing 10 mM-Mg2+ did not reduce the maximal transient outward current. 8. The reversal potential of IA,s with 2.5 mM-K+ in the medium was -95 +/- 3 mV; the reversal potential of IA,f was at least 15 mV negative to that of IA,s. 9. It is concluded that histaminergic tuberomammillary neurones possess at least two transient outward currents which can be distinguished on the basis of their rates of decay, 4-aminopyridine sensitivity, voltage dependence and reversal potentials.

A rapidly inactivating Ca2(+)-dependent K+ current in pheochromocytoma cells (PC12) of the rat

The membrane electrical properties of undifferentiated pheochromocytoma cells of the rat (PC12) were studied using both current- and voltage-clamp techniques with the use of low-resistance blunt-tipped micropipettes (patch electrodes). In the presence of tetrodotoxin (TTX, 2-3 microM), a spike-like wave form with a prominent after-hyperpolarization (AHP) was recorded following brief (less than 10 ms) depolarizing current pulses. The inorganic divalent cations, Cd2+ (0.5 mM), Mn2+ (4 mM), and 0 mM Ca2+/4 mM Mg2+ solution prolonged the duration, attenuated the AHP, slowed the rate of repolarization, and slightly enhanced the amplitude of this wave form. A rapidly inactivating outward current was recorded in over 70% of the cells under voltage-clamp conditions. This transient current was elicited at about -30 mV, and was blocked by tetraethylammonium (5 mM), inorganic divalent cations (Cd2+, 0.5 mM; Mn2+, 4 mM; Ba2+, 3 mM), and removal of Ca2+ (0 mM Ca2+/4 mM Mg2+) from the local perfusion medium. In addition, 4-aminopyridine (5 mM), which blocks the transient outward K+ current IA in a variety of excitable cells, did not have any appreciable effect on this rapidly inactivating current. Moreover, it was possible to elicit the current at a holding potential of -40 mV. The reversal potential of this current was -90 mV, and shifted positively when extracellular K+ concentrations were elevated. It is concluded that PC12 cells have a rapidly inactivating Ca2(+)-dependent K+ current. A possible explanation for the transient nature of this current may be the presence of an effective intracellular Ca2+ buffering (uptake or extrusion) system.

A voltage-dependent outward current with fast kinetics in single smooth muscle cells isolated from rabbit portal vein

1. Single smooth muscle cells were isolated enzymatically from the rabbit portal vein. They were voltage-clamped at room temperature using the whole-cell configuration of the patch-clamp technique. 2. When cells were bathed in physiological salt solution, depolarization from a holding potential of -70 mV elicited a time-dependent outward current which reached a maximum within 0.2-0.5 s, but when a more negative holding potential was used, an additional outward current could be activated. The current (Ifo) developed rapidly, was transient and seemed to be carried by potassium ions (K+). 3. The steady-state inactivation plot for Ifo was steeply voltage-dependent between -90 and -60 mV, current being 50% inactivated at -78 mV. The activation threshold was around -65 mV. The activation and inactivation kinetics were fast and voltage-dependent. When the test potential was -35 mV, peak current occurred after about 15 ms and the decay was complete within 250 ms. Recovery from inactivation was maximal after 1 s at -100 mV but was about five times slower at -70 mV. 4. The outward current Ifo was blocked completely by 4-aminopyridine (5 mM) or phencyclidine (0.1 mM), but was insensitive to tetraethylammonium ions (32 mM), apamin (0.1 microM), charybdotoxin from the venom of Leiurus quinquestriatus (0.1 microM), toxin-I from the venom of Dendroaspis polylepis (1 microM) or the putative K+ channel opener, cromakalim (10 microM). 5. The steady-state inactivation range and activation threshold, kinetics of activation and inactivation all showed a marked dependence on the concentration of divalent cations in the bathing solution. This effect was consistent with the hypothesis that Ifo was affected by membrane surface potential. The current did not seem to be Ca2+-activated. 6. Ifo closely resembled the A-current which has been described previously in neurones but not in smooth muscle.

Complete separation of four potassium currents in Drosophila

A number of voltage-activated and Ca2+ activated K+ currents are known to coexist and play a major role in a wide variety of cellular processes including neuromuscular phenomena. Separation of these currents is important for analyzing their individual functional roles and for understanding whether or not they are mediated by entirely different channels. In Drosophila, we have now been able to manipulate four different K+ currents, individually and in combination with one another, by a combined use of mutations and pharmacological agents. This allows analysis of the physiological and molecular properties of different K+ channels and of the role of individual currents in membrane excitability.

A family of putative potassium channel genes in Drosophila

Mutant flies in which the gene coding for the Shaker potassium channel is deleted still have potassium currents similar to those coded by the Shaker gene. This suggests the presence of a family of Shaker-like genes in Drosophila. By using a Shaker complementary DNA probe and low-stringency hybridization, three additional family members have now been isolated, Shab, Shaw, and Shal. The Shaker family genes are not clustered in the genome. The deduced proteins of Shab, Shaw, and Shal have high homology to the Shaker protein; the sequence identity of the integral membrane portions is greater than 50 percent. These genes are organized similarly to Shaker in that only a single homology domain containing six presumed membrane-spanning segments common to all voltage-gated ion channels is coded by each messenger RNA. Thus, potassium channel diversity could result from an extended gene family, as well as from alternate splicing of the Shaker primary transcript.

Central projections of peripheral mechanosensory cells with increased excitability in Drosophila mosaics

The formation and maintenance of the central projections of identified bristle mechanosensory neurons with altered excitability were examined in Drosophila mosaics. Two mutants, eag (ether à go-go) and Sh (Shaker), are known to increase excitability of both nerve and muscle cells and enhance synaptic transmission by affecting different types of K+ currents. The eag Sh double mutant produces a synergistic effect, resulting in a greatly increased level of spontaneous neuronal activity and extreme behavioral phenotypes. By constructing mosaic flies containing small patches of doubly mutant cuticle, it was possible to alter the excitability of only one or two identified sensory cells without affecting the surrounding tissue. In these mosaic flies, the doubly mutant sensory cells were more responsive to tactile stimulation. A CoCl2 backfilling technique was utilized in staining the sensory cell projections. Both qualitative and quantitative comparisons were made between projections of cells having normal and increased levels of excitability. The length, branching characteristics, and number of terminal varicosities were analyzed for each sensory cell projection. Results indicate that, at the light microscopy level, these characteristics were not obviously altered by an increased level of excitability.

Electrogenic responses elicited by transmembrane depolarizing current in aerated body wall muscles of Drosophila melanogaster larvae

Electrical excitability of the longitudinal ventrolateral body wall muscle of the third instar larva of Drosophila melanogaster was demonstrated. This is in contrast to previous papers which have reported that this muscle is electrically inexcitable. It was found that an air supply to the muscle through the tracheoles is essential for maintaining its excitability. In an aerated preparation, the muscle maintained a resting potential of around -80 mV for more than 1.5 h, while a non-aerated muscle depolarized to about -30 mV within 30 min. Muscles with resting potentials larger than -70 mV showed graded regenerative potentials with a double-peaked configuration in response to transmembrane depolarizing current. A tetrodotoxin- (TTX-)sensitive, voltage-dependent inward sodium current, and a tetraethylammonium- (TEA-)sensitive, voltage-dependent outward potassium current were found to be responsible for the first peak of the electrogenic response of this muscle. The rising phase of the second peak was caused by a cobalt/manganese-sensitive, voltage-dependent inward calcium current that had a threshold level near -40 mV. Elimination by TEA or barium of the delayed rectification following the first peak caused the second peak to be triggered at a lower threshold. The second peak was profoundly elongated by barium, and this effect was antagonized by external calcium. Thus, the falling phase of the second peak was most likely driven by a calcium-dependent, outward potassium current.

Transient calcium-dependent potassium current in magnocellular neurosecretory cells of the rat supraoptic nucleus

1. Magnocellular neurosecretory neurones were impaled in the supraoptic nucleus of perfused explants of rat hypothalamus. Membrane currents were studied at 35 degrees C using the single-microelectrode voltage-clamp technique. 2. Depolarizing voltage steps applied from -100 mV evoked a transient outward current (TOC) from a threshold of -75 mV. From this potential, the amplitude of the current increased non-linearly with voltage. 3. Following its activation TOC reached a peak within 7 ms and subsequently decayed monotonically with a time constant of 30 ms. This time constant did not vary significantly with voltage between -75 and -55 mV. 4. The TOC showed complete steady-state inactivation at potentials positive to -55 mV. Inactivation was removed by hyperpolarization, with a mid-point near -80 mV. The removal of inactivation followed a complex time course with distinct fast (tens of milliseconds) and slow (hundreds of milliseconds) components. 5. Tail current measurements revealed that the TOC equilibrium potential (ETOC) lies near -97 mV in the presence of 3 mM [K+]o. Increasing [K+]o caused a decrease of TOC amplitude and a shift in ETOC of 57 mV/log [K+]o. The TOC is therefore predominantly a K+ current. 6. The TOC was unaffected by tetraethylammonium (up to 12 mM) but was reversibly reduced by 4-aminopyridine (ca. 50% block at 1.0 mM) and dendrotoxin (ca. 50% block at 4 nM). 7. The TOC was strongly inhibited (greater than 70%) by adding Co2+ or Mn2+ (1-3 mM) or Cd2+ (50-400 microM) to Ca-containing solutions, or by removal of Ca2+ from the perfusate. These effects were not accompanied by detectable changes in threshold voltage. The amplitude of TOC was also depressed by the organic Ca2+ channel blocker methoxyverapamil (D600). Finally replacement of Ca2+ by Ba2+ in the perfusate completely and reversibly abolished the TOC. 8. These findings suggest that neurosecretory neurones of the rat supraoptic nucleus display a transient K+ current which is strongly dependent on the presence of external Ca2+. The possible role of this current is briefly discussed.

A modulatory action of divalent cations on transient outward current in cultured rat sensory neurones

1. The effects of some divalent cations on the A-current (IA) in cultured rat dorsal root ganglion cells (DRGs) were studied using whole-cell patch recording. 2. IA was not affected by omission of calcium from the external medium; however it was significantly depressed by manganese (10 mM) applied by pressure ejection. This depressant effect of manganese resulted from a depolarizing shift of the activation curve by 17 mV, associated with only a slight reduction of the maximum conductance. At 10 mM manganese also caused a depolarizing shift of the steady-state inactivation curve by 34 mV. Divalent cations other than manganese also gave positive shifts of the steady-state activation and inactivation curves for IA but were of different potency; the sequence was: Cd2+ greater than Mn2+ = Co2+ greater than Mg2+. 3. A dose-response curve for the depolarizing shift of the activation and inactivation curves of IA, as a function of manganese concentration, could be fitted by a single binding site model with an apparent dissociation constant of approximately 17 mM. The depolarizing shift of the inactivation curve was on average twice as large as that of the activation curve. 4. In contrast to its effect on IA, manganese (10 mM) did not cause any appreciable change in the voltage dependence of the activation curve for the delayed rectifier K+ current. 5. A low concentration of manganese (1 mM) increased the amplitude of IA recorded at pre-pulse potentials ranging from -50 to -70 mV. This augmentation of IA resulted from a positive shift of the inactivation curve by 6 mV without an appreciable shift of the activation curve; as a result a population of A-channels is released from inactivation over pre-pulse potentials from -50 to -70 mV. 6. These results show that divalent cations can evoke a depolarizing shift of both the activation and inactivation gates controlling IA; this causes either depression or augmentation of IA, depending on the species and concentration of the divalent cation, and also on the pre- pulse potential used to de-inactivate IA. This modulatory effect of divalent cations on the gating of IA appears to reflect binding to a specific, saturable site, either the A-channel protein itself, or phospholipids electrically close to the gating apparatus.

Ion channel expression by white matter glia: I. Type 2 astrocytes and oligodendrocytes

White matter is a compact structure consisting primarily of neuronal axons and glial cells. As in other parts of the nervous system, the function of glial cells in white matter is poorly understood. We have explored the electrophysiological properties of two types of glial cells found predominantly in white matter: type 2 astrocytes and oligodendrocytes. Whole-cells and single-channel patch-clamp techniques were used to study these cell types in postnatal rat optic nerve cultures prepared according to the procedures of Raff et al. (Nature, 303:390-396, 1983b). Type 2 astrocytes in culture exhibit a "neuronal" channel phenotype, expressing at least six distinct ion channel types. With whole-cell recording we observed three inward currents: a voltage-sensitive sodium current qualitatively similar to that found in neurons and both transient and sustained calcium currents. In addition, type 2 astrocytes had two components of outward current: a delayed potassium current which activated at 0 mV and an inactivating calcium-dependent potassium current which activated at -30 mV. Type 2 astrocytes in culture could be induced to fire single regenerative potentials in response to injections of depolarizing current. Single-channel recording demonstrated the presence of an outwardly rectifying chloride channel in both type 2 astrocytes and oligodendrocytes, but this channel could only be observed in excised patches. Oligodendrocytes expressed only one other current: an inwardly rectifying potassium current that is mediated by 30- and 120-pS channels. Because these channels preferentially conduct potassium from outside to inside the cell, and because they are open at the resting potential of the cell, they would be appropriate for removing potassium from the extracellular space; thus it is proposed that oligodendrocytes, besides myelinating axons, play an important role in potassium regulation in white matter. The conductances present in oligodendrocytes suggest a "modulated Boyle and Conway mechanism" of potassium accumulation.

Both barium and calcium activate neuronal potassium currents

Amphibian spinal neurons in culture possess both rapidly inactivating and sustained calcium-dependent potassium current components, similar to those described for other cells. Divalent cation-dependent whole-cell outward currents were isolated by subtracting the voltage-dependent potassium currents recorded from Xenopus laevis neurons in the presence of impermeant cadmium (100-500 microM) from the currents produced without cadmium but in the presence of permeant divalent cations (50-100 microM). These concentrations of permeant ions were low enough to avoid contamination by macroscopic inward currents through calcium channels. Calcium-dependent potassium currents were reduced by 1 microM tetraethylammonium. These currents can also be activated by barium or strontium. Barium as well as calcium activated outward currents in young neurons (6-8 hr) and in relatively mature neurons (19-26 hr in vitro). However, barium influx appeared to suppress the sustained voltage-dependent potassium current in most cells. Barium also activated at least one class of potassium channels observed in excised membrane patches, while blocking others. The blocking action may have masked and hindered detection of the stimulatory action of barium in other systems.

A calcium-dependent potassium current is increased by a single-gene mutation in Paramecium

The membrane currents of wild type Paramecium tetraurelia and the behavioral mutant teaA were analyzed under voltage clamp. The teaA mutant was shown to have a greatly increased outward current which was blocked completely by the combined use of internally delivered Cs+ and external TEA+. This, along with previous work (Satow, Y., Kung, C., 1976, J. Exp. Biol. 65:51-63) identified this as a K+ current. It was further found to be a calcium-activated K+ current since this increased outward K+ current cannot be elicited when the internal calcium is buffered with injected EGTA. The mutation pwB, which blocks the inward calcium current, also blocks this increased outward K+ current in teaA. This shows that this mutant current is activated by calcium through the normal depolarization-sensitive calcium channel. While tail current decay kinetic analysis showed that the apparent inactivation rates for this calcium-dependent K+ current are the same for mutant and wild type, the teaA current activates extremely rapidly. It is fully activated within 2 msec. This early activation of such a large outward current causes a characteristic reduction in the amplitude of the action potential of the teaA mutant. The teaA mutation had no effect on any of the other electrophysiological parameters examined. The phenotype of the teaA mutant is therefore a general decrease in responsiveness to depolarizing stimuli because of a rapidly activating calcium-dependent K+ current which prematurely repolarizes the action potential.

Single-channel and genetic analyses reveal two distinct A-type potassium channels in Drosophila

Whole-cell and single-channel voltage-clamp techniques were used to identify and characterize the channels underlying the fast transient potassium current (A current) in cultured myotubes and neurons of Drosophila. The myotube (A1) and neuronal (A2) channels are distinct, differing in conductance, voltage dependence, and gating kinetics. The myotube currents have a faster and more voltage-dependent macroscopic inactivation rate, a larger steady-state component, and a less negative steady-state inactivation curve than the neuronal currents. The myotube channels have a conductance of 12 to 16 picosiemens, whereas the neuronal channels have a conductance of 5 to 8 picosiemens. In addition, the myotube channel is affected by Shaker mutations, whereas the neuronal channel is not. Together, these data suggest that the two channels are separate molecular structures, the expression of which is controlled, at least in part, by different genes.

Action potential repolarization and a fast after-hyperpolarization in rat hippocampal pyramidal cells

1. The repolarization of the action potential, and a fast after-hyperpolarization (a.h.p.) were studied in CA1 pyramidal cells (n = 76) in rat hippocampal slices (28-37 degrees C). Single spikes were elicited by brief (1-3 ms) current pulses, at membrane potentials close to rest (-60 to -70 mV). 2. Each action potential was followed by four after-potentials: (a) the fast a.h.p., lasting 2-5 ms; (b) an after-depolarization; (c) a medium a.h.p., (50-100 ms); and (d) a slow a.h.p. (1-2 s). Both the fast a.h.p. and the slow a.h.p. (but not the medium a.h.p.) were inhibited by Ca2+-free medium or Ca2+-channel blockers (Co2+, Mn2+ or Cd2+); but tetraethylammonium (TEA; 0.5-2 nM) blocked only the fast a.h.p., and noradrenaline (2-5 microM) only the slow a.h.p. This suggests that two Ca2+-activated K+ currents were involved: a fast, TEA-sensitive one (IC) underlying the fast a.h.p., and a slow noradrenaline-sensitive one (IAHP) underlying the slow a.h.p. 3. Like the fast a.h.p., spike repolarization seems to depend on a Ca2+-dependent K+ current of the fast, TEA-sensitive kind (IC). The repolarization was slowed by Ca2+-free medium, Co2+, Mn2+, Cd2+, or TEA, but not by noradrenaline. Charybdotoxin (CTX; 30 nM), a scorpion toxin which blocks the large-conductance Ca2+-activated K+ channel in muscle, had a similar effect to TEA. The effects of TEA and Cd2+ (or Mn2+) showed mutual occlusion. Raising the external K+ concentration reduced the fast a.h.p. and slowed the spike repolarization, whereas Cl- loading of the cell was ineffective. 4. The transient K+ current, IA, seems also to contribute to spike repolarization, because: (a) 4-aminopyridine (4-AP; 0.1 mM), which blocks IA, slowed the spike repolarization; (b) depolarizing pre-pulses, which inactivate IA, had a similar effect; (c) hyperpolarizing pre-pulses speeded up the spike repolarization; (d) the effects of 4-AP and pre-pulses persisted during Ca2+ blockade (like IA); and (e) depolarizing pre-pulses reduced the effect of 4-AP. 5. Pre-pulses or 4-AP broadened the spike less, and in a different manner, than Ca2+-free medium, Cd2+, Co2+, Mn2+, TEA or CTX. The former broadening was uniform, with little effect on the fast a.h.p., whereas the latter affected mostly the last two-thirds of the spike repolarization and abolished the fast a.h.p.(ABSTRACT TRUNCATED AT 400 WORDS)

The use of Xenopus oocytes for the study of ion channels

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

A Drosophila mutation that eliminates a calcium-dependent potassium current

A mutation of Drosophila, slowpoke (slo), specifically abolishes a Ca2+-dependent K+ current, IC, from dorsal longitudinal flight muscles of adult flies. Other K+ currents remain normal, providing evidence that IC is mediated by a molecularly distinguishable set of channels. The pharmacological properties of IC are similar to those of Ca2+-dependent currents in some vertebrate cells. The muscle action potential was significantly lengthened in slo flies, indicating that IC plays the major role in its repolarization.

Two distinct calcium-activated potassium currents in larval muscle fibres of Drosophila melanogaster

The non-synaptic membrane currents of muscle fibres have been studied in late embryogenesis of Drosophila melanogaster using the voltage-clamp technique in wild-type and Shaker mutant third instar larvae. Five currents were found in the wild type muscle membrane at this embryonic stage: one fast inward Ca current (ICa), two fast outward K currents (IA and IAcd) and two slow outward K currents (IK and IC). IAcd and IC are Ca-dependent. Several procedures were used to separate IAcd from IA: IAcd is present in Shaker mutants which are characterized by the absence of IA (Salkoff and Wyman 1981); IAcd, but not IA, is suppressed by Co2+ (10 mM) or La3+ (1 mM); IAcd shows steady-state inactivation at more positive potentials than IA; IAcd, unlike IA, is 3,4-diaminopyridine (3,4-DAP) resistant. Furthermore, tetraethylammonium (TEA, 20 mM) which is known to be uneffective on IA, blocks IAcd. IAcd could not be triggered by using strontium or barium as calcium substitutes. By partial substitution of Ca by Ba or Sr ions, it was found that Ba, but not Sr, blocks the IAcd channel. A non-inactivating, TEA sensitive, Ca-dependent K current (IC), which gave N-shaped I-V plots, could be separated from IK by using Ca-channel blockers. IC and IK activate at membrane potentials of about -25 mV and -10 mV, respectively. The participation of IAcd and IC to membrane electrophysiology is discussed.

Altered K+ channel expression in abnormal T lymphocytes from mice with the lpr gene mutation

The observation that voltage-dependent K+ channels are required for activation of human T lymphocytes suggests that pathological conditions involving abnormal mitogen responses might be reflected in ion channel abnormalities. Gigaohm seal techniques were used to study T cells from MRL/MpJ-lpr/lpr mice; these mice develop generalized lymphoproliferation of functionally and phenotypically abnormal T cells and a disease resembling human systemic lupus erythematosus. The number and predominant type of K+ channels in T cells from these mice differ dramatically from those in T cells from control strains and a congenic strain lacking the lpr gene locus. Thus an abnormal pattern of ion channel expression has now been associated with a genetic defect in cells of the immune system.