Voltage-dependent and calcium-dependent inactivation of calcium channel current in identified snail neurones

1. The dependence of Ca2+ current inactivation on membrane potential and intracellular Ca2+ concentration ([Ca2+]i) was studied in TEA-loaded, identified Helix neurones which possess a single population of high-voltage-activated Ca2+ channels. During prolonged depolarization, the Ca2+ current declined from its peak with two clearly distinct phases. The time course of its decay was readily fitted by a double-exponential function. 2. In double-pulse experiments, the relationship between the magnitude of the Ca2+ current and the amount of Ca2+ inactivation was not linear, and considerable inactivation was present, even when conditioning pulses were to levels of depolarization so great that Ca2+ currents were near zero. Similar results were obtained when external Ca2+ was replaced by Ba2+. 3. In double-pulse experiments, hyperpolarization during the interpulse interval served to reprime a portion of the inactivated Ca2+ current for subsequent activation. The extent of repriming increased with hyperpolarization, reaching a maximum between -130 and -150 mV. The effectiveness of repriming hyperpolarizations was considerably increased when Ca2+ was replaced by Ba2+. 4. A significant fraction of inactivated Ca2+ channels can be recovered during hyperpolarizing pulses lasting only milliseconds. If hyperpolarizing pulses were applied before substantial inactivation of Ca2+ current, Ca2+ channels remained available for activation despite considerable Ca2+ entry. 5. The relationship between [Ca2+]i and inactivation was investigated by quantitatively injecting Ca2+-buffered solutions into the cells. The time course of Ca2+ current inactivation was unchanged at free [Ca2+] between 1 x 10(-7) and 1 x 10(-5) M. From 1 x 10(-7) to 1 x 10(-9) M, inactivation became progressively slower, mainly due to a decrease of the amplitude ratio (fast/slow) of the two components of inactivation, which fell from about unity to near zero at 1 x 10(-9) M. In double-pulse experiments, recovery from inactivation was enhanced in neurones that had been injected with Ca2+ chelator. 6. We conclude that inactivation of Ca2+ channels in these neurones depends on both [Ca2+]i and membrane potential. The voltage-dependent process may serve as a mechanism to quickly recover inactivated Ca2+ channels during repetitive firing despite considerable Ca2+ influx. 7. The results are discussed in the framework of a model which is based on two states of inactivation, INV and INCA, which represent different conformations of the inactivating substrate, and which are both reached from a lumped state of activation (A). Inactivation leads to high occupancy of INV during depolarization.(ABSTRACT TRUNCATED AT 400 WORDS)

Quisqualate receptor-mediated rhythmic bursting of rat hypothalamic neurons in dissociated cell culture

Dissociated hypothalamic neurons from embryonic rat brain exhibit a level of spontaneous synaptic activity after 21 days in culture. When GABA-mediated responses are blocked by picrotoxin or bicuculline (20 microM), the neurons burst rhythmically. Rhythmic burst activity is generated in most cells by postsynaptic excitatory currents (EPSCs) through non-specific cationic channels rather than by intrinsic pacemaker currents. We present evidence that EPSCs are mediated by an excitatory amino acid and a quisqualate receptor type.

A diacylglycerol analogue reduces neuronal calcium currents independently of protein kinase C activation

Diacylglycerol analogues (for example 1,2-oleoylacetylglycerol, OAG) and phorbol esters are activators of protein kinase C, and have been widely used to study the function of this enzyme in both intact cells and cell-free preparations. Electrophysiological studies have shown that these activators can either depress or increase Ca2+ currents, or decrease K+ currents when applied outside the cell. It has been assumed that these effects are mediated by protein kinase C activation. Here we report that micromolar levels of OAG and phorbol esters depress Ca2+ currents in chick sensory neurons independently of their effect as activators of protein kinase C. The depression of the Ca2+ current is rapid and is unaffected by intracellular application of the protein kinase C inhibitors staurosporin, sphingosine and H-7. Furthermore, the activators were ineffective when applied intracellularly, indicating that their site of action is on the outside of the membrane.

Calcium channel block by cadmium in chicken sensory neurons

Cadmium block of calcium channels was studied in chicken dorsal root ganglion cells by a whole-cell patch clamp that provides high time resolution. Barium ion was the current carrier, and the channel type studied had a high threshold of activation and fast deactivation (type FD). Block of these channels by 20 microM external Cd2+ is voltage dependent. Cd2+ ions can be cleared from blocked channels by stepping the membrane voltage (Vm) to a negative value. Clearing the channels is progressively faster and more complete as Vm is made more negative. Once cleared of Cd2+, the channels conduct transiently on reopening but reequilibrate with Cd2+ and become blocked within a few milliseconds. Cd2+ equilibrates much more slowly with closed channels, but at a holding potential of -80 mV virtually all channels are blocked at equilibrium. Cd2+ does not slow closing of the channels, as would be expected if it were necessary for Cd2+ to leave the channels before closing occurred. Instead, the data show unambiguously that the channel gate can close when the channel is Cd2+ occupied.

Fast-deactivating calcium channels in chick sensory neurons

Whole-cell Ca and Ba currents were studied in chick dorsal root ganglion (DRG) cells kept 6-10 in culture. Voltage steps with a 15-microseconds rise time were imposed on the membrane using an improved patch-clamp circuit. Changes in membrane current could be measured 30 microseconds after the initiation of the test pulse. Currents through Ca channels were recorded under conditions that eliminate Na and K currents. Tail currents, associated with Ca channel closing, decayed in two distinct phases that were very well fitted by the sum of two exponentials. The time constants tau f and tau s were near 160 microseconds and 1.5 ms at -80 mV, 20 degrees C. The tail current components, called FD and SD (fast-deactivating and slowly deactivating), are Ca channel currents. They were greatly reduced when Mg2+ replaced all other divalent cations in the bath. The SD component inactivated almost completely as the test pulse duration was increased to 100 ms. It was suppressed when the cell was held at membrane potentials positive to -50 mV and was blocked by 100-200 microM Ni2+. This behavior indicates that the SD component was due to the closing of the low-voltage-activated (LVA) Ca channels previously described in this preparation. The FD component was fully activated with 10-ms test pulses to +20 mV at 20 degrees C, and inactivated to approximately 30% during 500-ms test pulses. It was reduced in amplitude by holding at -40 mV, but was only slightly reduced by micromolar concentrations of Ni2+. Replacement of Ca2+ with Ba2+ increased the FD tail current amplitudes by a factor of approximately 1.5. The deactivation kinetics did not change (a) as channels inactivated during progressively longer pulses or (b) when the degree of activation was varied. Further, tau f was affected neither by changing the holding potential nor by varying the test pulse amplitude. Lowering the temperature from 20 to 10 degrees C decreased tau f by a factor of 2.5. In all cases, the FD component was very well fitted by a single exponential. There was no indication of an additional tail component of significant size. Our findings indicate that the FD component is due to closing of a single class of Ca channels that coexist with the LVA Ca channel type in chick DRG neurons.

Single Ca-activated cation channels in bursting neurons of Helix

The depolarizing drive that maintains bursting in Helix neurons is carried by a long-lasting calcium-activated inward current. This current was studied using cell-attached and inside-out patches from the right parietal fast burster neuron of Helix pomatia. One population of unitary currents was inward at -50 mV and showed an increased probability of opening when Ca2+ was injected or when excised patches were bathed in solutions with 10(-7) to 10(-5) M free Ca2+ levels. Cell-attached patches (patch electrodes filled with 10(-7) M Ca2+ Ringer) had single channel conductances near 30 pS with reversal potentials near -20 mV; excised patches had similar conductances in symmetrical Na+ solutions and reversal potentials within a few millivolts of zero. Calculations, assuming a simple spherical cell, yield a channel density of only about 1/6 micron2. The increased channel opening probability characteristically persisted well beyond the duration of transient whole-cell inward current. We conclude from this that the later phase of Ca-activated inward currents is normally masked by outward currents.

Direct ion channel gating: a new function for intracellular messengers

1. There is widespread belief that intracellular messengers [e.g., Ca2+, cyclic AMP, cyclic GMP, inositol-1,4,5-triphosphate (IP3)] assert their actions primarily through activation of protein kinases. 2. In studies of excitable cells protein kinase activation has been shown to alter membrane ionic conductance, presumably through phosphorylation of ion channels (see Levitan, 1985). However, recent reports from several laboratories indicate that intracellular messengers can also affect membrane ionic conductances directly without invoking protein kinase activation. 3. In this article we examine those examples of direct activation of ionic conductances by intracellular messengers which are supported by single-channel studies of isolated membrane patches. The list of cell types displaying this kind of response is growing and includes cells of neuronal as well as nonneuronal origin.

Effect of menthol on two types of Ca currents in cultured sensory neurons of vertebrates

The effect of menthol on voltage-dependent Ca currents was investigated in cultured dorsal root ganglion cells from chick and rat embryos. Bath application of menthol (0.1-1 mM) had different effects on the various Ca currents present in these neurons. Below -20 mV, the low threshold Ca currents were reduced in amplitude in a dose-dependent manner by menthol with little changes of their activation kinetics. In contrast to this, the time course of inactivation of the high-threshold Ca currents, activated above -20 mV from a holding potential of -80 mV, was drastically accelerated by external menthol. The action of menthol was unchanged with more positive holding potentials (-50 mV). Thus, a proposed third type of Ca current with transient activation and complete deactivation below -50 mV was either not present or not affected by menthol. Menthol exerted its action only when applied from the outside. Its effect was completely reversible within 15-20 min of wash-out. Our findings are consistent with the idea that menthol acts on two types of Ca channels coexisting on the membrane of cultured sensory neurons. Menthol blocks currents through the low voltage-activated Ca channel, and facilitates inactivation gating of the classical high voltage-activated Ca channel.

Cationic membrane conductances induced by intracellularly elevated cAMP and Ca2+: measurements with ion-selective microelectrodes

Adenosine 3',5'-cyclic monophosphate (cAMP) and CaCl2 were injected by a fast and quantitative pressure injection technique into voltage-clamped, identified Helix neurons. Intracellular elevation of cAMP as well as of Ca2+ activated an inward current (IcAMP and IN). To identify the ionic fluxes during IcAMP and IN changes in [Na+]i, [K+]o, [H+]i, and [Cl-]i were measured with ion-selective microelectrodes (ISMs). Near resting potential, Na+ was the main carrier of IcAMP. K+, and less effectively Ca2+, could substitute for Na+ in carrying IcAMP. H+ and Cl- were excluded as current carriers for IcAMP by means of ISMs. Simultaneous to this action, cAMP decreased a K+ conductance. This decrease was associated with a reduction of the K+ efflux activated by long-lasting depolarizing voltage steps, as directly measured with ISMs located near the external membrane surface. The nearly compensatory increase and decrease of two membrane conductances in the same neuron left the cell input resistance unchanged despite the considerable depolarizing action of intracellularly elevated cAMP. IN was also of nonspecific nature. However, our findings indicate less selectivity for the Ca2+-activated nonspecific channels. Large cations such as choline, TEA, and Tris passed nearly as well as Na+ through the channels. Measurements with ISMs showed that [H+]i and [Cl-]i were unchanged during IN. IN was largest in bursting pacemaker neurons compared with other cells of similar size. It was found to be essential for the burst production in these cells. IcAMP, on the other hand, might be involved in the presynaptic facilitatory action of cAMP, which as yet was attributed solely to a reduction of a K+ conductance.

Calcium channel current inactivation is selectively modulated by menthol

The effect of menthol on Ca channel current inactivation was studied in identified Helix neurons. External application of menthol accelerated the Ca-dependent rapid phase of inactivation. Menthol restored a fast inactivation phase after the Ca-dependent inactivation had been removed by strongly buffering changes in intracellular free Ca or by using Ba ions as current carriers. The menthol-induced inactivation was unchanged by variations in intracellular free Ca. A sensitizing effect of menthol on Ca-dependent inactivation appeared unlikely. Instead the results indicate a modulating action of menthol on Ca inactivation.

Activation of a nonspecific cation conductance by intracellular Ca2+ elevation in bursting pacemaker neurons of Helix pomatia

The pacemaker current of a bursting neuron of Helix pomatia was investigated using voltage-clamp and pressure-injection techniques. In the steady state the net membrane current was zero near threshold of the action potential at -45 mV. Negative to this potential the membrane current was inward and steady. During burst activity a long-lasting inward current instantaneously appeared with voltage steps to membrane potentials below -20 mV. This inward current was already present when the clamp step fell into the rising phase of the first spike and became larger during the depolarizing phase of the spike. The repolarization phase and the interspike interval did not add much current. As the spike duration became longer in the course of the burst discharge the inward current grew in amplitude, but its increase was not proportional to that of the spike duration. This was observed with clamp steps to the potassium equilibrium potential (EK = -70 mV). The inward current decayed during a hyperpolarizing step with a half time of approximately 400 ms, which was invariant to voltage as measured between -40 and -100 mV. It decreased linearly from -100 to -40 mV with an extrapolated zero potential of about -20 mV. The inward current was not generated by spikes if the Ca2+ conductance was blocked by Ni2+. At membrane potentials positive to EK the development of an outward current, probably carried by K+, could be observed during the burst. It overlasted the inward current and decayed with time constants of 6-7 s. This current grew successively in amplitude in the course of the burst discharge and finally nullified the inward-current component at potentials around spike threshold, thus terminating the burst. An inward current with properties similar to the spike-induced inward current was produced by pressure injecting CaCl2 into the neurons. This current was unselectively carried by cations as shown by both ion-substitution experiments and measurements with ion-selective microelectrodes. Large cations such as choline, TEA, and Tris passed through the channels nearly as well as Na+. Changes in the H+ or Cl- concentration were not seen to affect the inward current. Spike as well as the injection-induced currents were largest in bursting pacemaker cells compared with other cells of similar size. Both currents were found to be small or absent in nonbursting but regularly firing pacemaker cells, albeit these cells reveal a larger Ca2+ current density than the bursting pacemaker cell.(ABSTRACT TRUNCATED AT 400 WORDS)

Changes in ionic conductances induced by cAMP in Helix neurons

Adenosine 3',5'-cyclic monophosphate (cAMP) was injected by a fast and quantitative pressure injection method into voltage-clamped identified Helix neurons. The intracellular elevation of cAMP caused an inward current which was not accompanied by a significant change in membrane conductance in a negative potential range with little activation of voltage-dependent membrane conductances. Near resting potential Na+ ions were the main carrier of the cAMP-induced inward current as measured with ion-selective microelectrodes. TTX did not affect the Na+ influx. K+ and less effective Ca2+ could substitute for Na+ in carrying the inward current. In the presence of Na+, divalent cations such as Ca2+ and Mg2+, and also La3+ exerted an inhibitory influence on the cAMP-induced inward current, and Ca2+ as measured with ion-selective microelectrodes did not contribute significantly to the current. Thus, the inward current was of a non-specific nature. Simultaneously to this cAMP action, the membrane permeability for K+ ions was decreased by cAMP. This effect became particularly obvious when K+ currents were activated by long-lasting, depolarizing voltage steps. In this situation a reduced K+ efflux following cAMP injection was observed by means of K+-selective microelectrodes located near the external membrane surface. Outward K+ currents were less reduced by cAMP if external Ca2+ was replaced by Ni2+. The nearly compensatory increase and decrease of two membrane conductances in the same neuron explained the lack of change in the cell input resistance despite the considerable depolarizing action of intracellularly elevated cAMP.

Stimulation of a sodium influx by cAMP in Helix neurons

Brief pressure injections of aqueous solutions of cAMP in identified neurons of Helix pomatia caused depolarizations which lasted for tens of seconds. In voltage-clamped neurons an inward current of similar duration was induced which saturated at 10 microA/cm2 cell surface. In the range of negative membrane potentials with little voltage-dependent activation, this current was not accompanied by a change in membrane conductance. The inward current was not produced by injection of ATP, ADP, adenosine, inosine or cGMP. cAMP derivatives produced longer-lasting effects. Prolongation of the inward current was also observed after inhibition of the phosphodiesterase by IBMX. Drugs which block active transport had no effect on the response to cAMP injection. The inward current depended on extracellular sodium, and was maximal when all other mono- and divalent cations were replaced by Na+. The cAMP-induced current was accompanied by a transient increase in [Na+]i, but there was no change in [Cl-]i. Li+ could largely substitute for Na+; Ca2+ was less effective. Addition of Mg2+ or Ca2+ to solutions containing a high Na+-concentration inhibited the response. Internal acidification with HCl reversibly enhanced the inward current. These data indicate that the depolarizing effect of cAMP can be accounted for by an inward movement of Na-ions, and that the effect is augmented by H+-ions.