Calcium-dependent slow outward current in visceral primary afferent neurones of the rabbit

Sensory Neurons, Ion Channels, Inflammation and the Onset of Neuropathic Pain

Neuropathic pain often fails to respond to conventional pain management procedures. here we review the aetiology of neuropathic pain as would result from peripheral neuropathy or injury. We show that inflammatory mediators released from damaged nerves and tissue are responsible for triggering ectopic activity in primary afferents and that this, in turn, provokes increased spinal cord activity and the development of ‘central sensitization’. Although evidence is mounting to support the role of interleukin-1β, prostaglandins and other cytokines in the onset of neuropathic pain, the clinical efficacy of drugs which antagonize or prevent the actions of these mediators is yet to be determined. basic science findings do, however, support the use of pre-emptive analgesia during procedures which involve nerve manipulation and the use of anti-inflammatory steroids as soon as possible following traumatic nerve injury.

Cyclosporine A modulation of Ca++ activated K+ channels in cardiac sensory afferent neurons

Whole-cell and single channel recordings were used to characterize the effects of the immunosuppressant cyclosporine A (CsA) on cardiac sensory neurons (CSN) of the nodose ganglia. Application of 10 nM CsA resulted in a 29.1% decrease in CSN input resistance and an average -8+/-3 mV hyperpolarization of membrane potential. Application of 10 nM CsA had no effect on evoked Ca++ currents but increased evoked K+ currents by 158.9+/-24%. Application of 10 nM CsA significantly increased the open probability of KCa channels by 183+/-9%. These results suggest that application of CsA results in the activation of KCa channels in cardiac sensory neurons and this effect may contribute to the cellular mechanisms underlying CsA modulation of vagal afferent neurons.

Tetraethylammonium-sensitive calcium-sensitive potassium current in a subclass of the bullfrog dorsal root ganglion cells

Bullfrog dorsal root ganglion (DRG) cells were classified into three types, As, Ar and C, according to their electrophysiological properties. Actions of tetraethylammonium (TEA; 100 microM-100 mM) on As-type cells were examined using current- and voltage-clamp methods; TEA caused a membrane depolarization or an inward current, associated with a decrease in membrane conductance. These TEA-induced responses reversed in polarity at -85 to -90 mV, and the change in reversal potential followed the Nemst equation as extracellular K+ concentration was changed. The TEA-induced responses were reversibly inhibited by Ca(+2)-free/high-Mg+2 solutions and inorganic Ca blockers. It is concluded that bullfrog DRG As-type cells might be also endowed with Ca-sensitive K channels which may be open at rest and blocked by TEA.

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

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

Role of a Ca(2+)-dependent slow afterhyperpolarization in prostaglandin E2-induced sensitization of cultured rat sensory neurons

To determine if inhibition of a Ca(2+)-dependent slow afterhyperpolarization (AHPslow) contributes to prostaglandin E2 (PGE2)-induced sensitization of DRG neurons, we have used patch-clamp electrophysiological techniques on cultured dorsal root ganglion (DRG) neurons from the adult rat. In support of a role for AHPslow in sensitization of DRG neurons, we demonstrate that: (1) AHPslow expression is restricted to a subpopulation of putative nociceptors; (2) burst duration is controlled by AHPslow in these neurons; and (3) in some neurons, PGE2 decreases AHPslow and produces a concomitant increase in the number of action potentials generated in response to depolarizing current injection. However, our results also demonstrate that AHPslow modulation is not sufficient to explain PGE2-induced sensitization in the majority of DRG neurons because: (1) the size of the population of DRG neurons expressing AHPslow is less than half the size of the population of DRG neurons sensitized by PGE2; (2) PGE2 produces a decrease in action potential threshold as well as an increase in the number of action potentials in response to current injection, while inhibition of AHPslow has little effect on threshold; and (3) the sensitizing effects of PGE2 are dissociated from its effects on AHPslow in more than half of neurons tested. We conclude that PGE2-induced sensitization must involve the modulation of ionic currents in addition to that underlying AHPslow.

Channels underlying the slow afterhyperpolarization in hippocampal pyramidal neurons: neurotransmitters modulate the open probability

The slow afterhyperpolarization in hippocampal pyramidal neurons is mediated by a calcium-activated potassium current (IAHP) and is a target for variety of different neurotransmitters. The characteristics of the channels underlying IAHP and how they are modulated by neurotransmitters are, however, unknown. In this study, we have examined the properties of the channels underlying IAHP using fluctuation analysis of the macroscopic current. Our results indicate that this channel has a unitary conductance of 2-5 pS and a mean open time of about 2 ms. When the peak amplitude of IAHP was maximal, these channels have an open probability of 0.4. Noradrenaline and carbachol reduced IAHP amplitude by lowering open channel probability. These result indicate that a novel calcium-activated potassium channel underlies IAHP. This channel is modulated in a similar fashion by two different transmitter systems that utilize distinct protein kinases.

The slow Ca(2+)-activated K+ current, IAHP, in the rat sympathetic neurone

1. Adult and intact sympathetic neurones of the rat superior cervical ganglion maintained in vitro at 37 degrees C were analysed using the two-electrode voltage-clamp technique in order to investigate the slow component of the Ca(2+)-dependent K+ current, IAHP. 2. The relationship between the after-hyperpolarization (AHP) conductance, gAHP, and estimated Ca2+ influx resulting from short-duration calcium currents evoked at various voltages proved to be linear over a wide range of injected Ca2+ charge. An inflow of about 1.7 x 10(7) Ca2+ ions was required before significant activation of gAHP occurred. After priming, the gAHP sensitivity was about 0.3 nS pC-1 of Ca2+ inward charge. 3. IAHP was repeatedly measured at different membrane potentials; its amplitude decreased linearly with membrane hyperpolarization and was mostly abolished close to the K+ reversal potential, EK (-93 mV). The monoexponential decay rate of IAHP was a linear function of total Ca2+ entry and was not significantly altered by membrane potential in the -40 to -80 mV range. 4. Voltage-clamp tracings of IAHP could be modelled as a difference between two exponentials with tau on approximately 5 ms and tau off = 50-250 ms. 5. Sympathetic neurones discharged only once at the onset of a long-lasting depolarizing step. If IAHP was selectively blocked by apamin or D-tubocurarine treatments, accommodation was abolished and an unusual repetitive firing appeared. 6. Summation of IAHP was demonstrated under voltage-clamp conditions when the depolarizing steps were repeated sufficiently close to one another. Under current-clamp conditions the threshold depolarizing charge for action potential discharge significantly increased with progressive pulse numbers in the train, suggesting that an opposing conductance was accumulating with repetitive firing. This frequency-dependent spike firing ability was eliminated by pharmacological inhibition of the slow IAHP. 7. The IAHP was significantly activated by a single action potential; it was turned on cumulatively by Ca2+ load during successive action potential discharge and acted to further limit cell excitability.

Calcium-activated potassium channels in rat visceral sensory afferents

The purpose of the present study was to describe, at the single-channel level, the activity of a calcium-sensitive potassium channel in rat visceral-sensory neurons which has been suggested to be involved in sensory neuron excitability. Single-channel recordings in the inside-out configuration identified a 220 pS conductance calcium-activated potassium channel (KCa). From a -20 mV holding potential, increasing [Ca2+]i from 0.01 microM to 1.0 microM increased the open probability of this channel 92% (from 0.12 to 0.23). However, from a +20 mV holding potential, increasing [Ca2+]i from 0.01 to 1.0 microM increased the open probability by 326% (from 0.15 to 0.64). In addition, this large conductance KCa channel was blocked by TEA (1.0 microM) and charybdotoxin (40 microM) when applied to the external surface. These results are the first to characterize a large conductance KCa channel in the sensory afferent neurons of the rat nodose ganglia and should further expand the understanding of the ionic currents involved in the regulation of sensory afferent neuronal activity.

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

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

Calcium-activated hyperpolarizations in rat locus coeruleus neurons in vitro

1. Intracellular recordings were made from rat locus coeruleus (LC) neurons in completely submerged brain slices. Trains of action potentials in LC neurons were followed by a prolonged post-stimulus hyperpolarization (PSH). If trains were elicited with depolarizing current pulses of sufficient intensity, PSH was composed of a fast, early component (PSHE) and a slow, late component (PSHL). PSH which followed trains elicited with lower intensity depolarizing current pulses consisted only of PSHL. 2. Both PSHE and PSHL were augmented by increasing the number of action potentials in the train and both were associated with an increase in membrane conductance. The reversal potential for PSHE was -108 mV and for PSHL it was -114 mV. 3. When a hybrid voltage clamp protocol was used, the current underlying PSH (IPSH) was observed to consist of an early, rapidly decaying component, IE, followed by a late, slower decaying component, IL. The time course of decay of IPSH was biexponential with the time constant of decay of IL more than one order of magnitude larger than the time constant of decay of IE. An increase in the concentration of external K+ shifted the reversal potentials for IE and IL in the depolarizing direction; the mean value of shift per tenfold increase in external K+ concentration was 57.1 mV for IE and 57.6 mV for IL. 4. Both PSHE and PSHL were inhibited by lowering the external Ca2+ concentration or by application of the Ca2+ channel blockers Cd2+ (200-500 microM) or nifedipine (100 microM). Intracellular injection of EGTA abolished both components of PSH. Increasing the external Ca2+ concentration augmented both PSH components. 5. Superfusion of dantrolene (25 microM) or ryanodine (20 microM) decreased the amplitude and duration of PSHL with much less effect on PSHE. 6. d-Tubocurarine (20-200 microM) selectively blocked PSHE with no effect on PSHL; this effect is the same as that of apamin which we have previously described. Superfusion with charybdotoxin (40 nM) or TEA (400 microM-1 mM) did not reduce PSHE or PSHL. 7. Inhibition of IA by 4-aminopyridine or 2,4-diaminopyridine also did not reduce either component of PSH. In fact, these agents slightly augmented both components of PSH; this effect was probably secondary to the prolongation of action potential duration. Superfusion of TEA in concentrations of 2-10 mM increased the size and duration of PSHL and increased the duration but decreased the size of PSHE.(ABSTRACT TRUNCATED AT 400 WORDS)

Substance P inhibits activation of calcium-dependent potassium conductances in guinea-pig myenteric neurones

1. Intracellular recordings were made from myenteric AH neurones of the guinea-pig ileum in vitro. Some experiments were done with a single-electrode voltage clamp to measure membrane currents. 2. Substance P (SP) applied by superfusion (10 nM-300 nM), pressure ejection (100 nM-10 microM, 760 mmHg, for 10-20 ms) or ionophoresis (1 mM, 100 nA, for 0.2 s) caused a membrane depolarization and an inward current, associated with a decrease in potassium conductance. 3. The SP-induced depolarization was abolished within 15 min by superfusion with calcium-free/high-magnesium (10 mM) solution or solutions containing cobalt, manganese or nickel at 1-3 mM. The response persisted even after 40-60 min of superfusion with calcium-free/normal-magnesium (1.2 mM) solution. In all these solutions, synaptic potentials were abolished within 5 min. 4. SP inhibited a slowly developing outward current and an outward tail current during and after a long depolarizing command pulse (2-10 s), and an outward after-current following single or multiple brief depolarizing command pulses (10-50 ms). These outward currents were suppressed in calcium-free/high-magnesium solution. 5. SP depressed both a calcium-dependent slow after-hyperpolarization following the action potential and an outward after-current preceded by a brief depolarizing command. Both the SP-induced depolarization and the SP-induced inward current were augmented when the peptide was pressure-ejected during the recovery phase of the slow after-hyperpolarization and during that of the slow outward after-current, but both of them were inhibited or almost abolished when SP was applied immediately after spike initiation or a brief depolarizing command. 6. The SP-induced response was depressed by barium (1-2 mM). The SP response was not inhibited by tetraethylammonium at low concentrations (5-10 mM), but was depressed at high concentration (20 mM). 7. Superfusion (1-10 nM) or pressure application of a calcium ionophore, A23187, inhibited or even reversed the SP depolarization and the SP-induced inward current. 8. These results indicate that SP inhibits activation of a calcium-dependent potassium conductance which contributes to both the slow after-hyperpolarization and the resting membrane potential. SP may affect the process by which calcium activates this potassium conductance.

Ca(2+)-activated K+ currents underlying the afterhyperpolarization in guinea pig vagal neurons: a role for Ca(2+)-activated Ca2+ release

We examined the possibility that Ca2+ released from intracellular stores could activate K+ currents underlying the afterhyperpolarization (AHP) in neurons. In neurons of the dorsal motor nucleus of the vagus, the current underlying the AHP had two components: a rapidly decaying component that was maximal following the action potential (GkCa,1) and a slower component that had a distinct rising phase (GkCa,2). Both components required influx of extracellular Ca2+ for their activation, and neither was blocked by extracellular TEA (10 mM). GkCa,1 was selectively blocked by apamin, whereas GkCa,2 was selectively reduced by noradrenaline. The time course of GkCa,2 was markedly temperature sensitive. GkCa,2 was selectively blocked by application of ryanodine or sodium dantrolene, or by loading cells with ruthenium red. These results suggest that influx of Ca2+ directly gates one class of K+ channels and leads to release of Ca2+ from intracellular stores, which activates a different class of K+ channel.

Slowly inactivating potassium current in cultured bull-frog primary afferent and sympathetic neurones

1. Cultured bull-frog dorsal root ganglion cells were voltage clamped in the whole-cell configuration. The cells were superfused with a nominally calcium-free Ringer solution containing tetrodotoxin (3 microM), magnesium (10 mM), cobalt (1 mM), barium (2 mM), 4-aminopyridine (3 mM) and caesium (2 mM). 2. Step depolarizations (10-40 mV, 100-300 ms) from a holding potential close to the rest (typically -70 mV) evoked an outward current (IK) followed by an outward tail current. The peak amplitude of the current was reduced to less than 10% by tetraethylammonium (30 mM). 3. IK developed to its peak in 200 ms at -30 mV. Tail currents reversed at potentials that changed according to the logarithm of the extracellular potassium concentrations. 4. Tail currents declined to the baseline according to an exponential function of time (tau congruent to 40 ms at -60 mV) and its reciprocal time constant increased e-fold with a 13 mV hyperpolarization. 5. The current inactivated during sustained (1-20 s) depolarizing pulses according to a single exponential function (tau congruent to 3 s). 6. The peak amplitude of IK at -30 mV was progressively increased as the holding potential was made more negative than -70 mV reaching the maximum with step depolarizations from -120 mV. Reversed phenomenon was observed as the holding potential was made less negative than -70 mV. 7. The removal of the steady-state inactivation occurred along with a single exponential function and the time constant was decreased from 70 ms at -70 mV to 10 ms at -120 mV. 8. It is suggested that a slowly inactivating potassium current which we called IK in amphibian sensory neurones could be a class of a 'delayed' rectifier potassium current. A potassium current with properties indistinguishable from those which have been described for the sensory IK also occurred in cultured bull-frog sympathetic neurones. 9. Forskolin (1-30 microM) and 1,9-dideoxy forskolin (10 microM) reduced the amplitude of IK by up to 85% but these actions were not mimicked by any of 8-bromo-cyclic AMP (1 mM), dibutyryl cyclic AMP (1 mM) and 3-isobutyl-1-methylxanthine (1 mM). A hydrophilic forskolin analogue, 7-O-hemisuccinyl-7-deacetyl forskolin (10 microM), was about one-tenth as potent as forskolin (10 microM).

ATP regulates muscarine-sensitive potassium current in dissociated bull-frog primary afferent neurones

1. Bull-frog dorsal root ganglion cells in primary culture were voltage clamped in the whole-cell configuration. The pipette solution contained ATP (5 mM). 2. Step depolarizations (5-70 mV, 0.1-1 s) from a holding potential close to the resting potential (range, -64 to -79 mV) evoked a non-inactivating potassium current with properties indistinguishable from those which have been reported for the M-current of bull-frog sympathetic neurones. 3. An unhydrolysable ATP analogue APP(NH)P (5 mM), substitute with ATP in the pipette solution, did not support the M-current activation. 4. Bath application of ATP (30 nM-30 microM) reduced the amplitude of the M-current in a concentration-dependent manner, congruent to 50% inhibition of the current occurring with 1 microM-ATP. The main effect of ATP was to reduce the maximum M-conductance without changing the activation and deactivation kinetics of the M-current. 5. Essentially the same results were obtained with ADP (0.1-30 microM) and alpha, beta-methylene-ATP (10-30 microM). AMP (10-100 microM) and adenosine (10-30 microM) were without effect on the M-current. 6. The ATP-induced inhibition of the M-current was irreversible when an unhydrolysable GTP analogue GTP-gamma-S (10-30 microM) was present in the pipette solution. ATP (3 microM) reduced the amplitude of the M-current only by about 10% when GDP-beta-S (100 microM) was present in the pipette solution. Pre-treatment of the cells with pertussis toxin (IAP; 500 ng ml-1) for 24 h at 24 degrees C did not prevent the ATP-induced M-current inhibition. 7. Phorbol 12-myristate 13-acetate (PMA; 1-3 microM) reduced the amplitude of the M-current to about 50%. A reduction in the M-current amplitude by PMA (3 microM) and ATP (10 microM) was attenuated when staurosporine (200 nM) was present in the pipette solution. Forskolin (10 microM) was without effect on the M-current. 8. It is concluded that ATP acting at P2 receptors, associated with an IAP-insensitive GTP-binding protein, inhibits the M-current in amphibian primary afferent neurones.