Cloning and functional expression of rat eag2, a new member of the ether-à-go-go family of potassium channels and comparison of its distribution with that of eag1.

A second mammalian gene for the ether-à-go-go (eag) potassium channel has been cloned from the rat, and its predicted protein sequence is 70% identical to that of rat ether-à-go-go1 with a further 10% conservatively replaced residues. The rat eag2 mRNA was predominantly expressed in neural tissue and was not detected in adult skeletal, cardiac, or smooth muscle. Within the brain, its distribution overlaps that of rat ether-à-go-go1 in specific regions within the cortex and olfactory bulb, but was differentially distributed in other locations, being scanty within the cerebellum, and most notably present in the thalamus, inferior colliculus, and certain brainstem nuclei. Heterologous expression of rat eag2 in HEK-293 cells gave rise to a voltage-gated, noninactivating potassium current, active at the cells' resting potential and blocked by low nanomolar concentrations of cytosolic calcium. Thus, in neurones, this current is likely to impart a modulation in membrane conductance, which is sensitively responsive to resting internal calcium, and levels of electrical activity.

Elevation of intracellular calcium by muscarinic receptor activation induces a block of voltage-activated rat ether-à-go-go channels in a stably transfected cell line.

We have studied the properties of r-eag voltage-activated potassium channels in a stably transfected human embryonic kidney cell line. It was found that r-eag channels are rapidly and reversibly inhibited by a rise in intracellular calcium from 30 to 300 nM. The inhibition does not appear to depend on the activity of calcium-dependent kinases and phosphatases. The effect of calcium on r-eag channel activity was studied in inside-out membrane patches. Calcium inhibited r-eag channel activity with a mean IC50 of 67 nM. Activation of muscarinic receptors, generating calcium oscillations in the transfected cells, induced a synchronous inhibition of r-eag mediated outward currents. This shows that calcium can mediate r-eag current inhibition following muscarinic receptor activation. The data indicate that r-eag channels are calcium-inhibitable voltage-activated potassium channels.

Identification of M-channels in outside-out patches excised from sympathetic ganglion cells.

We have identified the species of K+ channel that underlies the neuronal M-current in rat sympathetic ganglion cells. The channels were kinetically and pharmacologically defined using outside-out and cell-attached patches. They exhibited multiple conductance levels, predominantly 3-9 pS. Their slow gating in response to voltage change in outside-out patches was exhibited only in the presence of AIF-4 or GTP gamma S on the inner membrane surface and when the lower conductance states were dominant. In the absence of AIF-4 or GTP gamma S, the channels exhibited rapid activation and deactivation. We conclude that M-channel gating may be controlled by an associated GTP-binding protein.

Closure of potassium M-channels by muscarinic acetylcholine-receptor stimulants requires a diffusible messenger.

The M-current (IK(M)) is a slow voltage-gated K+ current which can be inhibited by muscarinic acetylcholine-receptor (mAChR) agonists. In the present experiments we have tested whether this inhibition results from a local (membrane-delimited) interaction between the receptor and adjacent channels, or whether channel closure is mediated by a diffusible messenger. To do this, single KM(+)-channel currents were recorded from membrane patches in dissociated rat superior cervical sympathetic neurons by using cell-attached patch electrodes. Channel activity was inhibited when muscarine was applied to the cell membrane outside the patch but persisted when channels were exposed to muscarine added to the pipette solution. We conclude that a diffusible molecule (or molecules) is (are) required to induce intrapatch channel closure following activation of extra-patch receptors.

Charybdotoxin blocks dendrotoxin-sensitive voltage-activated K+ channels.

Charybdotoxin, a short scorpion venom neurotoxin, which was thought to be specific for the blockade of Ca2+-activated K+ channels also blocks a class of voltage-sensitive K+ channels that are known to be the target of other peptide neurotoxins from snake and bee venoms such as dendrotoxin and MCD peptide. Charybdotoxin also inhibits 125I-dendrotoxin and 125I-MCD peptide binding to their receptors. All these effects are observed with an IC50 of about 30 nM.

Dendrotoxin-sensitive K+ channels in dorsal root ganglion cells.

In primary sensory cells, a K current active at resting potential is selectively blocked by the convulsant snake toxin, dendrotoxin. Using the patch-clamp technique, we have examined the characteristics of this K current at the unitary level. The voltage-activated K+ channels were found to have a maximum conductance of 5-10 pS in a 'physiological' K+ gradient. They show negligible sensitivity to calcium at the inner membrane aspect. Blockade by dendrotoxin seems likely to be due to direct action on the K+ channel.

Mast cell degranulating peptide and dendrotoxin selectively inhibit a fast-activating potassium current and bind to common neuronal proteins.

Dendrotoxin and mast cell degranulating peptide are highly potent convulsant polypeptides from mamba snake and bee venoms, respectively. Electrophysiological techniques and binding assays were used to study their interaction with fast-activating, voltage-dependent potassium channels in rat neurons. Intracellular recordings in sensory ganglion cells showed that mast cell degranulating peptide blocks the same slowly inactivating potassium current as dendrotoxin but with lower potency, the respective IC50 values in sensory A neurons of nodose ganglion being 2.1 nM and 37 nM. In contrast, the transient potassium current (IA) in superior cervical ganglion neurons was unaffected by either toxin, highlighting the heterogeneity of these potassium channels and the selective action of the toxins. Using biologically active 125I-labelled derivatives of dendrotoxin and beta-bungarotoxin (a related snake protein), the binding of mast cell degranulating peptide to two subtypes of high-affinity acceptors in rat cerebrocortical synaptosomal preparations was examined. Mast cell degranulating peptide antagonized the specific binding of both radioiodinated toxins to each of the acceptor species, in the membrane-bound state; additionally, [125I]dendrotoxin binding in detergent-solubilized extracts was, likewise, blocked by mast cell degranulating peptide. Notably, the observed inhibitory constants (KI) for mast cell degranulating peptide were appreciably larger than for dendrotoxin, consistent with their different efficacies in blocking the potassium conductances. It is concluded that the specific interaction of this apian polypeptide with dendrotoxin acceptors must underlie its selective action on potassium conductances, emphasizing a functional relationship between these membrane acceptors and the potassium channel variants, sensitive to both dendrotoxin and mast cell degranulating peptide.

The mechanism of action of capsaicin on sensory C-type neurons and their axons in vitro.

The selective excitant and neurotoxic action of capsaicin on vagal sensory neurons in the rat has been investigated in vitro using three techniques: extracellular recording of compound spike potentials from the whole nerve; intracellular recording from ganglion cells using single-electrode current and voltage clamp; and electron microscopy of the nerve and nodose ganglion. Capsaicin (0.1-10 microM) depolarized vagal sensory C fibres and cell bodies, and produced an increased conductance. The conductance increase appeared to be due to an increased permeability to sodium and calcium, plus a secondary increase in potassium (and perhaps chloride) conductance consequent upon calcium entry. The early entry of calcium seems to be a significant priming event in the neurotoxic process, since dramatic ultrastructural changes take place within a few minutes of capsaicin application, which are minimized by removing extracellular calcium ions. The observations indicate that in sensory C neurons capsaicin opens a conductance of limited specificity and that a resultant large calcium entry is closely involved in the rapid development of cell injury.

4-Aminopyridine and dendrotoxin induce repetitive firing in rat visceral sensory neurones by blocking a slowly inactivating outward current.

In a subpopulation of rat visceral afferent neurones we have identified a potassium (K) current which is novel to mammalian neurones. It activates rapidly at potentials positive to - 70 mV but shows only slow and incomplete inactivation and is inhibited by 1-30 microM 4-aminopyridine (4-AP) or 3-10 nM dendrotoxin (DTX). Inhibition of this slowly inactivating current suppresses spike adaptation and leads to pronounced repetitive firing. In contrast, other visceral afferent neurones possessing the normal transient A-current were insensitive to 4-AP at concentrations below 100 microM. We suggest that inhibition of the slowly inactivating current may contribute to the convulsant actions of 4-AP and DTX.

Properties of visceral primary afferent neurons in the nodose ganglion of the rabbit.

The active and passive membrane properties of rabbit nodose ganglion cells and their responsiveness to depolarizing agents have been examined in vitro. Neurons with an axonal conduction velocity of less than 3 m/s were classified as C-cells and the remainder as A-cells. Mean axonal conduction velocities of A- and C-cells were 16.4 m/s and 0.99 m/s, respectively. A-cells had action potentials of brief duration (1.16 ms), high rate of rise (385 V/s), an overshoot of 23 mV, and relatively high spike following frequency (SFF). C-cells typically had action potentials with a "humped" configuration (duration 2.51 ms), lower rate of rise (255 V/s), an overshoot of 28.6 mV, an after potential of longer duration than A-cells, and relatively low SFF. Eight of 15 A-cells whose axons conducted at less than 10 m/s had action potentials of longer duration with a humped configuration; these were termed Ah-cells. They formed about 10% of cells whose axons conducted above 2.5 m/s. The soma action potential of A-cells was blocked by tetrodotoxin (TTX), but that of 6/11 C-cells was unaffected by TTX. Typically, A-cells showed strong delayed (outward) rectification on passage of depolarizing current through the soma membrane and time-dependent (inward) rectification on inward current passage. Input resistance was thus highly sensitive to membrane potential close to rest. In C-cells, delayed rectification was not marked, and slight time-dependent rectification occurred in only 3 of 25 cells; I/V curves were normally linear over the range: resting potential to 40 mV more negative. Data on Ah-cells were incomplete, but in our sample of eight cells time-dependent rectification was absent or mild. C-cells had a higher input resistance and a higher neuronal capacitance than A-cells. In a proportion of A-cells, RN was low at resting potential (5 M omega) but increased as the membrane was hyperpolarized by a few millivolts. A-cells were depolarized by GABA but were normally unaffected by 5-HT or DMPP. C-cells were depolarized by GABA in a similar manner to A-cells but also responded strongly to 5-HT; 53/66 gave a depolarizing response, and 3/66, a hyperpolarizing response. Of C-cells, 75% gave a depolarizing response to DMPP.(ABSTRACT TRUNCATED AT 400 WORDS)

Generation of an unusual depolarizing response in rabbit primary afferent neurones in the absence of divalent cations.

The effects of divalent cations on responses to 5-hydroxytryptamine (5-HT), gamma-aminobutyric acid (GABA) and 1,1-dimethyl-4-phenyl piperazinium (DMPP) were investigated using a sucrose-gap method to record population responses. In Ca-free medium responses to 5-HT were enhanced, those to DMPP depressed and those to GABA unchanged. In Mg-free medium responses to 5-HT were unchanged, while those to DMPP and GABA were depressed. Removal of both Ca and Mg from the superfusion medium caused a small reduction of GABA responses and a large reduction of DMPP responses. Responses to 5-HT were not only greatly potentiated but were changed in character; the depolarizing phase became sigmoid and the dose dependence between quantity of 5-HT and response magnitude was lost as if 5-HT were triggering an all-or-nothing phenomenon. Dose--response relationships for GABA were normal in the large majority of preparations. In about 10% of preparations, supramaximal amounts of GABA or DMPP evoked large responses of a similar character to those evoked by 5-HT. The large responses, generated by an unknown mechanism, were termed X responses. Further reduction in tissue divalent cations by EGTA (1 mM) caused X responses to be generated spontaneously. Ca, Mg, Mn or Co (1 mM) could suppress X responses. DMPP responses, reduced in Ca/Mg-free medium, were largely restored by 1 mM-Ca. Depression of GABA responses in Ca/Mg-free medium could be entirely attributed to the absence of Mg, Mn being able to substitute for Mg. X responses were generated only after equilibration for 1 h with Ca/Mg-free medium. Attempts to manipulate [Ca]i with dinitrophenol or caffeine did not produce the conditions under which X responses were generated. Intracellular records of responses to 5-HT, GABA or DMPP showed that cells with A fibres responded to GABA but not to 5-HT or DMPP. Fifty-four out of sixty-seven cells with C fibre axons (80%) were depolarized by 5-HT, thirty-seven out of forty-nine (76%) by DMPP and forty out of fifty-seven (70%) by GABA. Eighteen out of thirty-eight (47%) C cells were depolarized by all three agents. Some C cells were very sensitive to 5-HT, 10(-6) M evoking a substantial response. In most, responses to 10(-5) M-5-HT had a slower rate of rise than responses to 10(-4) or 10(-3) M-GABA or DMPP, yet lower 5-HT concentrations normally elicited X responses in sucrose-gap experiments whereas GABA or DMPP normally did not.(ABSTRACT TRUNCATED AT 400 WORDS)

Depolarizing responses recorded from nodose ganglion cells of the rabbit evoked by 5-hydroxytryptamine and other substances.

Membrane potential changes induced by 5-hydroxytryptamine (5-HT), gamma-aminobutyric acid (GABA) and 1,1-dimethyl-4-phenyl piperazinium (DMPP) were recorded from nodose ganglia (NG) by the sucrose-gap method. An amount of 0.002-0.5 mumol of the depolarizing agent was injected into the superfusion stream to the ganglion. Responses to 5-HT were also evoked from superior cervical (SCG) and dorsal root ganglia (DRG). 5-Hydroxytryptamine elicited depolarizations of graded amplitude. Maximal responses were 4.5 +/- 0.4 mV in nodose ganglia compared to 2.2 +/- 0.2 mV in superior cervical and 0.6 +/- 0.1 mV in dorsal root ganglia (means +/- SEM). In nodose ganglia, GABA induced smaller maximal depolarizations than did 5-HT, similar to those evoked by DMPP; dopamine was a weak depolarizing agent while substance P was apparently inactive. The dose-response curve for 5-HT in nodose ganglia was parallel to that for 5-HT in superior cervical ganglia and significantly to the left (ED50 values 0.029 and 0.098 mumol). Curves for 5-HT and GABA in nodose ganglia were superimposable. The high sensitivity of nodose ganglia cells to 5-HT is briefly discussed. Analogues of 5-HT lacking a hydroxyl group at position 5 on the nucleus were relatively inactive as depolarizing agents. Picrotoxin (10(-6)-10(-5) M) reduced or suppressed responses in nodose ganglia to GABA, whereas responses to 5-HT and DMPP were not much affected or, in the case of 5-HT, sometimes somewhat reduced. Quipazine (10(-6) M) was a selective antagonist of 5-HT responses in nodose ganglia; those to GABA and DMPP were not significantly altered. Neither trazodone nor LSD displayed antagonist properties at 5-HT receptors in nodose ganglia.