Single transient K channels in mammalian sensory neurons

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.

Diminished A-type potassium current and altered firing properties in presympathetic PVN neurones in renovascular hypertensive rats

Accumulating evidence supports a contribution of the hypothalamic paraventricular nucleus (PVN) to sympathoexcitation and elevated blood pressure in renovascular hypertension. However, the underlying mechanisms resulting in altered neuronal function in hypertensive rats remain largely unknown. Here, we aimed to address whether the transient outward potassium current (I(A)) in identified rostral ventrolateral medulla (RVLM)-projecting PVN neurones is altered in hypertensive rats, and whether such changes affected single and repetitive action potential properties and associated changes in intracellular Ca(2+) levels. Patch-clamp recordings obtained from PVN-RVLM neurons showed a reduction in I(A) current magnitude and single channel conductance, and an enhanced steady-state current inactivation in hypertensive rats. Morphometric reconstructions of intracellularly labelled PVN-RVLM neurons showed a diminished dendritic surface area in hypertensive rats. Consistent with a diminished I(A) availability, action potentials in PVN-RVLM neurons in hypertensive rats were broader, decayed more slowly, and were less sensitive to the K(+) channel blocker 4-aminopyridine. Simultaneous patch clamp recordings and confocal Ca(2+) imaging demonstrated enhanced action potential-evoked intracellular Ca(2+) transients in hypertensive rats. Finally, spike broadening during repetitive firing discharge was enhanced in PVN-RVLM neurons from hypertensive rats. Altogether, our results indicate that diminished I(A) availability constitutes a contributing mechanism underlying aberrant central neuronal function in renovascular hypertension.

Voltage-gated currents distinguish parvocellular from magnocellular neurones in the rat hypothalamic paraventricular nucleus

1. Magnocellular and parvocellular neurones of the hypothalamic paraventricular nucleus (PVN) differentially regulate pituitary hormone secretion and autonomic output. Previous experiments have suggested that magnocellular, or type I neurones, and parvocellular, or type II neurones, of the PVN express different electrophysiological properties. Whole-cell patch-clamp recordings were performed in hypothalamic slices to identify the voltage-gated currents responsible for the electrophysiological differences between type I and type II PVN neurones. 2. Type I neurones, which display transient outward rectification and lack a low-threshold spike (LTS), generated a large A-type K+ current (IA) (mean +/- s.e. m.: 1127.5 +/- 126.4 pA; range: 250-3600 pA; voltage steps to -25 mV) but expressed little or no T-type Ca2+ current (IT). Type II neurones, which lack transient outward rectification but often display an LTS, expressed a smaller IA (360.1 +/- 56.3 pA; range: 40-1100 pA; voltage steps to -25 mV), and 75 % of the type II neurones generated an IT (-402.5 +/- 166.9 pA; range: -90 to -2200 pA; at peak). 3. The voltage dependence of IA was shifted to more negative values in type I neurones compared to type II neurones. Thus, the activation threshold (-53.5 +/- 0.9 and -46.1 +/- 2.6 mV), the half-activation potential (-25 +/- 1.9 and -17.9 +/- 2.0 mV), the half-inactivation potential (-80.4 +/- 9.3 and -67.2 +/- 3.0 mV), and the potential at which the current became fully inactivated (-57.4 +/- 2.1 and -49.8 +/- 1.5 mV) were more negative in type I neurones than in type II neurones, respectively. 4. IT in type II neurones activated at a threshold of -59.2 +/- 1.2 mV, peaked at -32. 6 +/- 1.7 mV, was half-inactivated at -66.9 +/- 2.2 mV, and was fully inactivated at -52.2 +/- 2.2 mV. 5. Both cell types expressed a delayed rectifier current with similar voltage dependence, although it was smaller in type I neurones (389.7 +/- 39.3 pA) than in type II neurones (586.4 +/- 76.0 pA). 6. In type I neurones IA was reduced by 41.1 +/- 7.0 % and the action potential delay caused by the transient outward rectification was reduced by 46.2 +/- 10.3 % in 5 mM 4-aminopyridine. In type II neurones IT was reduced by 66.8 +/- 10.9 % and the LTS was reduced by 76.7 +/- 7.8 % in 100 microM nickel chloride, but neither IT nor LTS was sensitive to 50 microM cadmium chloride. 7. Thus, differences in the electrophysiological properties between type I, putative magnocellular neurones and type II, putative parvocellular neurones of the PVN can be attributed to the differential expression of voltage-gated K+ and Ca2+ currents. This diversity of ion channel expression is likely to have profound effects on the response properties of these neurosecretory and non-neurosecretory neurones.

Voltage-gated potassium channels activated during action potentials in layer V neocortical pyramidal neurons

To investigate voltage-gated potassium channels underlying action potentials (APs), we simultaneously recorded neuronal APs and single K(+) channel activities, using dual patch-clamp recordings (1 whole cell and 1 cell-attached patch) in single-layer V neocortical pyramidal neurons of rat brain slices. A fast voltage-gated K(+) channel with a conductance of 37 pS (K(f)) opened briefly during AP repolarization. Activation of K(f) channels also was triggered by patch depolarization and did not require Ca(2+) influx. Activation threshold was about -20 mV and inactivation was voltage dependent. Mean duration of channel activities after single APs was 6.1 +/- 0.6 ms (mean +/- SD) at resting membrane potential (-64 mV), 6.7 +/- 0.7 ms at -54 mV, and 62 +/- 15 ms at -24 mV. The activation and inactivation properties suggest that K(f) channels function mainly in AP repolarization but not in regulation of firing. K(f) channels were sensitive to a low concentration of tetraethylammonium (TEA, 1 mM) but not to charybdotoxin (ChTX, 100 nM). Activities of A-type channels (K(A)) also were observed during AP repolarization. K(A) channels were activated by depolarization with a threshold near -45 mV, suggesting that K(A) channels function in both repolarization and timing of APs. Inactivation was voltage dependent with decay time constants of 32 +/- 6 ms at -64 mV (rest), 112 +/- 28 ms at -54 mV, and 367 +/- 34 ms at -24 mV. K(A) channels were localized in clusters and were characterized by steady-state inactivation, multiple subconductance states (36 and 19 pS), and inhibition by 5 mM 4-aminopyridine (4-AP) but not by 1 mM TEA. A delayed rectifier K(+) channel (K(dr)) with a unique conductance of 17 pS was recorded from cell-attached patches with TEA/4-AP-filled pipettes. K(dr) channels were activated by depolarization with a threshold near -25 mV and showed delayed long-lasting activation. K(dr) channels were not activated by single action potentials. Large conductance Ca(2+)-activated K(+) (BK) channels were not triggered by neuronal action potentials in normal slices and only opened as neuronal responses deteriorated (e.g., smaller or absent spikes) and in a spike-independent manner. This study provides direct evidence for different roles of various K(+) channels during action potentials in layer V neocortical pyramidal neurons. K(f) and K(A) channels contribute to AP repolarization, while K(A) channels also regulate repetitive firing. K(dr) channels also may function in regulating repetitive firing, whereas BK channels appear to be activated only in pathological conditions.

Ion channels in presynaptic nerve terminals and control of transmitter release

The primary function of the presynaptic nerve terminal is to release transmitter quanta and thus activate the postsynaptic target cell. In almost every step leading to the release of transmitter quanta, there is a substantial involvement of ion channels. In this review, the multitude of ion channels in the presynaptic terminal are surveyed. There are at least 12 different major categories of ion channels representing several tens of different ion channel types; the number of different ion channel molecules at presynaptic nerve terminals is many hundreds. We describe the different ion channel molecules at the surface membrane and inside the nerve terminal in the context of their possible role in the process of transmitter release. Frequently, a number of different ion channel molecules, with the same basic function, are present at the same nerve terminal. This is especially evident in the cases of calcium channels and potassium channels. This abundance of ion channels allows for a physiological and pharmacological fine tuning of the process of transmitter release and thus of synaptic transmission.

A-type K+ current in neurons cultured from neonatal rat hypothalamus and brain stem: modulation by angiotensin II

The regulation of A-type K+ current (I(A)) and the single channel underlying I(A) in neonatal rat hypothalamus/brain stem cultured neurons were studied with the use of the patch-clamp technique. I(A) had a threshold of activation between -30 and -25 mV (n = 14). Steady-state inactivation of I(A) occurred between -80 and -70 mV and had a membrane voltage at which I(A) was half-maximum of -52.2 mV (n = 14). The mean values for the activation and inactivation (decay) time constants during a voltage step to +20 mV were 2.1 +/- 0.3 (SE) ms (n = 8) and 13.6 +/- 1.9 ms (n = 8), respectively. Single-channel recordings from outside-out patches revealed A-type K+ channels with voltage-dependent activation, 4-aminopyridine (4-AP) sensitivity, and inactivation kinetics similar to those of I(A). The single-channel conductance obtained from cell-attached patches was 15.8 +/- 1.3 pS (n = 4) in a physiological K+ gradient and 41.2 +/- 3.7 pS (n = 5) in symmetrical 140 mM K+. Angiotensin II (Ang II, 100 nM) reduced peak I(A) by approximately 20% during a voltage step to +20 mV (n = 8). Similarly, Ang II (100 nM) markedly reduced single A-type K+ channel activity by decreasing open probability (n = 4). The actions of Ang II on I(A) and single A-type K+ channels were reversible either by addition of the selective angiotensin type 1 (AT1) receptor antagonist losartan (1 microM) or on washout of the peptide. Thus the activation of AT1 receptors inhibits a tetraethylammonium-chloride-resistant, 4-AP-sensitive I(A) and single A-type K+ channels, and this may underlie some of the actions of Ang II on electrical activity of the brain.

Single voltage-gated K+ channels and their functions in small dorsal root ganglion neurones of rat

1. Single voltage-activated K+ channels were investigated by means of the patch-clamp technique in small dorsal root ganglion (DRG) neurones in 150 microns thin slices of new-born rat DRG. It was found that K+ conductance in small DRG neurones is formed by one type of fast inactivating A-channel and four types of delayed rectifier K+ channels, which could be separated on the basis of their single-channel conductance, kinetics and sensitivity to external tetraethylammonium (TEA). 2. Potassium A-channels were observed at relatively moderate density. They were weakly sensitive to TEA and activated between -70 and +20 mV. The conductance of A-channels was about 40 pS for inward currents in symmetrical high-K+ solutions with external 5 mM TEA added to suppress other types of K+ channels. The time constant of channel inactivation (tau in) was 18.8 ms at -70 mV and 6 ms at potentials positive to -20 mV. 3. A fast delayed rectifier (DRF) channel with a conductance of 55 pS in symmetrical high-K+ solutions was the most frequent type of K+ channel. The channel activated in a broad potential range between -50 and +60 mV and demonstrated a fast deactivation within 1-3 ms after potential return to -80 mV in high-Ko+ solution. The tau in value was 90-150 ms at positive membrane potentials. The single-channel current amplitudes were blocked to 55% by 1 mM TEA. 4. Three further types of delayed rectifier K+ channels were called DR1-, DR2- and DR3- channels. Their single-channel conductances for inward currents in symmetrical high-K+ solutions were distributed between 30 and 44 pS. The channels activated in almost the same voltage range between -60 and -10 mV. Deactivation of the channels at -80 mV lasted tens of milliseconds. The channels were separated on the basis of their sensitivities to TEA. DR1-channel currents were reduced to 50% in the presence of 1 mM TEA, DR2-channel currents were reduced to about 50% by 5 mM TEA, whereas the amplitudes of currents through DR3-channels were almost unaffected by 5 mM TEA. 5. Addition of external 1 and 5 mM TEA to whole cells under current-clamp condition depolarized the cell membrane, lowered the threshold for action potential firing, prolonged action potential duration and reduced the amplitude of after-hyperpolarization. 6. It is concluded that potassium A-, DRF-, DR1-, DR2- and DR3-channels play multiple roles in the excitability of DRG neurones. Possible influences of these channels on the shape of the action potential, its firing threshold and the resting membrane potential of small DRG neurones are discussed.

Single voltage-activated Na+ and K+ channels in the somata of rat motoneurones

1. Voltage-activated Na+ and K+ channels were investigated in the soma membrane of motoneurones using the patch-clamp technique applied to thin slices of neonatal rat spinal cord. 2. One type of TTX-sensitive Na+ channel, with a conductance of 14.0 pS, was found to underlie the macroscopic Na+ conductance in the somata of motoneurones. These channels activated within a potential range between -60 and -20 mV with a potential of half-maximal activation (E50) of -38.9 mV and steepness factor (k) of 6.1 mV. 3. Kinetics of Na+ channel inactivation could be fitted with a single exponential function at all potentials investigated. The curve of the steady-state inactivation had the following parameters: a half-maximal potential (Eh,50) of -81.6 mV and k of -10.2 mV. 4. Kinetics of recovery of Na+ channels from inactivation at a potential of -80 mV were double exponential with fast and slow components of 16.2 (76%) and 153.7 ms (24%), respectively. It is suggested that the recovery of Na+ channels from inactivation plays a major role in defining the limiting firing frequency of action potentials in motoneurones. 5. Whole-cell K+ currents consisted of transient (A)- and delayed-rectifier (DR)-components. The A-component activated between -60 and +20 mV with an E50 of -33.3 mV and k of 15.7 mV. The curve of steady-state inactivation was best fitted with an Eh,50 of -82.5 mV and k of -10.2 mV. The DR-component of K+ current activated smoothly at more positive potentials. E50 and k for DR-currents were +1.4 and 16.9 mV, respectively. 6. The most frequent single K+ channel found in the somata of motoneurones was the fast inactivating A-channel with a conductance of 19.2 pS in external Ringer solution. In symmetrical high-K+ solutions the conductance was 50.9 and 39.6 pS for inward and outward currents, respectively. The channel activation took place between -60 and +20 mV. The curve of steady-state inactivation of single A-channels had an Eh,50 of -87.1 mV and k of -12.8 mV. In high-Ko+ solution A-channels demonstrated a rapid deactivation at potentials between -110 and -60 mV. The time constant of the channel deactivation depended on the membrane potential and changed from 1.5 ms at -110 mV to 6.3 ms at -60 mV. 7. Delayed-rectifier K+ channels were found in the soma membrane at a moderate density.(ABSTRACT TRUNCATED AT 250 WORDS)

Lack of effect of 4-aminopyridine on acute resetting of the type I carotid baroreceptor

Acute resetting of the type I carotid baroreceptor was examined before and after exposure to 10(-4) M 4-aminopyridine (4-AP), a blocker of the transient K+ A current (IA), using a vascularly isolated carotid sinus preparation in thiopental anesthetized dogs. Type I baroreceptor firing patterns were analysed to determine threshold pressure (Pth) at different conditioning pressures. Additionally, the ability of 10(-4) M 4-AP to induce vasoconstriction in canine carotid sinus, internal carotid and common carotid artery vascular ring segments was tested as a possible contributing mechanism to resetting. Our findings demonstrated that 10(-4) M 4-AP did not alter acute baroreceptor resetting or induce carotid artery vasoconstriction.

Shaker potassium channel gating. I: Transitions near the open state

Kinetics of single voltage-dependent Shaker potassium channels expressed in Xenopus oocytes were studied in the absence of fast N-type inactivation. Comparison of the single-channel first latency distribution and the time course of the ensemble average current showed that the activation time course and its voltage dependence are largely determined by the transitions before first opening. The open dwell time data are consistent with a single kinetically distinguishable open state. Once the channel opens, it can enter at least two closed states which are not traversed frequently during the activation process. The rate constants for the transitions among these closed states and the open state are nearly voltage-independent at depolarized voltages (> -30 mV). During the deactivation process at more negative voltages, the channel can close directly to a closed state in the activation pathway in a voltage-dependent fashion.

Internal Na+ and Mg2+ blockade of DRK1 (Kv2.1) potassium channels expressed in Xenopus oocytes. Inward rectification of a delayed rectifier

Delayed rectifier potassium channels were expressed in the membrane of Xenopus oocytes by injection of rat brain DRK1 (Kv2.1) cRNA, and currents were measured in cell-attached and inside-out patch configurations. In intact cells the current-voltage relationship displayed inward going rectification at potentials > +100 mV. Rectification was abolished by excision of membrane patches into solutions containing no Mg2+ or Na+ ions, but was restored by introducing Mg2+ or Na+ ions into the bath solution. At +50 mV, half-maximum blocking concentrations for Mg2+ and Na+ were 4.8 +/- 2.5 mM (n = 6) and 26 +/- 4 mM (n = 3) respectively. Increasing extracellular potassium concentration reduced the degree of rectification of intact cells. It is concluded that inward going rectification resulting from voltage-dependent block by internal cations can be observed with normally outwardly rectifying DRK1 channels.

A characterization of the activating structural rearrangements in voltage-dependent Shaker K+ channels

In response to changes in membrane potential, voltage-dependent ion channel proteins undergo conformational rearrangements that lead to channel opening. These rearrangements move a net charge, measured as "gating current", across the membrane. Here we characterize the effects of the pharmacological blocker 4-aminopyridine on both the K+ and gating currents of wild-type and mutant Shaker K+ channels. Our results indicate that the activation of these channels involves two distinct types of structural rearrangement. In addition to independent Hodgkin and Huxley type rearrangements for each of the four subunits, which are responsible for most of the gating charge movement, Shaker channels interconvert between two quaternary conformations during activation. The transition between the two quaternary states moves about 10% of the total gating charge, and it is selectively blocked by 4-aminopyridine.

An ionic current model for neurons in the rat medial nucleus tractus solitarii receiving sensory afferent input

1. Neurons from a horizontal slice of adult rat brainstem were examined using intracellular recording techniques. Investigations were restricted to a region within the nucleus tractus solitarii, medial to the solitary tract and centred on the obex (mNTS). Previous work has shown this restricted area of the NTS to contain the greatest concentration of aortic afferent baroreceptor terminal fields. Electrical stimulation of the tract elicited short-latency excitatory postsynaptic potentials in all neurons. 2. mNTS neurons were spontaneously active with firing frequencies ranging between 1 and 10 Hz, at resting potentials of -65 to -45 mV. These neurons did not exhibit spontaneous bursting activity. 3. Depolarizing current injection immediately evoked a finite, high-frequency spike discharge which rapidly declined to a lower steady-state level (i.e. spike frequency adaptation, SFA). Increasing depolarizations produced a marked increase in the peak instantaneous frequency but a much smaller increase in the steady-state firing level. 4. Conditioning with a hyperpolarizing prepulse resulted in a prolonged delay of up to 600 ms before the first action potential (i.e. delayed excitation, DE) with an attendant decrease in peak discharge rates. DE was modulated by both the magnitude and duration of the prestimulus hyperpolarization, as well as the magnitude of the depolarizing stimulus. Tetrodotoxin (TTX) eliminated spike discharge but had little effect on the ramp-like membrane depolarization characteristic of DE. 5. We have developed a mathematical model for mNTS neurons to facilitate our understanding of the interplay between the underlying ionic currents. It consists of a comprehensive membrane model of the Hodgkin-Huxley type coupled with a fluid compartment model describing cytoplasmic [Ca2+]i homeostasis. 6. The model suggests that (a) SFA is caused by an increase in [Ca2+]i which activates the outward K+ current, IK,Ca, and (b) DE results from the competitive interaction between the injected depolarizing current and the hyperpolarization-activated transient outward K+ currents, IA and ID. 7. We conclude that our ionic current model is capable of providing biophysical explanations for a number of phenomena associated with brainstem neurons, either during spontaneous activity or in response to patterned injections of current. This model is a potentially useful adjunct for on-going research into the central mechanisms involved in the regulation of both blood pressure and ventilation.

Kinetic study of A-type current inactivation in Lymnaea neurons

Macroscopic inactivation of A-current was studied in internally perfused Lymnaea neurons under voltage clamp conditions. Inactivation kinetics were satisfactorily described by the sum of two exponentials, suggesting the presence of two type inactivation. The kinetics of recovery from inactivation were exponential. The rate constants of the fast phase of inactivation gamma f(V) rose steeply with depolarization exposing the pronounced plateau in the range from -30 to 0 mV. The time course of inactivation in this potential range was more closely approximated with the sum of three exponentially decaying components. Calcium and hydrogen ions strongly affected the fast phase of inactivation. Calcium gave a positive shift of a part of the gamma f(V) curve on the left of the plateau. Raising the pH caused a negative shift of the right-hand branch of the gamma f(V) curve. It was shown that these effects are associated with Ca2+ and H+ binding to some specific sites of the channel protein. Two models give good fits with the experimental data. They include two pathways for fast inactivation. Calcium and hydrogen ions are assumed to selectively affect the voltage-dependent transitions related to these pathways of inactivation.

Three potassium channels in rat posterior pituitary nerve terminals

1. The patch clamp technique was used to investigate the K+ channels in the membranes of nerve terminals in thin slices prepared from the rat posterior pituitary. 2. Depolarization of the membrane produced a high density of K+ current. With a holding potential of -80 mV, test pulses to +50 mV activated a K+ current which was inactivated by 65% within 200 ms. Hyperpolarizing prepulses enhanced the transient K+ current, with half-maximal enhancement at -87 mV. Depolarizing prepulses reduced or eliminated the transient K+ current. 3. In cell-attached patches formed with pipettes containing 130 mM KCl, three types of K+ channel could be distinguished on the basis of single-channel properties. One channel had a conductance of 33 pS and was inactivated with a time constant of 18 ms. A second channel had a conductance of 134 pS and was inactivated with a time constant of 71 ms. A third channel had a conductance of 27 pS, was activated relatively slowly with a time constant of 65 ms, and was not inactivated during test pulses of up to one second in duration. 4. Inactivation of the whole-cell K+ current was a biphasic process with two exponential components. The fast component had a time constant of 22 ms (at +50 mV), corresponding well with the time constant of decay of average current in cell-attached patches containing only the rapidly inactivating K+ channel. The slow component of inactivation had a time constant of 104 ms (at +50 mV), which was similar to but slightly slower than the time constant of decay of the average current in cell-attached patches containing only the slowly inactivating K+ channel. Inactivation of the slow transient K+ current became more rapid with increasing depolarization. 5. The low-conductance rapidly inactivating K+ channel had a lower voltage threshold for activation than the other two K+ channels. 6. Both inactivating K+ channels were enhanced in a similar manner by prior hyperpolarization. There was no difference with regard to voltage mid-point or steepness. 7. The large-conductance slowly inactivating K+ channel was activated by Ca2+ at the inner membrane surface. The resting intracellular Ca2+ was sufficiently high to produce significant activation of this channel without depolarization-induced Ca2+ entry. 8. Removal of Ca2+ from the bathing solution produced a -10 mV shift in the voltage dependence of enhancement of both transient K+ currents by prior hyperpolarization. This could be explained as a surface charge effect.(ABSTRACT TRUNCATED AT 400 WORDS)

A patch-clamp study on the muscarine-sensitive potassium channel in bullfrog sympathetic ganglion cells

1. A voltage-independent K+ channel was characterized and effects of muscarine were studied in cultured bullfrog sympathetic ganglion cells using the cell-attached patch-clamp configuration. 2. Three types of single-channel current were recorded from 2- to 10-day-old cultured cells in the presence of tetraethylammonium (2-20 mM), tetrodotoxin (1-2 microM), Cd2+ (0.1 mM) and apamin (20 nM). 3. The most frequently observed channel was a voltage-independent K+ channel which was open at the resting membrane potential and had a conductance of 52.6, 78.9 and 114.9 pS at a [K+]o of 2, 40 and 100 mM, respectively. This channel was designated background K+ channel. 4. Two other channel types were observed less frequently. One had a conductance of 26 pS (external K+, 118 mM) and a long open time of several seconds at the resting membrane potential. The second channel had a smaller conductance (20 pS) and displayed a voltage-dependent activation. 5. The open probability of the background K+ channel varied between patches, ranging from 0.0005 to 0.486. The open time distribution was fitted by a single exponential with a time constant of 0.51 ms. Both of these parameters were independent of the membrane potential. The closed time distribution consisted of at least four exponentials having time constants of 0.17, 3.7, 120 ms and several seconds. 6. Muscarine (10-20 microM) applied to the membrane outside the patch pipette reversibly enhanced the activity of the background K+ channel. This effect was associated with an increase in the open probability, which resulted from an increase in the mean open time concomitant with a decrease in the mean closed time. Muscarine did not change the single-channel conductance of this channel. 7. The effects of muscarine were blocked by atropine (1 microM). 8. It is concluded that there exists a muscarine-sensitive, voltage-independent K+ channel in cultured bullfrog ganglion cells. This K+ channel appears to contribute to the generation of the resting membrane potential and underlie the slow inhibitory postsynaptic potential of these neurones in situ.

K+ channels in PC12 cells are affected by propofol

The effect on K+ currents (IK) of the general anaesthetic propofol (PR) (2,6-diisopropylphenol) was tested in undifferentiated clonal pheochromocytoma (PC 12) cells using the patch-clamp technique in whole-cell and single-channel configurations. PR decreased macroscopic IK amplitudes in a concentration-dependent way from 50 microM to 1 mM. The blocking effect was unchanged by repetitive depolarizing pulses and it was independent of the holding potential. Whereas activation of IK in control conditions was fitted by sigmoidal plus exponential time courses, only the sigmoidal time course gave an adequate fit with PR in the bath. The above effects were reversible. PR concentrations below 140 microM decreased single-channel activity for K+ channels with unitary conductance of 22 pS, in the voltage range between -40 and 60 mV from a holding potential of -50 mV. In contrast, the anaesthetic had nearly no effect on the opening probability of a channel with conductance of 10 pS. The unitary current amplitudes were unaffected in both channel types. These results suggest that PR action on IK may depend on the different blocking mechanisms of the K+ channels.

Unitary A-currents of rat locus coeruleus neurones grown in cell culture: rectification caused by internal Mg2+ and Na+

1. We have used whole-cell and single-channel recording to study the transient outward potassium current (A-current) of rat locus coeruleus neurones grown in tissue culture. The A-current was largely inactivated at the resting potential, but could be activated from sufficiently negative holding potentials during steps positive to -50 mV. The current was sensitive to 4-aminopyridine. Another slowly activating, sustained current was similar to a delayed rectifier. 2. In the on-cell configuration the unitary conductance of channels carrying A-current was 40.9 +/- 2.2 pS (n = 6) with high external potassium (140 mM) and 14.8 +/- 1.4 pS (n = 11) with 3 mM [K+]o. The unitary current-voltage relation was not linear, but had a negative slope at very positive voltages in 3 mM [K+]o. The reversal potential changed with [K]o as expected for a K+ channel. 3. The open state probability of A-current channels was voltage dependent, reaching a peak of 0.78 +/- 0.17 (seven patches). The relationships between both activation and inactivation and membrane potential were well fitted by Boltzmann expressions. Activation was half-maximum at a potential 71.9 +/- 11.8 mV (n = 4) positive to the resting potential (approximately -61 mV). Inactivation was half-complete 29.4 +/- 3.8 mV (n = 4) negative to the resting potential. There was evidence from runs analysis for slow inactivation of channels. 4. Channels showed frequent visits to substates, the most readily identifiable of which had an amplitude 0.55 +/- 0.04 (n = 5) of the fully open state. Other substates had amplitudes of around 0.25 and 0.75. Occupancy of substates was greater at negative membrane potentials. 5. A preliminary analysis of kinetic behaviour, treating visits to substates as openings, shows that open times are distributed as a single exponential. The open time was 16.2 ms (n = 4) at a voltage 100 mV positive to the resting potential, increasing with further depolarization. Closed times are distributed as the sum of three or four exponentials. First latency distributions are strongly voltage dependent and show a delay, giving a sigmoidal rise to the distribution. Increasing temperature increased unitary current and reduced mean open time. 6. The mechanism of the rectification seen in the unitary current-voltage relationship was examined using excised, inside-out patches.(ABSTRACT TRUNCATED AT 400 WORDS)

Voltage-dependent K+ channels in the sarcolemma of mouse skeletal muscle

The voltage-dependent K+ channels of the mammalian sarcolemma were studied with the patch-clamp technique in intact, enzymatically dissociated fibres from the toe muscle of the mouse. With a physiological solution (containing 2.5 mM K+) in the pipette, depolarizing pulses imposed on a cell-attached membrane patch activated K+ channels with a conductance of about 17 pS. No channel activity was observed when the pipette solution contained 2 mM tetraethylammonium (TEA), or 2 mM 4-aminopyridine (4-AP). Whole cell recordings from these very small muscle fibres showed the well-known delayed rectifier K+ outward current with a threshold of about -40 mV. The whole-cell current was completely blocked by 2 mM TEA in the bath, suggesting that the TEA-sensitive channels in the patch were also delayed rectifier channels. The inactivation properties of the channels were studied in the cell-attached mode. Averaged single-channel traces showed at least two types of channels discernible by their inactivation time course at a test potential of 60 mV. The fast type inactivated with a time constant of about 150 ms, the slow type with a time constant of about 400 ms. A little channel activity always remained during pulses lasting several minutes, indicating either the presence of a very slowly inactivating third type of K+ channel, or the tendency of the fast inactivating channels to re-open at constant voltage. No difference was seen in the single-channel amplitudes of the different types of K+ channels. The well characterized adenosine-5'-triphosphate-(ATP)-sensitive and Ca(2+)-dependent K+ channels, although present, were not active under the conditions used.(ABSTRACT TRUNCATED AT 250 WORDS)

The flickery block of ATP-dependent potassium channels of skeletal muscle by internal 4-aminopyridine

We have examined the effects of 4-aminopyridine (4-AP) on single ATP-dependent potassium channels in patches excised from frog skeletal muscle. 4-AP applied to the internal face of the membrane caused a flickery block. We could not detect any flickery block when 10 mM 4-AP was applied to the external surface of the membrane. The reduction in mean unitary current by internal 4-AP was consistent with 1:1 binding with a Kd of 3.3 mM at 0 mV. The block was voltage-dependent, increasing with depolarization with an effective valency of 0.57. Rate constants for blocking and unblocking by 4-AP were obtained by fitting beta functions to the distribution of current amplitudes. Both rate constants were voltage-dependent. At 0 mV they were 17 mM-1 ms-1 and 61 ms-1. Simulation of the block using these rate constants produced a flickery block very similar to that observed experimentally.

Properties of transient K+ currents and underlying single K+ channels in rat olfactory receptor neurons

The transient potassium current, IK(t), of enzymatically dissociated rat olfactory receptor neurons was studied using patch-clamp techniques. Upon depolarization from negative holding potentials, IK(t) activated rapidly and then inactivated with a time course described by the sum of two exponential components with time constants of 22.4 and 143 ms. Single-channel analysis revealed a further small component with a time constant of several seconds. Steady-state inactivation was complete at -20 mV and completely removed at -80 mV (midpoint -45 mV). Activation was significant at -40 mV and appeared to reach a maximum conductance at +40 mV (midpoint -13 mV). Deactivation was described by the sum of two voltage-dependent exponential components. Recovery from inactivation was extraordinarily slow (50 s at -100 mV) and the underlying processes appeared complex. IK(t) was reduced by 4-aminopyridine and tetraethylammonium applied externally. Increasing the external K+ concentration ([K+]o) from 5 to 25 mM partially removed IK(t) inactivation, usually without affecting activation kinetics. The elevated [K+]o also hyperpolarized the steady-state inactivation curve by 9 mV and significantly depolarized the voltage dependence of activation. Single transient K+ channels, with conductances of 17 and 26 pS, were observed in excised patches and often appeared to be localized into large clusters. These channels were similar to IK(t) in their kinetic, pharmacological, and voltage-dependent properties and their inactivation was also subject to modulation by [K+]o. The properties of IK(t) imply a role in action potential repolarization and suggest it may also be important in modulating spike parameters during neuronal burst firing. A simple method is also presented to correct for errors in the measurement of whole-cell resistance (Ro) that can result when patch-clamping very small cells. The analysis revealed a mean corrected Ro of 26 G omega for these cells.

Catechol blocks the fast outward potassium current in melanotrophs of the rat pituitary

The effect of catechol on the fast voltage-gated K+ current (IK(f)) of acutely dissociated rat melanotrophs was investigated in whole-cell recordings. Half-maximal inhibition of IK(f) occurred at an external concentration of 1.7 mM and this effect was associated with a decrease of the rate of the current decay. Internal catechol had no measurable effect on IK(f). Catechol appeared to be equally effective as a blocker of the slow voltage-gated K+ current (IK(s)). Despite this lack of specificity the blocking action of catechol was voltage- and frequency-independent and was rapidly reversible. Catechol therefore represents a useful alternative to 4-aminopyridine as a blocker of IK(f).

Distribution of single-channel conductances in cultured rat hippocampal neurons

1. The nonhomogeneous spatial distribution of ionic channels in neurons has been implied from intracellular recordings at somatic and dendritic locations. These reports indicate that Na- and Ca-dependent regenerative currents are distributed differently throughout the neuron. Although a variety of K conductances and a noninactivating Na conductance have been described in intracellular studies, little is known about the spatial distribution of inward and outward currents throughout different regions of the neuron. 2. We recorded from cell-attached patches from cultured hippocampal cells from 1-day-old rats. The cells were cultured for 3-21 days. The spatial distribution of a variety of ionic channels was determined by comparing the conductances from somatic and dendritic membranes. Single-channel currents obtained from cell-attached patches were identified by the time course of ensemble (averaged) responses, voltage dependence, and the effect of channel blocking agents. 3. We consistently observed that only the rapidly inactivating inward current was localized to the soma. The other channel types that we studied, including an inward noninactivating, delayed rectifier and transient A-type currents, were observed in both the somatic and dendritic regions. 4. We suggest that the distribution of ionic conductances that we have observed may be functional in limiting excitability during development of neurons.

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).

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)

Developmental regulation of a slowly-inactivating potassium conductance in rat neostriatal neurons

In late embryonic and early post-natal rat neostriatal neurons, the voltage-dependent potassium currents activated by depolarization are largely attributable to a rapidly inactivating A-current and a delayed rectifier current. Over the first 4 weeks of post-natal life, a third potassium current emerges in most cells. This slowly inactivating conductance is distinct from the A-current and delayed rectifier in voltage-dependence, kinetics and pharmacology. The properties of this conductance suggest that it may be of central importance to the integrative behavior of neostriatal neurons by controlling such features as first spike latency and interspike interval.

A five-conductance model of the action potential in the rat sympathetic neurone

The origin of the action potential in neurones has yet to be answered satisfactorily for most cells. We present here a five-conductance model of the somatic membrane of the mature and intact sympathetic neurone studied in situ in the isolated rat superior cervical ganglion under two-electrode voltage-clamp conditions. The neural membrane hosts five separate types of voltage-dependent ionic conductances, which have been isolated at 37 degrees C by using simple manipulations such as conditioning-test protocols and external ionic pharmacological treatments. The total current could be separated into two distinct inward components: (1) the sodium current, INa, and (2) the calcium current, ICa; and three outward components: (1) the delayed rectifier, IKV, (2) the transient IA, and (3) the calcium-dependent IKCa. Each current has been kinetically characterized in the framework of the Hodgkin-Huxley scheme used for the squid giant axon. Continuous mathematical functions are now available for the activation and inactivation (where present) gating mechanisms of each current which, together with the maximum conductance values measured in the experiments, allow for a satisfactory reconstruction of the individual current tracings over a wide range of membrane voltage. The results obtained are integrated in a full mathematical model which, by describing the electrical behaviour of the neurone under current-clamp conditions, leads to a quantitative understanding of the physiological firing pattern. While, as expected, the fast inward current carried by Na+ contributes to the depolarizing phase of the action potential, the spike falling phase is more complex than previous explanations. IKCa, with a minor contribution from IKV, repolarizes the neurone only under conditions of low cell internal negativity. Their role becomes less pronounced in the voltage range negative to -60 mV, where membrane repolarization allows IA to deinactivate. In the spike arising from these voltage levels the membrane repolarization is mainly sustained by IA, which proves to be the only current sufficiently fast and large enough to recharge the membrane capacitor at the speed observed during activity. Different modes of firing coexist in the same neurone and the switching from one to another is fast and governed by the membrane potential level, which makes the selection between the different voltage-dependent channel systems. The neurone thus seems to be prepared to operate within a wide voltage range; the results presented indicate the basic factors underlying the different discrete behaviours.

4-Aminopyridine causes a voltage-dependent block of the transient outward K+ current in rat melanotrophs

1. Whole-cell voltage-clamp recordings were made from acutely dissociated melanotrophs obtained from adult rats. 2. In the presence of external Na+ and Ca2+ channel blockers and 20 mM-tetraethylammonium (TEA) depolarizations to -40 mV or more evoked a fast-activating fast-inactivating outward K+ current (IK(f)). Double-pulse experiments showed that steady-state half-inactivation occurred near -37 mV; half-maximal activation of IK(f) occurred at -15 mV. Recovery from inactivation in most cells fitted a single exponential with a time constant of 40-50 ms. 3. When applied either internally or externally, 1-2.5 mM-4-aminopyridine (4-AP) substantially reduced IK(f) but the degree of block was affected by the intensity, duration and frequency of depolarizing commands. 4. Analysis of the steady-state voltage dependence of the block by 4-AP showed that half-maximal blocking occurred at approximately -31 mV. This implied that 4-AP binds to the resting state of the IK(f) channel. 5. Studies of the time dependence for the blocking or unblocking of IK(f) showed that both processes were exponential with mean time constants of 1942 ms (at -70 mV) and 726 ms (at 20 mV), respectively. Recovery from inactivation was apparently unaffected by 4-AP. 6. A four-state sequential model in which 4-AP reversibly binds to the resting state of the channel replicates the frequency dependence of the 4-AP blockade.

Enhancement of the Ca2(+)-current by a serum factor in cultured dorsal root ganglia neurons of the adult guinea pig

To investigate effects of serum factor on the Ca2(+)-spike and neurite outgrowth in cultured nerve cells, dorsal root ganglia (DRG) neurons of the adult guinea pig were cultured in a serum-free N1 medium (N1 group) and a serum-containing medium (FCS group). The maximum rate of rise (MRR) of the Ca2(+)-spike, an indicator of the maximum Ca2(+)-current, was enhanced in the FCS group on day 5 in culture. The MRR of Ca2(+)-spike remained at a low level in the N1 group (2-10 days), but neurites outgrew rapidly during 2-5 days in both the FCS and N1 groups. Replacement of a serum-free medium by a serum-containing one on day 5 caused faster increase in the MRR of the Ca2(+)-spike. The active serum component for the Ca2(+)-spike enhancement was a heat-stable, small molecule. Chronic application of dibutyryl cyclic AMP (10 microM) mimicked the serum action on the Ca2(+)-spike. Whole-cell voltage-clamp experiment by a patch electrode showed that currents through the L- and T-type Ca-channels were enhanced in FCS group. Since kinetic and voltage-dependent gating properties of Ca-channels were similar between the FCS and N1 groups, available channel density might be increased by a serum factor.

Characteristics of transient outward currents in single smooth muscle cells from the ureter of the guinea-pig

1. Two kinds of transient outward currents were observed upon depolarization of single smooth muscle cells isolated from guinea-pig ureter. The major transient outward current was through Ca2(+)-activated K+ channels (IK(Ca) which had a large conductance (130 pS; 126 mM [K+]i/5.9 mM [K+]o). 2. The smaller transient outward current (ITO) was pharmacologically separated from other membrane currents in the presence of 1 mM-Cd2+ and 2 mM-tetraethylammonium(TEA+) and was selectively blocked by 3 mM-4-aminopyridine. It peaked (approximately 200 pA) within 10 ms upon depolarization from -80 to +20 mV and its half-inactivation time was approximately 50 ms at +20 mV. Half-maximum voltages (V 1/2) for activation and inactivation were about -8 and -50 mV, respectively, in the presence of 1 mM-Cd2+ and 2 mM-TEA+. The time course of recovery from inactivation of ITO was fitted with a single-exponential function (tau = 100 ms at -80 mV). A tenfold change of [K+]o resulted in a 53 mV change in the reversal potential of the tail of ITO. 3. Cadmium reduced peak ITO and shifted the voltage dependence of activation and inactivation in the positive direction in a concentration-dependent manner. The V 1/2 for inactivation in the absence of Cd2+ was estimated to be approximately -64 mV. 4. Single-channel outward currents which appeared only in the initial part of a depolarizing pulse from about -100 mV were recorded using the cell-attached patch clamp. The decay of the ensemble average of the current was similar to the macroscopic ITO under whole-cell clamp. When the holding potential was less negative, the opening probability of the channel greatly decreased. The channel conductance in normal extracellular medium was 14 pS. 5. In ureter cells ITO resembles A-type current. ITO does not contribute significantly to the repolarization of the action potential but it may regulate membrane excitability by opposing Ca2+ current activated around the threshold of the action potential.

Experimental and modeling study of the excitability of carotid sinus baroreceptors

In this study we examined the effects of blockade of a transient K+ current with 4-aminopyridine (4-AP) on the static stimulus-response relation of myelinated carotid sinus baroreceptors (n = 8), using a vascularly isolated sinus preparation in sodium thiopental-anesthetized dogs. In one class of baroreceptors (type I), which did not fire spontaneously below the pressure threshold (Pth), 4-AP (10(-5) to 10(-4) M) decreased Pth in a dose-dependent manner and transformed the stimulus-response relation from a discontinuous, hyperbolic shape to a sigmoidal, continuous curve. After exposure to 10(-4) M of 4-AP, baroreceptors were spontaneously active below Pth. These effects of 4-AP were more pronounced in baroreceptors with a high control Pth and were independent of enhanced neurotransmitter release or changes in carotid sinus distensibility. In contrast, 4-AP had relatively little effect on type II baroreceptors, which under control conditions are characterized by a continuous, sigmoidal stimulus-response curve. We believe that these effects of 4-AP on baroreceptor discharge were mediated by blockade of a transient K+ conductance that was present at the receptor spike-initiation zone. This hypothesis was examined using a mathematical model based on the Hodgkin-Huxley axon, but modified to include the transient K+ conductance. The modeling results showed that the minimum current necessary to elicit action potential firing is an extremely sensitive function of the magnitude of this K+ conductance, supporting our experimental results obtained with 4-AP. Our findings suggest that a transient K+ conductance might play a role in the determination of Pth and that differences between type I and II receptors could be the result of differences in the effectiveness of this conductance in controlling spike-initiation zone excitability.

Voltage-dependent gating of Shaker A-type potassium channels in Drosophila muscle

The voltage-dependent gating mechanism of A1-type potassium channels coded for by the Shaker locus of Drosophila was studied using macroscopic and single-channel recording techniques on embryonic myotubes in primary culture. From a kinetic analysis of data from single A1 channels, we have concluded that all of the molecular transitions after first opening, including the inactivation transition, are voltage independent and therefore not associated with charge movement through the membrane. In contrast, at least some of the activation transitions leading to first opening are considerably voltage dependent and account for all of the voltage dependence seen in the macroscopic currents. This mechanism is similar in many ways to that of vertebrate neuronal voltage-sensitive sodium channels, and together with the sequence similarities in the S4 region suggests a conserved mechanism for voltage-dependent gating among channels with different selectivities. By testing independent and coupled models for activation and inactivation we have determined that the final opening transition and inactivation are not likely to arise from the independent action of multiple subunits, each with simple gating transitions, but rather come about through their aggregate properties. A partially coupled model accurately reproduces all of the single-channel and macroscopic data. This model will provide a framework on which to organize and understand alterations in gating that occur in Shaker variants and mutants.

Molecular basis of functional diversity of voltage-gated potassium channels in mammalian brain

Cloning and sequencing of cDNAs isolated from a rat cortex cDNA library reveals that a gene family encodes several highly homologous K+ channel forming (RCK) proteins. Functional characterization of the channels expressed in Xenopus laevis oocytes following microinjection of in vitro transcribed RCK-specific RNAs shows that each of the RCK proteins forms K+ channels that differ greatly in both their functional and pharmacological properties. This suggests that the molecular basis for the diversity of voltage-gated K+ channels in mammalian brain is based, at least partly, on the expression of several RCK proteins by a family of genes and their assembly to homooligomeric K+ channels with different functional properties.

Voltage-activated membrane currents in rat cerebellar granule neurones

1. Voltage-activated currents have been recorded from cerebellar granule neurones in explant cultures from young rats (1-9 days old). Cells were examined with whole-cell patch-clamp methods. Depolarizing pulses from a pre-pulse potential of -100 mV evoked a rapidly activated transient inward current, and an outward current which decayed in two phases. The ionic dependence, kinetics and pharmacological properties of these currents have been studied. 2. Peak inward Na+ currents in cells from 7-day-old rats were in the range 350-450 pA. No evidence was found for the presence of calcium currents. Thus, inward current was unchanged in zero Ca2+, 1 mM-EGTA solution. No inward current was obtained in medium containing 10 mM-Ba2+ and tetrodotoxin (TTX). Supplementing the pipette (i.e. intracellular) solution with Mg-ATP did not reveal any Ca2+ current. 3. Depolarizing steps (from -100 mV) in TTX-containing solution gave an early transient outward current and a late outward current. The transient current resembled IA described in other cells, and reversed close to EK in both normal and elevated potassium concentrations, indicating that K+ is the predominant charge carrier. Depolarizing steps from -50 mV failed to give a transient outward current, and gave only a slowly rising current which resembled the late potassium current, IK. 4. Inactivation of the transient current was examined by applying test depolarizations from increasingly negative pre-pulse potentials (-50 to -120 mV): half-inactivation occurred at -72 mV. Transient outward currents decayed exponentially with time constants, tau, of 7.3-25.3 ms at 0 mV. The time course of removal of inactivation in cells held at -50 mV, and given increasingly long pre-pulses to -100 mV, was exponential with tau = 35 ms. 5. Both transient and late outward currents were reversibly abolished by addition to the bathing medium of 10 mM-Ba2+ or 1 mM-quinine. Outward K+ current was not dependent on external calcium. Tetraethylammonium (20 mM) selectively reduced the late outward current; the peak transient current was reduced by less than 20%. 4-Aminopyridine (2 mM) showed little selectivity between transient and late outward currents. 6. It is concluded that cerebellar granule cells from young rats possess voltage-activated inward Na+ current as well as two types of K+ current, IA and IK. In terms of neuronal functioning, the properties of the transient outward current may confer a role in regulating excitability and in repolarization, but a definitive statement will require knowledge of the cellular location and relative densities of channels in granule cells in vivo.

Expression of a cloned rat brain potassium channel in Xenopus oocytes

Potassium channels are ubiquitous membrane proteins with essential roles in nervous tissue, but little is known about the relation between their function and their molecular structure. A complementary DNA library was made from rat hippocampus, and a complementary DNA clone (RBK-1) was isolated. The predicted sequence of the 495-amino acid protein is homologous to potassium channel proteins encoded by the Shaker locus of Drosophila and differs by only three amino acids from the expected product of a mouse clone MBK-1. Messenger RNA transcribed from RBK-1 in vitro directed the expression of potassium channels when it was injected into Xenopus oocytes. The potassium current through the expressed channels resembles both the transient (or A) and the delayed rectifier currents reported in mammalian neurons and is sensitive to both 4-aminopyridine and tetraethylammonium.

The inactivating K+ current in GH3 pituitary cells and its modification by chemical reagents

1. Whole-cell and single-channel recording techniques were applied to the study of the permeability and gating of inactivating K+ channels from clonal pituitary cells. 2. The cation selectivity sequence (measured from reversal potentials) for the channels underlying the inactivating K+ current was Tl+ greater than K+ greater than Rb+ greater than NH4+. The conductance sequence (determined from current amplitudes) was K+ = Tl+ greater than Rb+ greater than NH4+. 3. The inactivating current (IK(i] which was blocked by 4-aminopyridine (4-AP), activated at voltages more positive than -40 mV and half-inactivated at that voltage. Inactivation proceeded as the sum of two exponentials with mean time constants of 21 and 82 ms. Deactivation followed a single-exponential time course. 4. Recovery from inactivation was slow, voltage dependent and multi-exponential, taking more than 50 s near the cell's resting potential. 5. The magnitudes of outward current and of slope conductance increased as the concentration of external K+ was increased. 6. On-cell and outside-out membrane patches revealed minicurrents with gating and pharmacological properties identical to whole-cell currents. Single channels with inactivating characteristics, while rarely observed, had an average slope conductance of 6-8 pS. 7. Intracellular application of the disulphonic stilbene derivative, SITS, and the protein-modifying reagent, N-bromoacetamide (NBA), at concentrations of 0.2-1 mM for several tens of minutes dramatically slowed the decay (inactivation) of K+ currents and caused coincident increases in the magnitude of outward IK(i). 8. Extracellular application of NBA at much lower concentrations (1-100 microM) and much shorter exposure times (1-30 s) also slowed inactivation. This effect was reversible for brief applications at low doses, but became irreversible after longer exposures. 9. Both internal and external NBA shifted the steady-state inactivation-voltage relation by +10 mV and reduced inactivation at voltages more positive than 0 mV. 10. The efficacy of external NBA was independent of holding potential between -80 and 0 mV. 11. Potassium minicurrents and single channels recorded from on-cell membrane patches were not affected by application of NBA to the extrapatch membrane. In contrast, NBA reversibly slowed the decay, increased the magnitude of minicurrents and prolonged the open times of single K+ channels recorded from outside-out patches. The single-channel conductance was unchanged by NBA.(ABSTRACT TRUNCATED AT 400 WORDS)

The intrinsic electrophysiological properties of mammalian neurons: insights into central nervous system function

This article reviews the electroresponsive properties of single neurons in the mammalian central nervous system (CNS). In some of these cells the ionic conductances responsible for their excitability also endow them with autorhythmic electrical oscillatory properties. Chemical or electrical synaptic contacts between these neurons often result in network oscillations. In such networks, autorhythmic neurons may act as true oscillators (as pacemakers) or as resonators (responding preferentially to certain firing frequencies). Oscillations and resonance in the CNS are proposed to have diverse functional roles, such as (i) determining global functional states (for example, sleep-wakefulness or attention), (ii) timing in motor coordination, and (iii) specifying connectivity during development. Also, oscillation, especially in the thalamo-cortical circuits, may be related to certain neurological and psychiatric disorders. This review proposes that the autorhythmic electrical properties of central neurons and their connectivity form the basis for an intrinsic functional coordinate system that provides internal context to sensory input.

Properties of the transient outward current in rabbit atrial cells

1. Whole-cell and patch clamp techniques have been used to study the steady-state voltage dependence and the kinetics of a transient outward current, It, in single cells from rabbit atrium. 2. The steady-state voltage dependence of both activation and inactivation of It are well described by Boltzmann functions. Inactivation is fully removed at potentials negative to -70 mV and it is complete near 0 mV. The threshold for activation of It is near -30 mV and it is fully activated at +30 mV. The region of overlap between the activation and inactivation curves indicates that a steady non-inactivating current will be recorded over a membrane potential range from approximately -30 to 0 mV. 3. In general, the time course of inactivation at potentials in the range 0 to +50 mV is best described as a sum of two exponential functions. The kinetic parameters controlling these processes exhibit only very weak voltage dependence. 4. Comparison of the time course of the development of inactivation in response to long depolarizing voltage clamp steps with the development of inactivation in response to trains of brief depolarizing pulses indicates that inactivation develops very quickly and decays relatively slowly at potentials near the resting potential (e.g. -70 mV). Thus, in response to (i) a train of voltage-clamp pulses or (ii) a series of action potentials, the magnitude of It decreases due to a progressive increase in the amount of inactivation. 5. A simple model of channel gating is presented: it can account for the major aspects of the voltage dependence and kinetics of It (cf. Aldrich, 1981). 6. Cell-attached patch clamp recordings have been used to identify the single-channel or unitary events underlying the current, It. In general, only one active channel is present per patch. The single-channel conductance in normal Tyrode solution is approximately 14 pS and the current-voltage relationship is approximately linear between +50 and +150 mV with respect to rest. This information, in combination with the fully activated current-voltage characteristics from the whole-cell data, can be used to estimate the number and density of It channels per cell: these are 1600 and one per 3-4 micron 2, respectively. 7. Ensemble averages obtained from patch recordings are very similar in time course to the macroscopic or whole-cell current itself: the ensemble current rises to a peak within approximately 5 ms and decays with a biexponential time course in response to depolarizations to approximately +50 mV.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Changes in densities and kinetics of delayed rectifier potassium channels during neuronal differentiation

Single-channel K+ currents were recorded from young and mature spinal neurons cultured from Xenopus embryos to examine the bases of the developmental increases in density and in rate of activation of the macroscopic voltage-dependent delayed rectifier K+ current (IKv). K+ channels of three conductance classes (integral of 80, 30, and 15 pS) are present at both ages, but only the intermediate and small conductance classes are voltage-dependent and thus underlie IKv. The increase in the density of IKv is due to increases in the numbers of intermediate and small channels per cell, but not to changes in their open probabilities. The increase in rate of activation of IKv results from a change in the activation kinetics of the intermediate channel class alone.

Transient outward current (IA) in clonal anterior pituitary cells: blockade by aminopyridine analogs

Whole cell voltage-clamp recordings from GH3 cells, a clonal cell line derived from a rat anterior pituitary tumor, demonstrated a rapidly activating and inactivating ("transient") voltage-dependent outward current. This current, referred to as IA, was elicited by step depolarization from holding potentials negative to -50 mV, showed strong outward rectification at potentials positive to -30 mV, and exhibited steady state inactivation with V 1/2 near -64 mV. The current rose to a peak within less than 10-20 ms following depolarization and decayed in two exponential phases, IAf and IAs, with time constants of 30-50 and 500-700 ms, respectively. Both IA components exhibited similar voltage dependencies for activation and inactivation. Aminopyridines (2 mumol/1-5 mmol/l) produced a dose dependent, reversible blockade of IA (70% inhibition at 0.5 to 2 mmol/l) with the following rank order of potencies: 4-aminopyridine greater than 3,4-diaminopyridine = 3-aminopyridine greater than 2-aminopyridine. These drugs reduced the peak conductance of IA, and produced complex effects on its time-dependent decay. With submaximal degrees of block, there was an increase in the inactivation rate, suggesting that open channels are preferentially blocked by the drugs. It is concluded that GH3 pituitary cells possess an aminopyridine-sensitive transient outward current comparable to the A-current in neural cells. However, this cell line is unusual in that it expresses both rapidly and slowly decaying A-current components.

Potassium currents in rat cerebellar Purkinje neurones maintained in culture in L15 (Leibovitz) medium

Cerebellar Purkinje cells (PC) can be maintained in culture for one to two weeks in L15, a rich medium known to allow expression of a normal excitability in peripheral neurones. When examined using whole cell recordings, PC proved to be inexcitable in these conditions, and this inexcitability could be related to the presence of large outward K currents. Depolarizing steps of -100 mV revealed a voltage-dependent biphasic K current with a large early transient phase followed by a small plateau phase. The early transient phase could be selectively eliminated by holding the cell at -40 mV or by extracellularly applying 5 mM 4-aminopyridine (4-AP), whereas the plateau was abolished by 15 mM tetraethylammonium (TEA). Hereafter, these currents will be identified as the IA and the delayed current respectively, IA being the predominant current. IA activated between -25 and +65 mV with a midpoint at +3 mV; inactivation occurred between -70 and -20 mV with a midpoint at -57 mV. Current decay followed an exponential time course with a time constant of about 30 ms between -20 and +10 mV. In the cell-attached recording configuration, depolarization elicited openings of two types of K channels, one inactivating and one non-inactivating. The non-inactivating K channel probably corresponded to the delayed K current and had a conductance of 22 pS in a physiological K gradient.

Modification of K channel inactivation by papain and N-bromoacetamide

The whole-cell variation of the patch clamp technique was used to study macroscopic K current in voltage clamped GH3 cells. An inactivating, voltage-dependent K current was studied in isolation by inhibiting Ca-activated K currents with internal Ca chelators and external tetraethylammonium ions. Under control conditions, the K current inactivated in two phases with time constants of 25 and 79 ms. After treatment with either a proteolytic enzyme such as papain or the amino acid reagent N-bromoacetamide, the K current no longer inactivated rapidly, but decayed very slowly with a time constant of 500 to 750 ms. The action of papain or N-bromoacetamide on K channels is comparable to their action on Na channels, suggesting that inactivation in Na and K channels occurs by a similar mechanism.

Single transient potassium channels in human neuroblastoma cells induced to differentiate in vitro

Single channel recordings were obtained from inside-out patches of cultured human neuroblastoma cells (cell line SH-SY5Y) treated with a phorbol ester, 12-o-tetradecanoylphorbol-13-acetate (TPA) to induce differentiation. An outward current reversing near the calculated reversal potential for potassium was detected. This channel is transiently active at membrane potentials between -40 and -70 mV but with preceding hyperpolarizing pulses also at more positive potentials, up to +75 mV. The current seems to consist of two components; a slowly activating component at potentials negative to -40 mV and a fast component, more sensitive to 4-aminopyridine, seen at more positive potentials.

The interactions between potassium and sodium currents in generating action potentials in the rat sympathetic neurone

1. Membrane conductance parameters for the rat sympathetic neurone in vitro at 37 degrees C have been determined by two-electrode voltage-clamp analysis. The activation kinetics of two ionic currents, IA and IK(V), has been considered. Data for both currents are expressed in terms of Hodgkin-Huxley equations. 2. The isolated IA developed following third-order kinetics. The activation time constant, tau a, was estimated from the current time-to-peak and, for V less than or equal to -40 mV, from the IA tail current analysis upon membrane repolarization to various potentials. The maximum tau a occurred at -55 mV and varied from 0.26 to 0.82 ms in the range of potentials between -100 and +10 mV. The steady-state value of the variable a, corrected for inactivation, was evaluated in the voltage range from -60 to 0 mV; 14.4 mV are required to change a infinity e-fold. Steady-state gA was voltage dependent, increasing with depolarization to a maximum of 1.40 microS at +10 mV. 3. IK(V) was similarly analysed in isolation. The current proved to develop as a first-order process. tau n was determined by fitting a single exponential to the IK(V) rising phase and to the tail currents at the end of short depolarizing pulses. The bell-shaped voltage dependence of tau n exhibited a maximum (25.5 ms) at -30 mV, becoming minimal (1.8 ms) at -80 and +20 mV. The n infinity curve was obtained (n infinity = 0.5 at -6.54 mV; k = 8.91 mV). The mean maximum conductance, gK(V), was 0.33 microS per neurone at +10 mV. 4. Single spikes have been elicited by brief current pulses at membrane potentials from -40 to -100 mV under two-electrode current-clamp conditions in normal saline and in the presence of blockers of the ICa-IK(Ca) (Cd2+) and/or IK(V) (TEA, tetraethylammonium) systems. Spike repolarization was affected by the suppression of either current in the depolarized neurone, but was insensitive to both treatments when the spike arose from holding levels negative to -75 to -80 mV, indicating that at these membrane potentials the IA current mainly, if not exclusively, contributes to the action potential falling phase. 5. The basic features of the sympathetic neurone action potential were reconstructed by simulations based on present and previous voltage-clamp characterization of the IA, IK(V) and INa conductances.(ABSTRACT TRUNCATED AT 400 WORDS)

Voltage-dependent K+ currents and underlying single K+ channels in pheochromocytoma cells

Properties of the whole-cell K+ currents and voltage-dependent activation and inactivation properties of single K+ channels in clonal pheochromocytoma (PC-12) cells were studied using the patch-clamp recording technique. Depolarizing pulses elicited slowly inactivating whole-cell K+ currents, which were blocked by external application of tetraethylammonium+, 4-aminopyridine, and quinidine. The amplitudes and time courses of these K+ currents were largely independent of the prepulse voltage. Although pharmacological agents and manipulation of the voltage-clamp pulse protocol failed to reveal any additional separable whole-cell currents in a majority of the cells examined, single-channel recordings showed that, in addition to the large Ca++-dependent K+ channels described previously in many other preparations, PC-12 cells had at least four distinct types of K+ channels activated by depolarization. These four types of K+ channels differed in the open-channel current-voltage relation, time course of activation and inactivation, and voltage dependence of activation and inactivation. These K+ channels were designated the Kw, Kz, Ky, and Kx channels. The typical chord conductances of these channels were 18, 12, 7, and 7 pS in the excised configuration using Na+-free saline solutions. These four types of K+ channels opened in the presence of low concentrations of internal Ca++ (1 nM). Their voltage-dependent gating properties can account for the properties of the whole-cell K+ currents in PC-12 cells.

The influence of capsaicin on membrane currents in dorsal root ganglion neurones of guinea-pig and chicken

The effect of capsaicin on voltage-dependent membrane currents of isolated dorsal root ganglia (DRG) neurones of guinea-pig and chicken were investigated by the voltage-clamp technique and intracellular perfusion. In both species, administration of capsaicin (3 X 10(-5) M) to the outer surface of the cell membrane reduced the amplitude and accelerated the inactivation of the fast inactivating potassium current. In contrast, 3,4-diaminopyridine (3,4-DAP) reduced the fast potassium current without affecting the inactivation. Combined application of capsaicin and 3,4-DAP was more effective than either drug alone. The slow potassium current was diminished by capsaicin but not affected by 3,4-DAP. Capsaicin (3 X 10(-5) M) applied to the internal surface of the membrane had little effect on the fast outward current but primarily decreased the amplitude of the slow potassium current. Two subpopulations of sodium currents could be demonstrated in guinea-pig neurones according to their tetrodotoxin (TTX) sensitivity. In type I neurones the sodium current was completely blocked by TTX; type II neurones exhibited a TTX-sensitive as well as a TTX-resistant inward current. Capsaicin (3 X 10(-5) M) applied externally reduced the maximal amplitude of both current components. The time course of inactivation was delayed only in the TTX-resistant sodium current. The effect of capsaicin on Na-currents of DRG neurones was similar in guinea-pigs and chicken. In DRG neurones of chicken, only TTX-sensitive currents were observed. In both species the steady-state inactivation of the sodium currents was shifted by capsaicin to more negative potentials.

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.