Effect of calcium upon sodium inactivation in the giant axon ofLoligo pealei

Summary Giant axons ofLoligo pealei were voltage clamped in artificial seawater solutions containing varying concentrations of calcium from 10 to 100mm, and the sodium conductance inactivation was measured with a series of two-pulse experiments. Theh vs. voltage curve showed a shift of about 10 mV in the depolarizing direction on the voltage axis for a tenfold increase in external calcium without substantial alteration in the slope of the voltage dependence. The kinetics of the inactivation process were found to be exponential for hyperpolarizing prepulses, but showed some indication of a sigmoidal decay for depolarizing prepulses in all calcium concentrations employed. Increasing calcium increased the delay in the sigmoidal response. The inactivation time constant _h increased as a function of calcium concentration over the potential range studied, –10 to –90 mV. The values of the rate constants _h and _h are decreased with an increase in calcium and these effects are not consistent with parallel shifts of the rate constant vs. voltage curves along the voltage axis for changes in calcium concentration.Magnesium does not behave as an equimolar substitute for calcium. The effect of a solution containing 10mm calcium and 50mm magnesium is intermediate to that of solutions containing 10 and 30mm calcium alone.Predictions of a recent model for the sodium conductance (Moore, J.W., Cox, E.B., 1976Biophys. J. 16:171) which employs calcium binding were compared with the experimental data.     

Voltage-gated ion channels of inflowing current expressed in Xenopus oocytes after injection of rat brain mRNA

The expression of two types of voltage-gated ion channels of the inflowing current ("fast" sodium channels, sensitive to tetrodotoxin, and high-threshold calcium channels) was detected by electrophysiological methods in the membrane ofXenopus oocytes, after injection of poly(A)⁺-mRNA from the brains of 18- to 20-day-old rats. When Cd²⁺ (200 µmoles/liter) was added to the extracellular solution, the barium current through the expressed calcium channels was completely suppressed, but no sensitivity to D-600 (20 µmoles/liter) and nitrendipine (50 µmoles/liter) was exhibited. A peptide blocker of the high-threshold calcium channels of the neuron membrane, -conotoxin GVIA, in a concentration of 1 µmole/liter led to 20–40 min suppression of the barium current expressed in the oocyte. Steady-state inactivation of this current could be described by the Boltzman formula, using the values of the half-inactivation potential V_1/2=–50 mV and the steepness factor k=14 mV. It is concluded that in potential-dependent and pharmacological properties, the calcium channels expressed in the oocyte, despite the absence of any appreciable time-dependent inactivation, most resemble the high-threshold inactivatable (HTI- or N-type) calcium channels of the neuron membrane.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 23, No. 3, pp. 344–353, May–June, 1991.     

Properties of Proton-Gated Ion Channels in Sensory Neurons of Rats

In experiments on the somata of sensory neurons isolated from the spinal and trigeminal ganglia of rats, we characterized three subclasses of proton-gated currents differing from each other in their kinetics of desensitization and characteristics of stationary desensitization (but not in the characteristics of stationary activation). A voltage clamp technique in the whole cell configuration and intracellular perfusion were used. Expression of the channels providing currents of each subclass depended on the soma diameter but not on anatomical localization of the neuron. Proton-gated channels of type I were characterized by mono- or biexponential kinetics of current desensitization with the duration of complete decay within a 1 to 15 sec range; the mean pH₅₀ of the curve of stationary desensitization was 7.21 ± 0.02. Channels of type II possessed mostly monoexponential desensitization kinetics with the duration of decay within a 1 to 3 sec range; their pH₅₀ of the stationary desensitization curve was 7.11 ± 0.02. Channels of type III showed mostly biexponential desensitization kinetics; the complete current decay lasted about 5 sec, while the mean pH₅₀ was about 6.78 ± 0.02. Channels of type I were typical of small neurons (soma diameter 10-20 m), while those of types II and III were found mostly in large cells (35-60 m).     

Ionic current through batrachotoxin-modified sodium channels of the ranvier node membrane at high positive and negative potentials

Ionic current through batrachotoxin (BTX)-modified sodium channels within a wide range of membrane potentials were measured by the voltage clamp method on the membrane of a myelinated frog nerve fiber. At high positive voltages (above +80 mV) the current decreased with time; with an increase in voltage the steady-state level of the currents fell. The results of measurement of "instant" currents showed that this phenomenon is connected with a decrease in overall conductivity of the modified channels. Scorpion toxin had no significant effect on the kinetics of decline of the currents. This indicates that they are due to processes which differ from ordinary inactivation. In the presence of procaine, at high positive voltages slow (tens of milliseconds) potential-dependent blocking of BTX-modified channels was observed. An increase in negative potentials above ?100 mV caused a decrease in "instant" currents, connected with rapid potential-dependent blocking of BTX-modified sodium channels by calcium ions.     

Sodium currents in the giant axon of the crabCarcinus maenas

Summary Measurements were made of the kinetics and steady-state properties of the sodium conductance changes in the giant axon of the crabCarcinus maenas. The conductance measurements were made in the presence of small concentrations of tetrodotoxin and as much electrical compensation as possible in order to minimize errors caused by the series resistance. After an initial delay of 10–150 sec, the conductance increase during depolarizing voltage clamp pulses followed the Hodgkin-Huxley kinetics. Values of the time constant for the activation of the sodium conductance lay on a bell-shaped curve with a maximum under 180 sec at –40 mV (at 18°C). Values of the time constant for the inactivation of the sodium conductance were also fitted using a bell-shaped curve with a maximum under 7 msec at –70 mV. The effects of membrane potential on the fraction of Na channels available for activation studied using double pulse protocols suggest that hyperpolarizing potentials more negative than –100 mV lock a fraction of the Na channels in a closed conformation.     

Photodynamic Alteration of Sodium Currents in Lobster Axons

Photodynamic alteration of lobster giant axons drastically changed the magnitude and kinetics of sodium currents seen under voltage clamp using the sucrose gap technique. Illumination of axons following treatment with acridine orange or eosin Y decreased the maximum sodium conductance to a zero asymptote as an exponential function of illumination time. Normal sodium inactivation was slowed, with τ_h more than doubled depending on experimental conditions. A second slower inactivation rate developed occasionally. τ_h was altered little, if at all. Sodium current "tails" were not prolonged. At maximum light intensity and with eosin Y as sensitizer leakage current increased after 4–10 sec in light. These changes were irreversible. Decreases in maximum sodium conductance correlated highly with increases in time to peak sodium current. The magnitude of change varied linearly with light intensity. The action spectra for eosin Y and acridine orange peaked near 545 and 505 nm, respectively. The magnitude of change varied with preillumination dye exposure time in a quasi-exponential approach to a maximum effect. Sodium dithionite protected the axon from photodynamic change.     

Effect of Nifedipine on Low-Threshold Voltage-Activated Ca2+ Channels in Thalamic Neurons of the Rat

In neurons of the rat thalamic nucl. lateralis dorsalis, we analyzed the effect of a well-known antihypertensive agent, nifedipine, on low-threshold Ca²⁺ channels that, according to their kinetics of activation, were classified as fast and slow subtypes. The transmembrane currents through the respective channels in freshly isolated neurons obtained from 14- to 17-day-old rats were measured using a patch-clamp technique in the whole-cell configuration. The fast component of the Ca²⁺ current demonstrated a higher sensitivity to nifedipine (A_max = 81%, IC₅₀ = 22 M) than the slow component did (A_max = 51%, IC₅₀ = 28 M). Nifedipine changed the activation and inactivation characteristics of the fast and slow current components, although in a different manner. Therefore, the affinity of nifedipine for the respective channels, which determine the above components, is different and depends on the functional state of such channels. The data obtained allow us to estimate in detail the pharmacological characteristics of the channels under study and to hypothesize on the mechanisms underlying interaction between nifedipine and channels of the above subtypes.     

The characteristics of the sodium currents across EGTA-modified calcium channels in the membrane of cultured rat cardiomyocytes]

In isolated, cultured neonatal rat ventricular myocytes sodium currents through calcium channels induced by lowering of extracellular calcium concentration 100 nmol/l have been investigated by whole-cell patch clamp technique. Such Na(+)-carried currents are modulated by classic Ca2+ agonists and antagonists. The potential-dependent characteristics of Na+ current are shifted at 20 mV in hyperpolarizing direction as compared to initial Ca(2+)-carried current. The inactivation decay of Na+ current through Ca2+ channels has the monoexponential behaviour. The possible action of extracellular Ca2+ lowering on Ca2+ channel selective filter and gating mechanisms is suggested.     

Tolbutamide enhances potential-dependent inactivation of calcium channels in snail neurons

A two-microelectrode voltage-clamp method was used to measure a high-threshold calcium current (I_Ca) on isolated snail neurons. Tolbutamide (1–5 mmole/liter) and H-8 (1–30 µmole/liter), inhibitors of kinase A, caused a decrease in the peak amplitude and accelerated I_Ca decay during a depolarizing stimulus. The half-life of the "slow" time constant of I_Ca decay decreased in the presence of tolbutamide, and was two to three times stronger than the half-life of the "fast" time constant. I_Ca inactivation curves plotted in a double-stimulus experiment have shown that after tolbutamide application, I_Ca inactivation elicited by the application of high-amplitude depolarizing pre-stimuli preferentially rises (V_c=+30 to +70 mV). The results suggest that dephosphorylation of Ca²⁺ channels enhances a potential-dependent component of the inactivation process.Scientific-Research Institute of the Brain, Academy of Medical Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 23, No. 5, pp. 515–519, September–October, 1991.     

Chlorine decay and bacterial inactivation kinetics in drinking water in the tropics

The decay of free chlorine (Cl₂) and combined chlorine (mostly monochloramine: NH₂Cl) and the inactivation of bacteria was examined in Dar es Salaam, Tanzania. Batch experiments, pilot-scale pipe experiments and full-scale pipe experiments were carried out to establish the kinetics for both decay and inactivation, and to compare the two disinfectants for use under tropical conditions. The decay of both disinfectants closely followed first order kinetics, with respect to the concentration of both disinfectant and disinfectant-consuming substances. Bacterial densities exhibited a kinetic pattern consisting of first order inactivation with respect to the density of the bacteria and the concentration of the disinfectant, and first order growth with respect to the bacterial density. The disinfection kinetic model takes the decaying concentration of the disinfectant into account. The decay rate constant for free chlorine was 114 lg^-1h^-1, while the decay rate constant for combined chlorine was 1.84 lg^-1h^-1 (1.6% of the decay rate for free chlorine). The average concentration of disinfectant consuming substances in the water phase was 2.6 mg Cl₂/l for free chlorine and 5.6 mg NH₂Cl/l for combined chlorine. The decay rate constant and the concentration of disinfectant consuming substances when water was pumped through pipes, depended on whether or not chlorination was continuous. Combined chlorine especially could clean the pipes of disinfectant consuming substances. The inactivation rate constant , was estimated at 3.06×10⁴ lg^-1h^-1. Based on the inactivation rate constant, and a growth rate constant determined in a previous study, the critical concentration of free chlorine was found to be 0.08 mg Cl₂/l. The critical concentration is a value below which growth rates dominate over inactivation.The authors are with the Technical University of Denmark, IMT, CDC, Build. 208, DK-2800 Lyngby, Denmark     

Implication of the C-terminal region of the alpha-subunit of voltage-gated sodium channels in fast inactivation

The α-subunit of both the human heart (hH1) and human skeletal muscle (hSkM1) sodium channels were expressed in a mammalian expression system. The channels displayed slow (hH1) and fast (hSkM1) current decay kinetics similar to those seen in native tissues. Hence, the aim of this study was to identify the region on the α-subunit involved in the differences of these current-decay kinetics. A series of hH1/hSkM1 chimeric sodium channels were constructed with the focus on the C-terminal region. Sodium currents of chimeric channels were recorded using the patch-clamp technique in whole-cell configuration. Chimeras where the C-terminal region had been exchanged between hH1 and hSkM1 revealed that this region contains the elements that cause differences in current decay kinetics between these sodium channel isoforms. Other biophysical characteristics (steady-state activation and inactivation and recovery from inactivation) were similar to the phenotype of the parent channel. This indicates that the C-terminus is exclusively implicated in the differences of current decay kinetics. Several other chimeras were constructed to identify a specific region of the C-terminus causing this difference. Our results showed that the first 100-amino-acid stretch of the C-terminal region contains constituents that could cause the differences in current decay between the heart and skeletal muscle sodium channels. This study has uncovered a direct relationship between the C-terminal region and the current-decay of sodium channels. These findings support the premise that a novel regulatory component exists for fast inactivation of voltage-gated sodium channels. Received: 1 March 2001/Revised: 18 May 2001     

Steady-state and dynamic properties of cardiac sodium-calcium exchange. Sodium-dependent inactivation

Sodium-calcium exchange current was isolated in inside-out patches excised from guinea pig ventricular cells using the giant patch method. The outward exchange current decayed exponentially upon activation by cytoplasmic sodium (sodium-dependent inactivation). The kinetics and mechanism of the inactivation were studied. (a) The rate of inactivation and the peak current amplitude were both strongly temperature dependent (Q10 = 2.2). (b) An increase in cytoplasmic pH from 6.8 to 7.8 attenuated the current decay and shifted the apparent dissociation constant (Kd) of cytoplasmic calcium for secondary activation of the exchange current from 9.6 microM to < 0.3 microM. (c) The amplitude of exchange current decreased synchronously over the membrane potential range from -120 to 60 mV during the inactivation, indicating that voltage dependence of the exchanger did not change during the inactivation process. The voltage dependence of exchange current also did not change during secondary modulation by cytoplasmic calcium and activation by chymotrypsin. (d) In the presence of 150 mM extracellular sodium and 2 mM extracellular calcium, outward exchange current decayed similarly upon application of cytoplasmic sodium. Upon removal of cytoplasmic sodium in the presence of 2-5 microM cytoplasmic free calcium, the inward exchange current developed in two phases, a fast phase within the time course of solution changes, and a slow phase (tau approximately 4 s) indicative of recovery from sodium-dependent inactivation. (e) Under zero-trans conditions, the inward current was fully activated within solution switch times upon application of cytoplasmic calcium and did not decay. (f) The slow recovery phase of inward current upon removal of cytoplasmic sodium was also present under the zero-trans condition. (g) Sodium-dependent inactivation shows little or no dependence on membrane potential in guinea pig myocyte sarcolemma. (h) Sodium-dependent inactivation of outward current is attenuated in rate and extent as extracellular calcium is decreased. (i) Kinetics of the sodium-dependent inactivation and its dependence on major experimental variables are well described by a simple two-state inactivation model assuming one fully active and one fully inactive exchanger state, whereby the transition to the inactive state takes place from a fully sodium-loaded exchanger conformation with cytoplasmic orientation of binding sites (E1.3Ni).     

Sea Anemone Toxin (ATX II) Modulation of Heart and Skeletal Muscle Sodium Channel α-Subunits Expressed in tsA201 Cells

We have expressed recombinant α-subunits of hH1 (human heart subtype 1), rSkM1 (rat skeletal muscle subtype 1) and hSkM1 (human skeletal muscle) sodium channels in human embryonic kidney cell line, namely the tsA201 cells and compared the effects of ATX II on these sodium channel subtypes. ATX II slows the inactivation phase of hH1 with little or no effect on activation. At intermediate concentrations of ATX II the time course of inactivation is biexponential due to the mixture of free (fast component, τ^fast _h ) and toxin-bound (slow component, τ^slow _h ) channels. The relative amplitude of τ^slow _h allows an estimate of the IC₅₀ values ∼11 nm. The slowing of inactivation in the presence of ATX II is consistent with destabilization of the inactivated state by toxin binding. Further evidence for this conclusion is: (i) The voltage-dependence of the current decay time constants (τ _h ) is lost or possibly reversed (time constants plateau or increase at more positive voltages in contrast to these of untreated channels). (ii) The single channel mean open times are increased by a factor of two in the presence of ATX II. (iii) The recovery from inactivation is faster in the presence of ATX II. Similar effects of ATX II on rSkM1 channel behavior occur, but only at higher concentrations of toxin (IC₅₀= 51 nm). The slowing of inactivation on hSkM1 is comparable to the one seen with rSkM1. A residual or window current appears in the presence of ATX II that is similar to that observed in channels containing mutations associated with some of the familial periodic paralyses. Received: 5 December 1995/Revised: 1 March 1996     

Inactivation of calcium currents in the soma of spinal ganglia by removing the membrane potential depolarization shift

Kinetic and voltage-dependent characteristics of the inactivating action of incoming calcium currents were investigated in the somatic membrane of rat spinal ganglia neurons using an intracellular dialysis technique. It was shown that the "tail" of low-threshold calcium current could be reliably described by one exponent with a time constant of =1.2–1.8 msec at a repolarization potential of –90 mV. The "tail" of the high-threshold calcium current represented the sum of several exponents. The time constant of the main component which expressed inactivation of the high threshold calcium current was ^h=250–350 µsec. It was also shown that and ^h remained virtually unchanged for repolarization potentials in the subthreshold region; they increase, however, if the repolarizing potential is close to those potentials at which the corresponding component of calcium current is initially activated. A dependence was observed between the levels and ^h and duration of the depolarizing shift. Findings are discussed in the context of a three-tier model of calcium channels.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 17, No. 5, pp. 682–691, September–October, 1985.     

Differential Effects of TipE and a TipE-Homologous Protein on Modulation of Gating Properties of Sodium Channels from Drosophila melanogaster

β subunits of mammalian sodium channels play important roles in modulating the expression and gating of mammalian sodium channels. However, there are no orthologs of β subunits in insects. Instead, an unrelated protein, TipE in Drosophila melanogaster and its orthologs in other insects, is thought to be a sodium channel auxiliary subunit. In addition, there are four TipE-homologous genes (TEH1-4) in D. melanogaster and three to four orthologs in other insect species. TipE and TEH1-3 have been shown to enhance the peak current of various insect sodium channels expressed in Xenopus oocytes. However, limited information is available on how these proteins modulate the gating of sodium channels, particularly sodium channel variants generated by alternative splicing and RNA editing. In this study, we compared the effects of TEH1 and TipE on the function of three Drosophila sodium channel splice variants, DmNa_v9-1, DmNa_v22, and DmNa_v26, in Xenopus oocytes. Both TipE and TEH1 enhanced the amplitude of sodium current and accelerated current decay of all three sodium channels tested. Strikingly, TEH1 caused hyperpolarizing shifts in the voltage-dependence of activation, fast inactivation and slow inactivation of all three variants. In contrast, TipE did not alter these gating properties except for a hyperpolarizing shift in the voltage-dependence of fast inactivation of DmNa_v26. Further analysis of the gating kinetics of DmNa_v9-1 revealed that TEH1 accelerated the entry of sodium channels into the fast inactivated state and slowed the recovery from both fast- and slow-inactivated states, thereby, enhancing both fast and slow inactivation. These results highlight the differential effects of TipE and TEH1 on the gating of insect sodium channels and suggest that TEH1 may play a broader role than TipE in regulating sodium channel function and neuronal excitability in vivo.     

Alteration of channel characteristics by exchange of pore-forming regions between two structurally related Ca2+ Channels

Several types of structurally homologous high voltage-gated Ca²⁺ channels (L-, P-and N-type) have been identified via biochemical, pharmacological and electrophysiological techniques. Among these channels, the cardiac L-type and the brain BI-2 Ca²⁺ channel display significantly different biophysical properties. The BI-2 channel exhibits more rapid voltage-dependent current activation and inactivation and smaller single-channel conductance compared to the L-type Ca²⁺ channel. To examine the molecular basis for the functional differences between the two structurally related Ca²⁺ channels, we measured macroscopic and single-channel currents from oocytes injected with wild-type and various chimeric channel ₁ subunit cRNAs. The results show that a chimeric channel in which the segment between S5-SS2 in repeat IV of the cardiac L-type Ca²⁺ channel, was replaced by the corresponding region of the BI-2 channel, exhibited macroscopic current activation and inactivation time-courses and single-channel conductance, characteristic of the BI-2 Ca²⁺ channel. The voltage-dependence of steady-state inactivation was not affected by the replacement. Chimeras, in which the SS2-S6 segment in repeat III or IV of the cardiac channel was replaced by the corresponding BI-2 sequence, exhibited altered macroscopic current kinetics without changes in single-channel conductance. These results suggest that part of the S5-SS2 segment plays a critical role in determining voltage-dependent current activation and inactivation and single-channel conductance and that the SS2-S6 segment may control voltage-dependent kinetics of the Ca²⁺ channel.     

Activation kinetics of single high-threshold calcium channels in the membrane of sensory neurons from mouse embryos

Summary Activation kinetics of single high-threshold inactivating (HTI orN-type) calcium channels of cultured dorsal root ganglion cells from mouse embryos was studied using a patchclamp method. Calcium channels displayed bursting activity. The open-time histogram was single exponential with an almost potential-independent mean open time _op. The closed-time histogram was multicomponent; at least three of the components were associated with the activation process. The fast exponential component with the potential-independent time constant _cl ^f included all intraburst gaps, while two slower ones with potential-dependent time constants _cl ^vs described shut times between bursts and between clusters of bursts. The burst length histogram was biexponential. The fast component with a relatively potential-independent time constant _bur ^f described short, isolated channel openings while the slow component characterized real bursts with a potential-dependent mean life time. The waiting-time histogram could be fitted by a difference of two exponentials with time constants being the same as _cl ^s and _cl ^vs . The data obtained were described in the frame of a 4-state sequential model of calcium channel activation, in which the first two stages are formally attributed to potential-dependent transmembrane transfer of two charged gating particles accompanying the channel transitions between three closed states, and the third one to fast conformational changes in channel protein leading to the opening of the channel. The rate constants for all transitions were defined. The validity of the proposed model for both low-threshold inactivating (LTI orT-type) and high-threshold noninactivating (HTN orL-type) calcium channels is discussed.     

Acute effects of thyroid hormone on sodium currents in neonatal myocytes

Sodium currents and action potentials were recorded from myocytes of neonatal rats during acute exposure to thyroid hormone (5–20 nM). One to 5 minutes after addition of thyroid hormone to the bath, decay from peak Na current was slowed, with the fractional current flowing 20 ms after onset (relative to peak current) increasing from 6±5% to 17±13% (p<0.01, n=12). Action potential durations were increased from 55±14 to 86±36 msec (p<0.05, n=6). The effects of thyroid hormone were partially reversed by lidocaine (60 M, n=5), a specific blocker of a slow sub-population of Na channels. Thus thyroid hormone interacts directly with myocyte membrane, probably by slowing of inactivation of Na channels.Abbreviations and Symbols T3 3,5,3-triiodo-L-thyronine - I_Na current carried by sodium ions - I_T3 net current attributible to T3 treatment - I₂₀ % of peak current at 20 msec after current onset - ADP₉₀ Time required for action potential to return to within 10% of baseline level     

Inactivation of calcium currents in the molluscan neuron somatic membrane

The time course of weakening of inward calcium currents (inactivation) during prolonged (of the order of 1 sec) depolarizing shifts of membrane potential was studied in isolated dialyzed neurons of snailHelix pomatia. This decay of the current recorded in this way can be approximated by two exponential functions with time constants of 20–70 and 250–350 msec, respectively. With an increase in pH of the intracellular solution to 8.5 the fast component of the decay disappeared completely; the kinetics of the slow component in this case was very slightly retarded. It is concluded that the fast component of decay of the recorded current does not reflect a change in the calcium current but is due to parallel activation of the nonspecific outward current; the slow component, however, is true in activation of the calcium current. The rate of inactivation of this current was shown to be determined by its maximal value and not by the level of the depolarizing potential shift and it depends on the conditions of accumulation of calcium ions near the inner surface of the membrane.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 14, No. 5, pp. 525–531, September–October, 1982.     

Temperature dependence of multiple high voltage activated Ca2+ channels in chick sensory neurones

The temperature dependence of high voltage activated Ca²⁺ channels has been investigated in cultured dorsal root ganglion neurones from chick embryos, using the cell-attached patch-clamp technique. The dihydropyridine sensitive L-type Ca²⁺ channel had a conductance of 23 pS, with 110 mM Ba²⁺ as charge carrier and in the presence of 3 M Bay K 8644. When the temperature was raised from 15 to 30 °C, the unitary channel current amplitude increased, with Q₁₀ value equal to 1.4. The rising phase of the averaged single-channel current became faster, with Q₁₀ value 2.7, whereas the decay phase showed a lower temperature sensitivity. Channel open probability decreased according to an exponential distribution of open and closed times. A second type of Ca²⁺ channel was identified, which was DHP-insensitive and had a lower conductance with a mean value equal to 13 pS. For the current amplitude, the Q₁₀ value was 1.3. Both activation and inactivation kinetics were strongly accelerated by an increase in temperature. The corresponding time constants gave Q₁₀ values equal to 5.9 for activation, and 2.0 for inactivation. Peak channel open probability was highly sensitive to a change in temperature, with a Q₁₀ value of 1.6. Finally, in -conotoxin GVIA pre-treated neurones, a non-inactivating DHP-insensitive Ca²⁺ channel with the lowest unitary conductance (10 pS) and a much lower temperature dependence was recorded. Single-channel current was increased by heating, with Q₁₀ value 1.3, whereas the channel kinetics were almost unaffected by temperature. Our data are consistent with the assumption that the different temperature dependence of the Ca²⁺ channel behaviours may be explained by separate gating processes of three types of Ca²⁺ channels.