Computational study of enhanced excitability in Hermissenda: membrane conductances modulated by 5-HT

Serotonin (5-HT) applied to the exposed but otherwise intact nervous system results in enhanced excitability of Hermissenda type-B photoreceptors. Several ion currents in the type-B photoreceptors are modulated by 5-HT, including the A-type K⁺ current (I_K,A), sustained Ca²⁺ current (I_Ca,S), Ca-dependent K⁺ current (I_K,Ca), and a hyperpolarization-activated inward rectifier current (I_h). In this study, we developed a computational model that reproduces physiological characteristics of type B photoreceptors, e.g. resting membrane potential, dark-adapted spike activity, spike width, and the amplitude difference between somatic and axonal spikes. We then used the model to investigate the contribution of different ion currents modulated by 5-HT to the magnitudes of enhanced excitability produced by 5-HT. Ion currents were systematically varied within limits observed experimentally, both individually and in combinations. A reduction of I_K,A or I_K,Ca, or an increase in I_h enhanced excitability by 20–50%. Decreasing I_Ca,S produced a dramatic decrease in excitability. Reductions of I_K,V produced only minimal increases in excitability, suggesting that I_K,V probably plays a minor role in 5-HT induced enhanced excitability. Combinations of changes in I_K,A, I_K,Ca, I_h and I_Ca,S produced increases in excitability comparable to experimental observations. After 5-HT application, the cell's depolarization force is shifted from the I_h–I_Ca,S combination to predominantly I_h.     

A prolonged,voltage-dependent calcium permeability revealed by tetraethylammonium in the soma and axon of Aplysia giant neuron

The soma but not the axon of the giant neuron, R2, of Aplysia can generate an all-or-none Ca spike in Na-free or TTX-containing medium (Junge and Miller, 1974). Extracellular axonal recordings made at several distances from the soma provide evidence that the transition in ability to fire a spike in Na-free medium occurs within the first 250 μm of the axon. Application of 25 mM TEA-Br to the bathing medium causes a more than tenfold increase in the duration of the somatic action potential. The duration of the axonal action potential in TEA decreases with distance from the soma. At distances greater than 3 mm from the soma this concentration of TEA causes little or no increase in the duration of the axon spike. The effect of 25 mM TEA on both the soma and proximal axon is blocked reversibly by 30 mM CoCl₂ or 1 mM CdCl₂. The duration of the somatic action potential in TEA increases with an increase in Ca concentration of the bath. At a constant concentration of Na, the voltage level of the somatic plateau increases with Ca concentration in the manner predicted for a Ca electrode. In the presence of 11 mM Ca²⁺ the potential of the plateau is relatively insensitive to Na concentration. The TEA plateau in R2 reveals a prolonged voltage-dependent permeability to Ca. The duration of the plateau may indicate the degree of Ca activation during a spike.     

Low dose of dopamine may stimulate prolactin secretion by increasing fast potassium currents

Dopamine (DA) released from the hypothalamus tonically inhibits pituitary lactotrophs. DA (at micromolar concentration) opens potassium channels, hyperpolarizing the lactotrophs and thus preventing the calcium influx that triggers prolactin hormone release. Surprisingly, at concentrations ∼1000 lower, DA can stimulate prolactin secretion. Here, we investigated whether an increase in a K⁺ current could mediate this stimulatory effect. We considered the fast K⁺ currents flowing through large-conductance BK channels and through A-type channels. We developed a minimal lactotroph model to investigate the effects of these two currents. Both I _BK and I _A could transform the electrical pattern of activity from spiking to bursting, but through distinct mechanisms. I _BK always increased the intracellular Ca²⁺ concentration, while I _A could either increase or decrease it. Thus, the stimulatory effects of DA could be mediated by a fast K⁺ conductance which converts tonically spiking cells to bursters. In addition, the study illustrates that a heterogeneous distribution of fast K⁺ conductances could cause heterogeneous lactotroph firing patterns. Action Editor: Christiane Linster     

A re-excitation mechanism for strychnine-induced doublets in molluscan neurons

The effects of strychnine on Aplysia R2 neurons were evaluated using simultaneous intracellular recordings of the soma and axon potentials. 1 mM strychnine produced a slight enlargement of the somatic spike and a large increase of the axon spike duration. Following direct stimulation, the soma displayed depolarizing afterpotentials ( DAPs ) which might trigger extra-spikes, both produced electronically by long-lasting axon spikes. Cobalt suppressed both the axon spike lengthening and the somatic extra-spikes or DAPs , and induced large depolarizing shifts in the soma. The region of largest spike lengthening (proximal axon) had a large density of Ca channels. The different effects of strychnine on the soma and on the axon were assumed to result from a selective blockage of the V-dependent K channels which would predominate in the axon whereas Ca-activated K channels would predominate in the soma.     

Inhibitory Effects of Honokiol on the Voltage-Gated Potassium Channels in Freshly Isolated Mouse Dorsal Root Ganglion Neurons

Voltage-gated potassium (K_V) currents, subdivided into rapidly inactivating A-type currents (I _A) and slowly inactivating delayed rectifier currents (I _K), play a fundamental role in modulating pain by controlling neuronal excitability. The effects of Honokiol (Hon), a natural biphenolic compound derived from Magnolia officinalis, on K_V currents were investigated in freshly isolated mouse dorsal root ganglion neurons using the whole-cell patch clamp technique. Results showed that Hon inhibited I _A and I _K in concentration-dependent manner. The IC₅₀ values for block of I _A and I _K were 30.5 and 25.7 µM, respectively. Hon (30 µM) shifted the steady-state activation curves of I _A and I _K to positive potentials by 17.6 and 16.7 mV, whereas inactivation and recovery from the inactivated state of I _A were unaffected. These results suggest that Hon preferentially interacts with the active states of the I _A and I _K channels, and has no effect on the resting state and inactivated state of the I _A channel. Blockade on K⁺ channels by Hon may contribute to its antinociceptive effect, especially anti-inflammatory pain.

     

The Influences of I h on Temporal Summation in Hippocampal CA1 Pyramidal Neurons: A Modeling Study

Recent experimental and theoretical studies have found that active dendritic ionic currents can compensate for the effects of electrotonic attenuation. In particular, temporal summation, the percentage increase in peak somatic voltage responses invoked by a synaptic input train, is independent of location of the synaptic input in hippocampal CA1 pyramidal neurons under normal conditions. This independence, known as normalization of temporal summation, is destroyed when the hyperpolarization-activated current, I _h, is blocked [Magee JC (1999a), Nature Neurosci. 2: 508–514]. Using a compartmental model derived from morphological recordings of hippocampal CA1 pyramidal neurons, we examined the hypothesis that I _h was primarily responsible for normalization of temporal summation. We concluded that this hypothesis was incomplete. With a model that included I _h, the persistent Na⁺ current (I _NaP), and the transient A-type K⁺ current (I _A), however, we observed normalization of temporal summation across a wide range of synaptic input frequencies, in keeping with experimental observations.     

Adaptation and accommodation in the squid axon

Current clamp data of the squid axon indicate that there is a qualitative change in the adaptive response as the magnitude of the current step is increased. Large stimulus currents have a strong inhibitory effect on spike generation and on active responses in general. Such currents always lead to only one action-potential and to the elimination of post-spike subthreshold oscillation. In view of a direct connection between stimulus current and potassium current I _K, the potassium channel of the Hodgkin-Huxley model is reinterpreted in a natural way such that the K⁺ conductance is directly dependent on I _K in addition to a voltage dependence. The I-_Kdependence seems to dominate whenever the stimulus current is greater than approximately 35 μA/cm². For current ramps, and large current steps, such a current formulation leads to good agreement with the data.     

Axons Amplify Somatic Incomplete Spikes into Uniform Amplitudes in Mouse Cortical Pyramidal Neurons

Background

Action potentials are the essential unit of neuronal encoding. Somatic sequential spikes in the central nervous system appear various in amplitudes. To be effective neuronal codes, these spikes should be propagated to axonal terminals where they activate the synapses and drive postsynaptic neurons. It remains unclear whether these effective neuronal codes are based on spike timing orders and/or amplitudes.

Methodology/Principal Findings

We investigated this fundamental issue by simultaneously recording the axon versus soma of identical neurons and presynaptic vs. postsynaptic neurons in the cortical slices. The axons enable somatic spikes in low amplitude be enlarged, which activate synaptic transmission in consistent patterns. This facilitation in the propagation of sequential spikes through the axons is mechanistically founded by the short refractory periods, large currents and high opening probability of axonal voltage-gated sodium channels.

Conclusion/Significance

An amplification of somatic incomplete spikes into axonal complete ones makes sequential spikes to activate consistent synaptic transmission. Therefore, neuronal encoding is likely based on spike timing order, instead of graded analogues.     

Sodium Metabisulfite Modulation of Potassium Channels in Pain-Sensing Dorsal Root Ganglion Neurons

The effects of sodium metabisulfite (SMB), a general food preservative, on potassium currents in rat dorsal root ganglion (DRG) neurons were investigated using the whole-cell patch-clamp technique. SMB increased the amplitudes of both transient outward potassium currents and delayed rectifier potassium current in concentration- and voltage-dependent manner. The transient outward potassium currents (TOCs) include a fast inactivating (A-current or I _A) current and a slow inactivating (D-current or I _D) current. SMB majorly increased I_A, and I_D was little affected. SMB did not affect the activation process of transient outward currents (TOCs), but the inactivation curve of TOCs was shifted to more positive potentials. The inactivation time constants of TOCs were also increased by SMB. For delayed rectifier potassium current (I _K), SMB shifted the activation curve to hyperpolarizing direction. SMB differently affected TOCs and I _K, its effects major on A-type K⁺ channels, which play a role in adjusting pain sensitivity in response to peripheral redox conditions. SMB did not increase TOCs and I _K when adding DTT in pipette solution. These results suggested that SMB might oxidize potassium channels, which relate to adjusting pain sensitivity in pain-sensing DRG neurons.     

Axonal contribution to subthreshold currents inaplysia bursting pacemaker neurons

The contribution of axonal activity to the ionic currents which generate bursting pacemaker activity was studied by using the two-electrode voltage-clamp technique in Aplysia bursting neuron somata in conjunction with intraaxonal voltage recordings. Depolarizing voltage-clamp pulses applied to bursting cell somata triggered axonal action potentials. The voltage-clamp current recording exhibited transient inward current "notches" corresponding to each of the axonal spikes. The addition of 50 microM tetrodotoxin (TTX) to the bathing medium blocked the fast axonal spikes and current notches, revealing a slower axonal spike which was blocked by the replacement of external Ca2+ with Co2+. The inward current evoked by applying a depolarizing voltage-clamp pulse in the soma is distorted by the occurrence of the axonal Ca2+ spike. Elimination of the axonal spike, by injecting hyperpolarizing current into the axon, changes both the time course and the magnitude of the inward current. The axonal Ca2+ spikes are followed by a series of Ca2+-dependent afterpotentials: a rapid postspike hyperpolarization, a depolarizing afterpotential (DAP) and, finally, a long-lasting postburst hyperpolarization. The long-lasting hyperpolarization is not blocked by 50 mM external tetraethyl ammonium, an effective blocker of Ca2+-activated K+ current [IK(Ca)], and does not appear to reverse at EK. Hence, the axonal long-lasting hyperpolarization may not be due to IK(Ca). Somatic voltage-clamp pulses in bursting neurons are followed by a slow inward tail current, which is sometimes coincident with a DAP in the axon. In some cells, the amplitude of the slow inward tail current is greatly reduced if axonal spikes and DAPs are prevented by hyperpolarization of the axon, while, in other cells, elimination of axonal activity has little effect. Therefore, the slow inward tail current is not necessarily an artifact of poor voltage-clamp control over the axonal membrane potential but probably results from the activation of an ionic conductance mechanism located partly in the axon and partly in the soma.     

Impulse conduction in the jellyfish Aglantha digitale

In the jellyfish Aglantha digitale two forms of swimming arise from two separate propagating axonal impulses: a fast, overshooting action potential that depends on TTX-resistant Na⁺ channels, and a low-amplitude spike that depends on T-type Ca²⁺ channels. While the Na⁺ action potential is propagated simply and without distortion, the shape of the Ca²⁺ spike depends on the past history of the axon; it is processed as well as propagated. Patch- and voltage-clamp experiments show how three classes of K⁺ channels contribute to this apparently unique system. A dual Na⁺/Ca²⁺ impulse mechanism may increase the bandwidth of an axonal line of communication but it also places restrictions on the form of the synaptic input needed for spike initiation.     

Activation of inwardly rectifying potassium channels by muscarinic receptor-linked G protein in isolated human ventricular myocytes

Muscarinic receptor-linked G protein, G _i , can directely activate the specific K⁺ channel (I _K(ACh)) in the atrium and in pacemaker tissues in the heart. Coupling of G _i to the K⁺ channel in the ventricle has not been well defined. G protein regulation of K⁺ channels in isolated human ventricular myocytes was examined using the patch-clamp technique. Bath application of 1 μm acetylcholine (ACh) reversibly shortened the action potential duration to 74.4 ± 12.1% of control (at 90% repolarization, mean ±sd, n= 8) and increased the whole-cell membrane current conductance without prior β-adrenergic stimulation in human ventricular myocytes. The ACh effect was reversed by atropine (1 μm). In excised inside-out patch configurations, application of GTPγS (100 μm) to the bath solution (internal surface) caused activation of I _K(ACh) and/or the background inwardly-rectifying K⁺ channel (I _K1) in ventricular cell membranes. I _K(ACh) exhibited rapid gating behavior with a slope conductance of 44 ± 2 pS (n= 25) and a mean open lifetime of 1.8 ± 0.3 msec (n= 21). Single channel activity of GTPγS-activated I _K1 demonstrated long-lasting bursts with a slope conductance of 30 ± 2 pS (n= 16) and a mean open lifetime of 36.4 ± 4.1 msec (n= 12). Unlike I _K(ACh), G protein-activated I _K1 did not require GTP to maintain channel activity, suggesting that these two channels may be controlled by G proteins with different underlying mechanisms. The concentration of GTP at half-maximal channel activation was 0.22 μm in I _K(ACh) and 1.2 μm in I _K1. Myocytes pretreated with pertussis toxin (PTX) prevented GTP from activating these channels, indicating that muscarinic receptor-linked PTX-sensitive G protein, G _i , is essential for activation of both channels. G protein-activated channel characteristics from patients with terminal heart failure did not differ from those without heart failure or guinea pig. These results suggest that ACh can shorten the action potential by activating I _K(ACh) and I _K1 via muscarinic receptor-linked G _i proteins in human ventricular myocytes. Received: 23 September 1996/Revised: 18 December 1996     

Outward K+ channels in Brassica chinensis pollen protoplasts are regulated by external and internal pH

Summary.  Patch-clamp whole-cell and single-channel recording techniques were used to investigate the regulation of outward K⁺ channels by external and internal protons in Brassica chinensis pollen protoplasts. Outward K⁺ currents and conductance were insensitive to external pH (pH_o) except at pH 4.5. Maximal conductance (G _max) for the outward K⁺ currents was inhibited at acidic external pH. Half-activation voltage (E _1/2) for the outward K⁺ currents shifted to more positive voltages along with the decrease in pH_o. E _1/2 can be described by a modified Henderson–Hasselbalch equation expected from a single titratable binding site. The activation kinetics of the outward K⁺ channels was largely insensitive to pH_o. An internal pH (pH_i) of 4.5 significantly increased outward K⁺ currents and conductance. G _max for the outward K⁺ currents decreased with elevations in pH_i. In contrast to the effect of pH_o, E _1/2 was shifted to more positive voltages with elevations in pH_i. The outward K⁺ currents, G _max and E _1/2 can be described by the modified Henderson–Hasselbalch equation. Furthermore, acidifying pH_i accelerated the activation of the outward K⁺ currents significantly. The differences in electro-physiological properties among previously reported and currently described plant outward K⁺ channels may reflect differences in the structure of these channels. Received May 7, 2002; accepted July 9, 2002; published online November 29, 2002     

III. Ion Channel Expression in PMA-differentiated Human THP-1 Macrophages

Ion channel expression was studied in THP-1 human monocytic leukemia cells induced to differentiate into macrophage-like cells by exposure to the phorbol ester, phorbol 12-myristate 13-acetate (PMA). Inactivating delayed rectifier K⁺ currents, I _DR, present in almost all undifferentiated THP-1 monocytes, were absent from PMA-differentiated macrophages. Two K⁺ channels were observed in THP-1 cells only after differentiation into macrophages, an inwardly rectifying K⁺ channel (I _IR) and a Ca²⁺-activated maxi-K channel (I _BK). I _IR was a classical inward rectifier, conducting large inward currents negative to E _K and very small outward currents. I _IR was blocked in a voltage-dependent manner by Cs⁺, Na⁺, and Ba²⁺, block increasing with hyperpolarization. Block by Na⁺ and Ba²⁺ was time-dependent, whereas Cs⁺ block was too fast to resolve. Rb⁺ was sparingly permeant. In cell-attached patches with high [K⁺] in the pipette, the single I _IR channel conductance was ∼30 pS and no outward current could be detected. I _BK channels were observed in cell-attached or inside-out patches and in whole-cell configuration. In cell-attached patches the conductance was ∼200–250 pS and at potentials positive to ∼100 mV a negative slope conductance of the unitary current was observed, suggesting block by intracellular Na⁺. I _BK was activated at large positive potentials in cell-attached patches; in inside-out patches the voltage-activation relationship was shifted to more negative potentials by increased [Ca²⁺]. Macroscopic I _BK was blocked by external TEA⁺ with half block at 0.35 mm. THP-1 cells were found to contain mRNA for Kv1.3 and IRK1. Levels of mRNA coding for these K⁺ channels were studied by competitive PCR (polymerase chain reaction), and were found to change upon differentiation in the same direction as did channel expression: IRK1 mRNA increased at least 5-fold, and Kv1.3 mRNA decreased on average 7-fold. Possible functional correlates of the changes in ion channel expression during differentiation of THP-1 cells are discussed. Received: 19 September 1995/Revised: 14 March 1996     

Sharpness of Spike Initiation in Neurons Explained by Compartmentalization

In cortical neurons, spikes are initiated in the axon initial segment. Seen at the soma, they appear surprisingly sharp. A standard explanation is that the current coming from the axon becomes sharp as the spike is actively backpropagated to the soma. However, sharp initiation of spikes is also seen in the input–output properties of neurons, and not only in the somatic shape of spikes; for example, cortical neurons can transmit high frequency signals. An alternative hypothesis is that Na channels cooperate, but it is not currently supported by direct experimental evidence. I propose a simple explanation based on the compartmentalization of spike initiation. When Na channels are placed in the axon, the soma acts as a current sink for the Na current. I show that there is a critical distance to the soma above which an instability occurs, so that Na channels open abruptly rather than gradually as a function of somatic voltage.     

Kv 1.1 is associated with neuronal apoptosis and modulated by protein kinase C in the rat cerebellar granule cell

Previously, we reported that apoptosis of cerebellar granular neurons induced by low‐K⁺ and serum‐free (LK‐S) was associated with an increase in the A‐type K⁺ channel current (I_A), and an elevated expression of main α‐subunit of the I_A channel, which is known as Kv4.2 and Kv4.3. Here, we show, as assessed by quantitative RT‐PCR and whole‐cell recording, that besides Kv4.2 and Kv4.3, Kv1.1 is very important for I_A channel. The expression of Kv1.1 was elevated in the apoptotic neurons, while silencing Kv1.1 expression by siRNA reduced the I_A amplitude of the apoptotic neuron, and increased neuron viability. Inhibiting Kv1.1 current by dendrotoxin‐K evoked a similar effect of reduction of I_A amplitude and protection of neurons. Applying a protein kinase C (PKC) activator, phorbol ester acetate A (PMA) mimicked the LK‐S‐induced neuronal apoptotic effect, enhanced the I_A amplitude and reduced the granule cell viability. The PKC inhibitor, bisindolylmaleimide I and Gö6976 protected the cell against apoptosis induced by LK‐S. After silencing the Kv1.1 gene, the effect of PMA on the residual K⁺ current was reduced significantly. Quantitative RT‐PCR and Western immunoblot techniques revealed that LK‐S treatment and PMA increased the level of the expression of Kv1.1, in contrast, bisindolylmaleimide I inhibited Kv1.1 expression. In addition, the activation of the PKC isoform was identified in apoptotic neurons. We thus conclude that in the rat cerebellar granule cell, the I_A channel associated with apoptotic neurons is encoded mainly by the Kv1.1 gene, and that the PKC pathway promotes neuronal apoptosis by a brief modulation of the I_A amplitude and a permanent increase in the levels of expression of the Kv1.1 α‐subunit.     

Computational Model of Touch Sensory Cells (T Cells) of the Leech: Role of the Afterhyperpolarization (AHP) in Activity-Dependent Conduction Failure

Bursts of spikes in T cells produce an AHP, which results from activation of a Na⁺/K⁺ pump and a Ca²⁺-dependent K⁺ current. Activity-dependent increases in the AHP are believed to induce conduction block of spikes in several regions of the neuron, which in turn, may decrease presynaptic invasion of spikes and thereby decrease transmitter release. To explore this possibility, we used the neurosimulator SNNAP to develop a multi-compartmental model of the T cell. The model incorporated empirical data that describe the geometry of the cell and activity-dependent changes of the AHP. Simulations indicated that at some branching points, activity-dependent increases of the AHP reduced the number of spikes transmitted from the minor receptive fields to the soma and beyond. More importantly, simulations also suggest that the AHP could modulate, under some circumstances, transmission from the soma to the synaptic terminals, suggesting that the AHP can regulate spike conduction within the presynaptic arborizations of the cell and could in principle contribute to the synaptic depression that is correlated with increases in the AHP.     

Modes of Initiation and Propagation of Spikes in the Branching Axons of Molluscan Central Neurons

A study has been made of Aplysia nerve cells, mainly in the pleural ganglia, in which the main axon divides into at least two branches in the neighbourhood of the soma. Conduction between these branches was investigated by intracellular recordings from the soma following antidromic stimulation via the nerves containing the axonal branches. It has been shown that transmission between separate branches need not involve discharge of the soma but only of the axonal region between the soma and the origin of the branches. In some cells, the spike may fail to invade the other axonal branch, whereas transmission in the opposite direction is readily achieved. Often spikes in none of the branches are transmitted to the others, unless facilitated. Indications about the geometry of the neuron in the vicinity of the soma may be obtained from the study of the relative size of the A spikes originated in different branches. These observations, together with the presence of different sizes of A spikes, produced by orthodromic stimulation, provide evidence that spikes initiated at separate axonal "trigger zones" of Aplysia neurons may be conducted selectively to the effectors or other neurons innervated by the particular branch.     

K+-Sensitive Gating of the K+ Outward Rectifier in Vicia Guard Cells

The effect of extracellular cation concentration and membrane voltage on the current carried by outward-rectifying K⁺ channels was examined in stomatal guard cells of Vicia faba L. Intact guard cells were impaled with double-barrelled microelectrodes and the K⁺ current was monitored under voltage clamp in 0.1–30 mm K⁺ and in equivalent concentrations of Rb⁺, Cs⁺ and Na⁺. From a conditioning voltage of −200 mV, clamp steps to voltages between −150 and +50 mV in 0.1 mm K⁺ activated current through outward-rectifying K⁺ channels (I _{K, out}) at the plasma membrane in a voltage-dependent fashion. Increasing [K⁺] _o shifted the voltage-sensitivity of I _{K, out} in parallel with the equilibrium potential for K⁺ across the membrane. A similar effect of [K⁺] _o was evident in the kinetics of I _{K, out} activation and deactivation, as well as the steady-state conductance- (g _K ⁻) voltage relations. Linear conductances, determined as a function of the conditioning voltage from instantaneous I-V curves, yielded voltages for half-maximal conductance near −130 mV in 0.1 mm K⁺, −80 mV in 1.0 mm K⁺, and −20 mV in 10 mm K⁺. Similar data were obtained with Rb⁺ and Cs⁺, but not with Na⁺, consistent with the relative efficacy of cation binding under equilibrium conditions (K⁺≥ Rb⁺ > Cs⁺ > > Na⁺). Changing Ca²⁺ or Mg²⁺ concentrations outside between 0.1 and 10 mm was without effect on the voltage-dependence of g _K or on I _{K, out} activation kinetics, although 10 mm [Ca²⁺] _o accelerated current deactivation at voltages negative of −75 mV. At any one voltage, increasing [K⁺] _o suppressed g _K completely, an action that showed significant cooperativity with a Hill coefficient of 2. The apparent affinity for K⁺ was sensitive to voltage, varying from 0.5 to 20 mm with clamp voltages near −100 to 0 mV, respectively. These, and additional data indicate that extracellular K⁺ acts as a ligand and alters the voltage-dependence of I _{K, out} gating; the results implicate K⁺-binding sites accessible from the external surface of the membrane, deep within the electrical field, but distinct from the channel pore; and they are consistent with a serial 4-state reaction-kinetic model for channel gating in which binding of two K⁺ ions outside affects the distribution between closed states of the channel. Received: 27 November 1996/Revised: 4 March 1997     

Characterization of whole-cell k<Superscript>+</Superscript> currents across the plasma membrane of pollen grain and tube protoplasts of <Emphasis Type="Italic">Lilium longiflorum</Emphasis>

Outward and inward currents, mainly carried by K⁺, were detected in protoplasts of pollen grains (PG) and pollen tubes (PT) of Lilium longiflorum Thunb. by using the whole-cell configuration of the patch-clamp technique. The outward K⁺ current (I_{K+ out}) was similar in both protoplast types, while the inward K⁺ current (I_{K+ in}) was higher in pollen tube protoplasts. In PT but not in PG protoplasts, inward K⁺ currents were already detectable at negative membrane voltages usually monitored in lily pollen. I_{K+ in} consisted of a slow and a fast current component, as revealed by fitting a sum of two exponential functions to the time-dependent current. The contribution of the fast component to the total inward current was higher in PT than in PG protoplasts, which was even more evident at acidic pH of the external medium. Therefore, based on the measured characteristics, the I_{K+ in} of PT protoplasts may contribute to the endogenous K⁺ currents surrounding a growing pollen tube. Abbreviations: BS, bath solution; BTP, bis-Tris-propane; MES, 2-N-morpholinoethane sulfonic acid; V_act, activation voltage; V_M, membrane voltage; E_rev, reversal potential; I_{K+ in}, inward K⁺ current; I_{K+ out}, outward K⁺ current; PG, pollen grain; PT, pollen tube; PM, pipette medium