Single K+ channel currents of anomalous rectification in cultured rat myotubes

Impact of ISK Voltage and Ca2+/Mg2+-Dependent Rectification on Cardiac Repolarization

Cardiac small conductance Ca²⁺-activated K⁺ (SK) channels are activated solely by Ca²⁺, but the SK current (I_SK) is inwardly rectified. However, the impact of inward rectification in shaping action potentials (APs) in ventricular cardiomyocytes under β-adrenergic stimulation or in disease states remains undefined. Two processes underlie this inward rectification: an intrinsic rectification caused by an electrostatic energy barrier from positively charged amino acids at the inner pore and a voltage-dependent Ca²⁺/Mg²⁺ block. Thus, Ca²⁺ has a biphasic effect on I_SK, activating at low [Ca²⁺] yet inhibiting I_SK at high [Ca²⁺]. We examined the effect of I_SK rectification on APs in rat cardiomyocytes by simultaneously recording whole-cell apamin-sensitive currents and Ca²⁺ transients during an AP waveform and developed a computer model of SK channels with rectification features. The typical profile of I_SK during AP clamp included an initial peak (mean 1.6 pA/pF) followed by decay to the point that submembrane [Ca²⁺] reached ∼10 μM. During the rest of the AP stimulus, I_SK either plateaued or gradually increased as the cell repolarized and submembrane [Ca²⁺] decreased further. We used a six-state gating model combined with intrinsic and Ca²⁺/Mg²⁺-dependent rectification to simulate I_SK and investigated the relative contributions of each type of rectification to AP shape. This SK channel model replicates key features of I_SK recording during AP clamp showing that intrinsic rectification limits I_SK at high V_m during the early and plateau phase of APs. Furthermore, the initial rise of Ca²⁺ transients activates, but higher [Ca²⁺] blocks SK channels, yielding a transient outward-like I_SK trajectory. During the decay phase of Ca²⁺, the Ca²⁺-dependent block is released, causing I_SK to rise again and contribute to repolarization. Therefore, I_SK is an important repolarizing current, and the rectification characteristics of an SK channel determine its impact on early, plateau, and repolarization phases of APs.

Human myoblast fusion requires expression of functional inward rectifier Kir2.1 channels

Myoblast fusion is essential to skeletal muscle development and repair. We have demonstrated previously that human myoblasts hyperpolarize, before fusion, through the sequential expression of two K+ channels: an ether-à-go-go and an inward rectifier. This hyperpolarization is a prerequisite for fusion, as it sets the resting membrane potential in a range at which Ca2+ can enter myoblasts and thereby trigger fusion via a window current through alpha1H T channels.

IS3 peptide-formed ion channels in rat skeletal muscle cell membranes

A 22-mer peptide, identical to the primary sequence of domain I segment 3 (IS3) of rat brain sodium channel I, was synthesized. With the patch clamp cell-attached technique, single channel currents could be recorded from the patches of cultured rat myotube membranes when the patches were held at hyperpolarized potentials and the electrode solution contained NaCl and 1 microM IS3, indicating that IS3 incorporated into the membranes and formed ion channels. The single channel conductances of IS3 channels were distributed heterogeneously, but mainly in the range of 10-25 pS. There was a tendency that the mean open time and open probability of IS3 channels increased and the mean close time decreased with the increasing of hyperpolarized membrane potentials. IS3 channels are highly selective for Na+ and Li+ but not for Cl- and K+, similar to the authentic Na+ channels.

Different sulfonylurea and ATP sensitivity characterizes the juvenile and the adult form of KATP channel complex of rat skeletal muscle

We have described here the changes of the biophysical and pharmacological properties of the sarcolemmal ATP-sensitive K+ channels (KATP) of rat skeletal muscle fibres, occurring from an early postnatal period (5 days) to adulthood (210 days). The age-dependent changes of the mean current of the KATP channel (channel activity) and the effects of the blockers, ATP and glybenclamide, were examined by using the patch-clamp technique. Measurements of the single channel conductance, open probability and channel density were also performed. Excision of cell-attached patches into an ATP-free solution dramatically increased the KATP channel activity; however, the intensity of this activity was age dependent. The relative activity was low at 5-6 days of postnatal life, increased to a plateau at 12-13 days, then declined toward adult values after 37 days. Two distinct types of the KATP channel complex could be distinguished. The early developmental period (5-6 days) was dominated by a KATP channel having a conductance of 66 pS, a high open probability of 0.602, and an IC50 for ATP and glybenclamide of 123.1 microM and 3.97 microM, respectively. This type of channel disappeared with maturation of the muscle to be replaced by the adult form of the KATP channel. The later developmental period (from 56 days) was dominated by a KATP channel having a 71 pS conductance, but a low open probability of 0.222. This adult channel was also 3.2 and 73.5 times more sensitive to ATP and glybenclamide, respectively. We have also observed that the sensitivity of the KATP channel to ATP and glybenclamide develops differently. Indeed, the greater increase in the sensitivity of the channel to ATP was observed between 5 and 12 days of age. Conversely, the greater enhancement of the sensitivity of the channel to glybenclamide occurred between 12 and 37 days. A further increase of this parameter was also observed between 37 and 56 days of age. The differential age-dependent acquisition of the sensitivity of KATP channels to ATP and glybenclamide poses the hypothesis that in rat skeletal muscle the ATP regulatory site and sulfonylurea site are located on different subunits of the KATP channel complex. The intense KATP channel activity recorded between 12 and 37 days of postnatal life sustains the high resting macroscopic K+ conductance characteristic of the early postnatal development.

Potassium inward rectifier and acetylcholine receptor channels in embryonic Xenopus muscle cells in culture

Embryonic muscle cells of the frog Xenopus laevis were isolated and grown in culture and single-channel recordings of potassium inward rectifier and acetylcholine (ACh) receptor currents were obtained from cell-attached membrane patches. Two classes of inward rectifier channels, which differed in conductance, were apparent. With 140 mM potassium chloride in the electrode, one channel class had a conductance of 28.8 +/- 3.4 pS (n = 21), and, much more infrequently, a smaller channel class with a conductance of 8.6 +/- 3.6 pS (n = 7) was recorded. Both channel classes had relatively long mean channel open times, which decreased with membrane hyperpolarization. The probability of finding a patch of membrane with an inward rectifier channel was high (66%) and many membrane patches contained more than one inward rectifier channel. The open state probability (with no applied potential) was high for both inward rectifier channel classes so that 70% of the time there was a channel open. Seventy-three percent of the membrane patches with ACh receptor channels (n = 11) also had at least one inward rectifier channel present when the patch electrode contained 0.1 mu M ACh. Inward rectifier channels were also found at 71% of the sites of high ACh receptor density (n = 14), which were identified with rhodamine-conjugated alpha-bungarotoxin. The results indicate that the density of inward rectifier channels in this embryonic skeletal muscle membrane was relatively high and includes sites of membrane that have synaptic specializations.

Primary structure and characterization of a small-conductance inwardly rectifying potassium channel from human hippocampus

We have isolated a human hippocampus cDNA that encodes an inwardly rectifying potassium channel, termed HIR (hippocampal inward rectifier), with strong rectification characteristics. Single-channel recordings indicate that the HIR channel has an unusually small conductance (13 pS), distinguishing HIR from other cloned inward rectifiers. RNA blot analyses show that HIR transcripts are present in heart, skeletal muscle, and several different brain regions, including the hippocampus.

An inwardly rectifying potassium channel in the basolateral membrane of sheep parotid secretory cells

Using whole-cell patch-clamp techniques, we demonstrate that sheep parotid secretory cells have both inwardly and outwardly rectifying currents. The outwardly rectifying current, which is blocked by 10 mmol/liter tetraethylammonium (TEA) applied extracellularly, is probably carried by the 250 pS Ca(2+)- and voltage-activated K+ (BK) channel which has been described in previous studies. In contrast, the inwardly rectifying current, which is also carried by K+ ions, is not sensitive to TEA. It is similar to the inwardly rectifying currents observed in many excitable tissues in that (i) its conductance is dependent on the square root of the extracellular K+, (ii) the voltage range over which it is activated is influenced by the extracellular K+ concentration and (iii) it is blocked by the addition of Cs+ ions (670 mumol/liter) to the bathing solution. Our previously published cell-attached patch studies have shown that the channel type most commonly observed in the basolateral membrane of unstimulated sheep parotid secretory cells is a K+ channel with a conductance of 30 pS and, in this study, we find that its conductance also depends on the square root of the extracellular K+ concentration. It thus seems likely that it carries the inwardly rectifying K+ current seen in the whole-cell studies.

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.

Extracellular cations modulate the ATP sensitivity of ATP-K+ channels in rat ventromedial hypothalamic neurons

ATP-sensitive K+ (ATP-K+) channels underlie the glucose-sensing nature of pancreatic beta-cells by way of their inhibition by intracellular ATP. Recently it has been proposed that ATP-K+ channels have a similar function in certain hypothalamic neurons that become excitable in raised concentrations of extracellular glucose. The aim of this study was to assess the ATP sensitivity of ATP-K+ channels in inside-out membrane patches excised from glucose-sensing neurons that were acutely isolated from the ventromedial nucleus of rat hypothalamus. ATP-K+ channels were less sensitive to ATP in neurons than in other tissues. Moreover, the sensitivity of neuronal ATP-K+ channels to inhibition by intracellular ATP was modulated by extracellular cations. Under physiological ionic gradients (i.e. high extracellular Na+ and low K+), intracellular ATP produced a concentration-dependent inhibition of channel activity, with a half-maximal inhibition (Ki) of 2.32 mM. A non-hydrolysable analogue of ATP, AMP(PNP), was similarly effective. In symmetrical K+ (i.e. no extracellular sodium), channel activity was tenfold more sensitive to ATP (Ki of 0.21 mM). A parallel study on ATP-K+ channels from an insulin-secreting beta-cell line (CRI-G1) showed that, in contrast to the neuronal data, extracellular cations had no effect on the ATP sensitivity of the channel.

Angiotensin II, vasopressin and GTP[gamma-S] inhibit inward-rectifying K+ channels in porcine cerebral capillary endothelial cells

Cerebral capillaries from porcine brain were isolated, and endothelial cells were grown in primary culture. The whole-cell tight seal patch-clamp method was applied to freshly isolated single endothelial cells, and cells which were held in culture up to one week. With high K+ solution in the patch pipette and in the bath we observed inward-rectifying K+ currents, showing a time-dependent decay in part of the experiments. Ba2+ (1-10 mM) in the bath blocked this current, whereas outside tetraethylammonium (10 mM) decreased the peak current but increased the steady-state current. Addition of 1 microM of angiotensin II or of arginine-vasopressin to the extracellular side caused a time-dependent inhibition of the inward-rectifying K+ current in part of the experiments. Addition of 100 microM GTP[gamma-S] to the patch pipette blocked the K+ inward rectifier. In cell-attached membrane patches two types of single inward-rectifying K+ channels were observed, with single channel conductances of 7 and 35 pS. Cell-attached patches were also obtained at the antiluminal membrane of intact isolated cerebral capillaries. Only one type of K+ channel with g = 30 pS was recorded. In conclusion, inwardly rectifying K+ channels, which can be inhibited by extracellular angiotensin II and arginine-vasopressin, are present in cerebral capillary endothelial cells. The inhibition of this K+ conductance by GTP[gamma-S] indicates that G-proteins are involved in channel regulation. It is suggested that angiotensin II and vasopressin regulate K+ transport across the blood-brain barrier, mediating their effects via G-proteins.

Postnatal induction and neural regulation of inward rectifiers in mouse skeletal muscle

The whole-cell voltage-clamp technique was used to examine developmental changes of inward rectifier currents in fibres of the flexor digitorum brevis muscle acutely isolated from mice on postnatal day 0 (P0) to P36. Neither a steady-state component (Is-s) nor a slowly activated component (Irise) of inward rectifier currents were observed in fibres of P0 and P4 mice. Both Is-s and Irise became apparent between days P8 and P16. The specific amplitudes of Is-s and Irise measured at a test-pulse potential of -100 mV at 20 mM extracellular K+ [( K+]o) increased to their respective platcau values of -68 +/- 10 and -15 +/- 7 microA/cm2 at P20. In fibres denervated on day P4 the developmental increase of Is-s was suppressed, its specific amplitude at P20 being one-tenth of that in the corresponding normal fibres. Irise did not appear in P4-denervated fibres throughout the development. In muscle fibres denervated at P16 or P20, the specific amplitudes of Is-s and Irise decreased, reaching the levels of P4-denervated fibres in 2-4 days after denervation. We conclude that Is-s and Irise develop within 3 weeks after birth, and suggest that innervation plays a key role in their induction.

Macrophage-colony-stimulating factor (CSF-1) modulates a differentiation-specific inward-rectifying potassium current in human leukemic (HL-60) cells

A voltage-activated inward-rectifying K+ conductance (lKi) appears in human promyelocytic leukemia (HL-60) cells during phorbol ester-induced differentiation into macrophages. This conductance was detected in the cells 24 hours after exposure to phorbol-12-myristate-13-acetate (PMA), as the cells began to express the macrophage phenotype, and continued to increase for 4 days after PMA exposure. The magnitude of inward current was a function of external K+; current was blocked by extracellular or intracellular Cs+ and by extracellular Ba++. Hyperpolarization produced activation at membrane potentials more negative than -80 mV, and a slower, partial inactivation also occurred at potentials more negative than -100 mV. This conductance was not detected in proliferating cells nor in granulocytes derived from HL-60 cells which were induced to differentiate with retinoic acid (RA). Exposure of differentiated macrophages to recombinant human CSF-1 produced inhibition of the lKi beginning within 1 minute after exposure. CSF-1 inhibition of lKi channels in cell-attached patches indicated that channel modulation was via intracellular mediators. The rapid inhibition of the inward rectifier by the macrophage-specific CSF-1 appears to be one of the earliest cellular responses to this factor.

Single inwardly rectifying potassium channels in cultured muscle cells from rat and mouse

1. Inward unitary currents through inwardly rectifying K+ channels of myotubes derived from newborn rats or from a murine, clonal myoblast cell line were studied in the cell-attached configuration. Open-closed transitions of the channel were observed in the absence of blocking ions. 2. The single-channel conductance was 26.3 +/- 2.9 pS (mean + S.D., n = 14) with 150 mM-K+ pipette solution at room temperature (19-22 degrees C). The channel showed substates of conductance in addition to the main conductance state. A channel with a smaller conductance (8.9 +/- 2.6 pS, n = 4) was also but less frequently observed. 3. The probability of the channel being open is weakly voltage dependent: it decreased from 0.94 to 0.84 as the membrane was hyperpolarized from the resting potential (RP) + 20 mV to RP - 50 mV. 4. The lifetimes of the openings were distributed according to a single exponential. At least three exponentials were required to fit the frequency histogram of the lifetimes of all closed states. The mean open time showed a weak voltage dependence, while the mean closed times had little voltage dependence. 5. In the presence of external Na+, the open probability decreased from 0.89 to 0.43 and the mean open time decreased from 203 to 28 ms (40 mM-K+, 200 mM-Na+ pipette solution) when the patch membrane was hyperpolarized from RP - 40 mV to RP - 110 mV. The mean closed times were not different from those with 150 mM-K+, Na+-free pipette solution and showed little voltage dependence. 6. It is suggested that inactivation of the macroscopic inward currents during hyperpolarization results mainly from a voltage-dependent block by Na+ with relatively slow kinetics.

Anion and cation channels in the basolateral membrane of rabbit parietal cells

Ion channels in the basolateral membrane of rabbit parietal cells in isolated gastric glands were studied by the patch clamp technique. Whole-cell current-clamp recordings showed that the membrane potential (Em) changed systematically as a function of the chloride concentrations of the basolateral bathing solution ([Cl-]0), and of the pipette (intracellular) solution. The relationship between Em and [Cl-]0 was not affected by additions of histamine, dibutyryl-cAMP, 4-acetoamido-4'-isothiocyanostilbene-2,2'-disulfonic acid and diphenylamine-2-carboxylate. The whole-cell Cl- conductance was insensitive to voltage. In cell-attached and cell-free patch membranes, however, single Cl- channel opening events could not be observed. The value of Em depended little on the basolateral K+ concentration, but inward-rectifier K+ currents were observed in the whole-cell configuration, activated by hyperpolarizing pulses and inhibited by extracellular Ba2+. In cell-attached and cell-free patches, openings of single inward-rectifier K+ channels and non-selective cation channels were infrequently recorded. Neither cAMP nor Ca2+ activated these cation channels. The single K+ channel conductance was about 230 pS under the symmetrical high K+ conditions and was inhibited by intracellular tetraethylammonium ions (TEA). The non-selective cation channel had a voltage-independent single conductance of 22 pS and was not inhibited by TEA.

Internal and external K+ help gate the inward rectifier

Recent investigations have demonstrated substantial reductions in internal [K+] in cardiac Purkinje fibers during myocardial ischemia (Dresdner, K.P., R.P. Kline, and A.L. Wit. 1987, Circ. Res. 60: 122-132). We investigated the possible role these changes in internal K+ might play in abnormal electrical activity by studying the effects of both internal and external [K+] on the gating of the inward rectifier iK1 in isolated Purkinje myocytes with the whole-cell patch-clamp technique. Increasing external [K+] had similar effects on the inward rectifier in the Purkinje myocyte as it does in other preparations: increasing peak conductance and shifting the activation curve in parallel with the potassium reversal potential. A reduction in pipette [K+] from 145 to 25 mM, however, had several dramatic previously unreported effects. It decreased the rate of activation of iK1 at a given voltage by several-fold, reversed the voltage dependence of recovery from deactivation, so that the deactivation rate decreased with depolarization, and caused a positive shift in the midpoint of the activation curve of iK1 that was severalfold smaller than the associated shift of reversal potential. These changes suggest an important role of internal K+ in gating iK1 and may contribute to changes in the electrical properties of the myocardium that occur during ischemia.

Saturation effects and rectifier properties of sodium channels in human skeletal muscle

Sodium outward currents were measured in human myoballs with the whole-cell recording method. The electro-chemical gradient of the sodium ions across the cell membrane was modified over a wide range by variations of the clamped membrane potential and of the internal and external sodium concentration. Up to 50 mV positive to the sodium equilibrium potential, ENa, the current-voltage relation is linear. At a potential 80 mV positive to ENa the sodium outward current has a maximum and decreases with a further increase in electrochemical gradient. Investigating the instantaneous current change in experiments in which the membrane potential was changed while the channels were already open we could exclude the possibility that the gates of activation or inactivation are responsible for this effect. Therefore we postulate that the sodium channel has a valve-like mechanism producing a negative slope conductance at highly positive membrane potentials, a current saturation with self-inhibition by the intracellular sodium concentration, and a blockade of the channel on reduction of the extracellular sodium concentration.

An emerging pharmacology of peptide toxins targeted against potassium channels

Voltage-dependent ion channels are a difficult class of proteins to approach biochemically. Many such channels are present at low density in relevant tissues and exist as multiple subtypes that can be distinguished electrophysiologically. In particular, K channels appear to be a diverse family of proteins characterized by many different conductance properties, gating behaviors and regulatory phenomena. Fortunately, specific peptide toxins for K channels are present in the venoms of insects, scorpions, snakes and possibly other species. The available sequences of these peptides define several different families of toxins. Electrophysiological and radioligand binding studies suggest that these toxins can be used to distinguish subclasses of K channels that share similar toxin binding sites. The growing databank of sequence homologies for both toxins and channels is, in essence, a codebook for identifying common elements of structure and function. The continuing development of toxins as biochemical probes should help to uncover the molecular basis and physiological significance of K-channel diversity.

Single-channel activity in sarcolemmal vesicles from human and other mammalian muscles

Segments of mammalian, including human, skeletal muscle 1-2 cm long can be induced to shed vesicles by treatment with collagenase in a high-KCl solution containing no added calcium. The vesicles are encompassed by clean sarcolemma so that the gigaseal necessary for patch-clamping is readily formed. The properties of inwardly rectifying potassium channels and of calcium-activated potassium channels in patches detached from such vesicles are shown to be consistent with expectations based on earlier studies on intact muscle fibers and with patch clamp results on the same type of channels in other tissues. A chloride channel which rectifies outwardly with a conductance ranging from 15 to 50 pS is also described. The utility of sarcolemmal vesicles for the study of ion channels in human biopsy material is discussed.

Inwardly rectifying whole-cell and single-channel K currents in the murine macrophage cell line J774.1

Inward currents in the murine macrophage-like cell line J774.1 were studied using the whole-cell and cell-attached variations of the patch-clamp technique. When cells were bathed in Na Hanks' (KCl = 4.5 mM, NaCl = 145 mM), and the electrode contained Na-free K Hanks' (KCl = 145 mM) single-channel currents were observed at potentials below -40 mV which showed inward rectification, were K-selective, and were blocked by 2.5 mM Ba in the pipette. Single-channel conductance was 29 pS, and was proportional to the square root of [K]o. Channels manifested complex kinetics, with multiple open and closed states. The steady-state open probability of the channel was voltage dependent, and declined from 0.9 to 0.45 between -40 and -140 mV. When hyperpolarizing voltage pulses were repetitively applied in the cell-attached patch mode, averaged single-channel currents showed inactivation. Inactivation of inwardly rectifying whole-cell current was measured in Na Hanks' and in two types of Na-free Hanks': one with a normal K concentration (4.5 mM) and the other containing 145 mM K. Inactivation was shown to have Na-dependent and Na-independent components. Properties of single-channel current were found to be sufficient to account for the behavior of the macroscopic current, except that single-channel current showed a greater degree of Na-independent inactivation than whole-cell current.

Open-state substructure of inwardly rectifying potassium channels revealed by magnesium block in guinea-pig heart cells

1. Outward single-channel currents through inwardly rectifying K+ channels of cardiac myocytes were studied in the open cell-attached configuration to clarify the mechanism of the rectification. The outward currents, which were not recorded in the cell-attached configuration, appeared after the inner surface of the patch was exposed to low-Mg2+ solution by rupturing a part of the cell membrane. 2. The single-channel current-voltage (I-V) relation was linear in the absence of Mg2+ and crossed the voltage axis near the equilibrium potential for K+ (EK). The channel conductance was 22 and 16 pS (15-16 degrees C) at external K+ concentrations of 150 and 40 mM, respectively. 3. The channel rapidly closed on stepping the membrane potential of the patch to values more positive than EK. Decay of the average current during depolarization was fitted with a single-exponential function. The time constant appeared voltage dependent, but also tended to increase slowly with time after opening the cell to the bath solution. 4. Mg2+ on the cytoplasmic side blocked the outward currents without affecting the inward currents. The half-saturation concentration of the Mg2+ block was 1.7 microM as examined by measuring the mean patch current at +70 mV. 5. In the presence of internal Mg2+ at a micromolar level (2-10 microM), the outward single-channel current fluctuated between four levels including two intermediate levels (sublevels) in addition to the fully open channel current and the zero-current levels. The I-V relations of each sublevel were equally spaced with an interval of about 7 pS. Corresponding sublevels were found spontaneously in the inward direction. 6. Occupancy at each level was estimated from reconstructed traces at various Mg2+ concentrations and voltages, and compared with the value predicted from the binomial theorem. At different probabilities for the blocked state, the distribution of the current levels showed reasonable agreement with the binomial theorem. These findings suggest that the inwardly rectifying K+ channel of cardiac cells is composed of three identical conducting subunits and each subunit is blocked by Mg2+ independently. 7. Dwell times in each substate were distributed exponentially. On the assumption of the above model, the blocking (mu) and unblocking (lambda) rates were calculated. The value of mu increased with higher Mg2+ concentrations or larger depolarizations, while lambda ranged between 50 and 90 s-1 and seemed independent of Mg2+. 8. Owing to the voltage-dependent block by Mg2+, the average current decayed exponentially on depolarization beyond EK.(ABSTRACT TRUNCATED AT 400 WORDS)

Single-channel recordings from cultured human retinal pigment epithelial cells

We have applied patch-clamp techniques to on-cell and excised-membrane patches from human retinal pigment epithelial cells in tissue culture. Single-channel currents from at least four ion channel types were observed: three or more potassium-selective channels with single-channel slope conductances near 100, 45, and 25 pS as measured in on-cell patches with physiological saline in the pipette, and a relatively nonselective channel with subconductance states, which has a main-state conductance of approximately 300 pS at physiological ion concentrations. The permeability ratios, PK/PNa, measured in excised patches were 21 for the 100-pS channels, 3 for the 25-pS channels, and 0.8 for the 300-pS nonselective channel. The 45-pS channels appeared to be of at least two types, with PK/PNa's of approximately 41 for one type and 3 for the other. The potassium-selective channels were spontaneously active at all potentials examined. The average open time for these channels ranged from a few milliseconds to many tens of milliseconds. No consistent trend relating potassium-selective channel kinetics to membrane potential was apparent, which suggests that channel activity was not regulated by the membrane potential. In contrast to the potassium-selective channels, the activity of the nonselective channel was voltage dependent: the open probability of this channel declined to low values at large positive or negative membrane potentials and was maximal near zero. Single-channel conductances observed at several symmetrical KCl concentrations have been fitted with Michaelis-Menten curves in order to estimate maximum channel conductances and ion-binding constants for the different channel types. The channels we have recorded are probably responsible for the previously observed potassium permeability of the retinal pigment epithelium apical membrane.

Fractal analysis of a voltage-dependent potassium channel from cultured mouse hippocampal neurons

The kinetics of ion channels have been widely modeled as a Markov process. In these models it is assumed that the channel protein has a small number of discrete conformational states and the kinetic rate constants connecting these states are constant. In the alternative fractal model the spontaneous fluctuations of the channel protein at many different time scales are represented by a kinetic rate constant k = At1-D, where A is the kinetic setpoint and D the fractal dimension. Single-channel currents were recorded at 146 mM external K+ from an inwardly rectifying, 120 pS, K+ selective, voltage-sensitive channel in cultured mouse hippocampal neurons. The kinetics of these channels were found to be statistically self-similar at different time scales as predicted by the fractal model. The fractal dimensions were approximately 2 for the closed times and approximately 1 for the open times and did not depend on voltage. For both the open and closed times the logarithm of the kinetic setpoint was found to be proportional to the applied voltage, which indicates that the gating of this channel involves the net inward movement of approximately one negative charge when this channel opens. Thus, the open and closed times and the voltage dependence of the gating of this channel are well described by the fractal model.

Voltage-activated potassium, but not calcium currents in cultured bovine aortic endothelial cells

The electrophysiological properties of cultured bovine aortic endothelial cells were characterized using the patch clamp technique. Resting potentials were measured on passing to the whole cell recording configuration and were close to--65 mV in healthy cells. In cell-attached recordings with a high potassium pipette solution, inward single channel currents were observed with zero applied pipette potential. A linear slope conductance of 25 pS was found for a wide range of hyperpolarizing patch potentials and also for depolarizing patch potentials of up to 50-60 mV. A pronounced inward rectification was apparent as no reversal of these currents was seen for larger depolarizations. Whole cell recording in physiological solutions revealed the presence of a hyperpolarization-activated inward current with strong inward rectification and no voltage-dependent ionic current was observed upon depolarization in this subset of cells. Substitution of potassium for external sodium resulted in a shift in the zero current potential consistent with potassium being the main permeant ion. Together with the characteristic voltage-dependent blocking actions of external sodium ions and low concentrations of barium and caesium ions, our results indicate that this current is very similar to the classical inward rectifier as originally described in skeletal muscle and in tunicate eggs. In a second population of cells, a depolarization-activated outward current displaying characteristics of the fast transient A-type potassium current as first reported in molluscan neurones was also observed. No evidence for inward voltage dependent sodium or calcium currents was found.

Epinephrine activates outward rectifying K channel in Madin-Darby canine kidney cells

Patch-clamp recordings were used to study the epinephrine dependent activation of ion channels in the cell membrane of cultured subconfluent renal epithelial (MDCK) cells. The patch-current was dominated by two populations of K channels. The spontaneously active population of K channels shows an inward rectifying behavior. Addition of epinephrine to the cell exterior, after the patch-pipette had been sealed to the cell membrane, increased the open probability of the inward rectifying K channel and shifted the membrane potential in the hyperpolarizing direction. The epinephrine induced hyperpolarization occurs in the range of seconds and is caused by activation of outward-rectifying K channels. The outward-rectifying K channel could not be observed under control conditions. Epinephrine activated channels always appeared in clusters of four to nine channels. Both populations of K channels are modulated in their open probability by cytoplasmic free calcium and voltage.

Direct activation of mammalian atrial muscarinic potassium channels by GTP regulatory protein Gk

The mammalian heart rate is regulated by the vagus nerve, which acts via muscarinic acetylcholine receptors to cause hyperpolarization of atrial pacemaker cells. The hyperpolarization is produced by the opening of potassium channels and involves an intermediary guanosine triphosphate-binding regulatory (G) protein. Potassium channels in isolated, inside-out patches of membranes from atrial cells now are shown to be activated by a purified pertussis toxin-sensitive G protein of subunit composition alpha beta gamma, with an alpha subunit of 40,000 daltons. Thus, mammalian atrial muscarinic potassium channels are activated directly by a G protein, not indirectly through a cascade of intermediary events. The G protein regulating these channels is identified as a potent Gk; it is active at 0.2 to 1 pM. Thus, proteins other than enzymes can be under control of receptor coupling G proteins.

Increased numbers of ion channels promoted by an intracellular second messenger

The anomalous rectifier potassium current in Aplysia neurons was examined to determine the immediate cause of an increase in conductance induced by serotonin and mediated by adenosine 3',5'-monophosphate. Voltage-dependent cesium ion block and steady-state current power spectral density were measured under voltage clamp before and after application of serotonin. The amplitude of the anomalous rectifier conductance was increased by adding serotonin, but the shapes of the conductance-voltage curve and the power spectrum were not altered. Calculation of the number of functional channels and of the single-channel conductance from the power spectra indicates that the serotonin-induced increase in conductance resulted from an increase in the number of functional channels, while the single-channel conductance and the open-channel probability were unchanged.

Ionic channels: II. Voltage- and agonist-gated and agonist-modified channel properties and structure

This article reviews the different forms of ionic channels: voltage-gated, agonist-gated, and agonist- and second messenger-modified channels. The recent advances in our knowledge of the amino acid sequence of the sodium channel and the nicotinic acetylcholine receptor and the relationship of the primary structure to the channels' quarternary structure and function are discussed.

Voltage-dependent channels of human muscle cultures

Cultures were grown from satellite cells obtained from biopsies of normal children and of boys having Duchenne muscular dystrophy (DMD). Patch-clamp recordings were obtained from mononucleated cells and from young myotubes containing up to five nuclei. Four current types were distinguished. Na currents had a maximum amplitude near -10 mV and a half inactivation point near -60 mV. Single channel currents observed in isolated patches had a main unit size of 1.8 pA at -30 mV. Voltage dependent outward K currents were blocked by applying tetraethylammonium to the bath solution. In some cells, outward currents had a rather slow activation and did not inactivate. In other cells, activation was faster, and the currents inactivated. At large positive potentials, another K current was activated. The corresponding channels displayed large unit steps in isolated patches. Hyperpolarizing voltage pulses elicited in about one third of the cells inward rectifier currents. All currents types were found with similar characteristics in normal and DMD cultures. Whole cell results were very variable. Cells displayed various combinations of the four kinds of currents. To understand the origin of this diversity, clonal cultures were investigated. Clones displayed more homogeneous electrical properties than standard cultures, suggesting the presence of various types of stem cells in the non-clonal cultures.

Single-channel analysis of a potassium inward rectifier in myocytes of newborn rat heart

Unitary K+ currents in single cells isolated from ventricular muscle of newborn rat hearts were measured in response to different potentials and [K]o. The I/V curves were linear for potentials more negative than the zero-current voltage; especially in high [K]o (150 mM KCl), no clear outward currents could be detected indicating a drastic rectification in the inward direction. The channel is mainly selective to K+ but Na+ ions are also carried (PNa/PK = 0.056). The channel conductance is proportional to the square root of [K]o but Na+ ions seem to have a facilitatory effect on gamma K, the single-channel conductance. The channel activity, measured as Po, i.e. the probability to find the channel in open state, decreased as the membrane was hyperpolarized. This behavior was tentatively explained by an inactivation process as the membrane becomes more negative. The rate constants of the transitions between the different states were calculated according to a C-O-C model. A control of the gating process by permeant ion K+ was postulated, based on the increase of one of the rate constants from the closed to the open state with [K]o. Finally, the macroscopic I/V curves calculated from Po and delta i, the unit current, were found to be characteristic of a ion-blocked inward rectifier.

Properties of adenosine-triphosphate-regulated potassium channels in guinea-pig ventricular cells

A class of K channels in cardiac muscle is reversibly blocked by intracellular adenosine 5'-triphosphate (ATP). The characteristics of this K channel were studied by recording single-channel currents in ventricular cells isolated enzymatically from guinea-pig heart. The reversal potential of single-channel currents agreed well with the K equilibrium potential. Blockers of other K channels, such as tetraethylammonium and 4-aminopyridine, decreased the mean open time of the channel. The chord conductance increased as the 0.24th power of the K concentration on the outer surface of the membrane, and showed a marked inward-going rectification on strong depolarizations. The degree of rectification was larger with increasing Na concentration on the inner side of the membrane. The kinetics of the channel were almost voltage independent, but depended on the concentration of intracellular ATP. The conductance of the channel was not affected by ATP. When channel kinetics were examined in the presence of ATP, the distribution of open times and closed times was fitted well with a sum of two exponential components. When ATP concentration was increased, the time constants obtained from the open-time histogram decreased and those from the closed-time histogram increased, resulting in a decrease of the open-state probability. The channel was blocked by ATP, adenosine 5'-diphosphate,5'-adenylylimidodiphosphate, guanosine 5'-triphosphate and uridine 5'-triphosphate, but not by adenosine 5'-monophosphate, creatine phosphate, creatine or adenosine. Plots of the open-state probability versus the ATP concentration revealed Michaelis-Menten saturation kinetics with strong co-operativity of multiple receptor sites (Hill coefficient 3-4, concentration of half-saturation 0.5 mM). It was concluded that this K channel has three or four receptor sites selective for triphosphate nucleotide on the inner surface of the membrane, and that the channel is blocked through the binding of agonists to the receptors.

The mechanism of action of Ba2+ and TEA on single Ca2+-activated K+ -channels in arterial and intestinal smooth muscle cell membranes

The interaction of Ba2+ and TEA with Ca2+-activated K+ channels was studied in isolated membrane patches of cells from longitudinal jejunal smooth muscle of rabbit and from guinea-pig small mesenteric artery (100 micron external diameter). Ba2+ applied from the inside of the membrane did not reduce unit current, except at high concentrations, but channels failed to open for long periods (s). This effect became much stronger when the potential gradient was in a direction driving Ba2+ into the channel and was reduced by increasing K+ ion concentration on the outside of the membrane. These results are consistent with Ba2+ entering the open channel and blocking at a site most of the way through the channel bore. In contrast, TEA and procaine dose-dependently reduced unit current amplitude at all patch potentials and slightly increased mean open time. Their effects were not detectably voltage-dependent and could be explained by TEA and procaine blocking the open channel with a timecourse that was faster than the frequency response of the recording system. The lack of appreciable voltage-dependence suggests that TEA and procaine bind to a site near to the inner mouth of the channel.

Effects of L-glutamate on the anomalous rectifier potassium current in horizontal cells of Carassius auratus retina

The effects of externally applied L-glutamate (Glu) on K currents through the anomalous rectifier were studied in solitary horizontal cells dissociated from goldfish retinae under whole-cell voltage-clamp or cell-attached patch-clamp conditions using 'giga-seal' suction pipettes. In the whole-cell clamp experiments, hyperpolarization of the membrane below the resting potential (ca. -57 mV) induced a large voltage-dependent inward current which has been identified as the K current through the anomalous rectifier (Ianomal.). Application of Glu to the external medium reduced Ianomal.. Reduction of the inward current was not seen in preparations in which Ianomal. has been blocked by an application of Cs or Ba ions to the external medium. Single-channel currents through the anomalous rectifier were recorded under cell-attached patch-clamp conditions. The current showed an inward rectification; its amplitude increased with hyperpolarization of the patch membrane, and became below the noise level near the equilibrium potential of K ions (EK). No polarity reversal was observed even by a strong membrane depolarization. The patch membrane potential at which the current amplitude became undetectable shifted in parallel to the shift of EK. The open probability changed little with polarization of the patch membrane. When Glu (greater than 100 microM) was applied to the outside of the patch membrane, the number of available Ianomal. channels was decreased, but neither the single-channel conductance, open or closed time constants, nor the open probability changed significantly. Removal of Glu produced the opposite sequence; i.e. the number of available Ianomal. channels increased with time. It was concluded that the reduction of the Glu-induced current at hyperpolarized potentials in the whole-cell recording configuration is due to the blocking action of Glu on Ianomal..

Ion channels in plasmalemma of wheat protoplasts

The patch-clamp technique was used to study passive movements of ions through the plasmalemma of wheat leaf protoplasts. This method overcomes the problems inherent in conventional electrophysiological study of plant cells. Changes in conductance were recorded in patches excised from the plasmalemma. Two types of patches were observed: (i) regions of low channel density, where discrete single-channel currents could be resolved and conductance ranged from 10 to 200 picosiemens and (ii) regions of high channel density, where single-channel currents could not be resolved and conductance was on the order of a few nanosiemens. The results indicate a striking similarity between animal and plant cell membranes in the basic phenomena of transport. Moreover, the approach used constitutes a new degree of refinement in the study of processes of regulation, pathology, and toxicity in plants.

Adenosine-5'-triphosphate-sensitive single potassium channel in the atrioventricular node cell of the rabbit heart

The patch-clamp method was applied to single atrioventricular (a.v.) node cells of the rabbit heart to study the characteristics of the K+ channel. When the electrode contained 5.4 mM-K+, depolarizations of the cell-attached patch membrane induced outward single channel currents characterized by burst-like openings; the open-state probability increased from 0.005-0.01 at -40 mV to 0.07-0.1 at +20 mV of membrane potential. The reversal potentials of the current at K+ concentrations of 5.4, 20 and 130 mM in the electrode agreed with those given by the Nernst equation, indicating that this channel is selective for K+ ions. The slope conductance of the channel decreased beyond 60-90 mV positive to the reversal potential (inward-going rectification). The conductance near the reversal potential increased with increasing K+ concentrations on either side of the membrane: from 31-32 pS at 5.4 mM-K+ to 41-42 pS at 20 mM-K+ on the outside, and from 19 pS at 90 mM-K+ to 29.3 pS at 130 mM-K+ on the inside. Superfusion of the cell with 5.4 mM-CN-, glucose-free Tyrode markedly increased the number of channel openings in the cell-attached patch. In the inside-out patch, application of 1 mM-adenosine-5'-triphosphate (ATP) at the inner surface of the patch membrane blocked reversibly the channel activity, while 1 mM-adenosine-5'-diphosphate (ADP) failed to block it. The conductance and kinetics of the channel were not modified by increasing the Ca2+ concentration from 10(-8) M to 5 X 10(-6) M on the inner side of the membrane, while a further increase in Ca2+ to 10(-4) M decreased the open-state probability. The probability density for the open time fitted well with an exponential distribution (time constant of 5.4 ms at 60 mV positive to the resting potential), while that for the closed time was separated into a fast and a slow component (time constants of 4.0 and 132.0 ms, respectively). The time constant of the slow component decreased significantly with depolarization in some preparations. However, neither the time constant of the fast component of the closed-time histogram nor that of the open-time histogram was voltage-dependent.

Studies of ionic currents in the isolated vestibular hair cell of the chick

The ionic currents in enzymatically isolated vestibular hair cells of the chick were studied by a whole-cell-clamp variation of the patch voltage clamp, and by single channel recording. At membrane potentials more negative than -80 mV the hair cell showed anomalous rectification, and at potentials more positive than -40 mV large outward K currents were observed in normal saline. The outward K current decreased at large positive potentials, showing an N-shaped I-V relation. The outward K current was carried mostly through the Ca-activated K channel. K currents through the anomalous rectifier channel showed a decay in normal saline. This decay was eliminated reversibly in Na-free saline when the isotonic KCl-EGTA solution was used as the internal medium. However, a fast decay was still observed in Na-free high-K external solution when isotonic CaCl-EGTA was used as the internal medium. An increase in [K]o decreased the decay rate of the inward K current. The single-channel conductance of the anomalous rectifier channel was 50 pS in 160 mM-K saline and 23 pS in 40 mM-K saline. In 100 mM-Ca, -Sr and -Ba salines a large inward current was observed. At positive potentials the inward current carried by Ca and Sr ions showed significant decay; the current became outward at large positive potentials. Since the decay of the inward current was eliminated when 100 microM-quinine was added to the bathing medium, it was probably due to the activation of some Ca-activated K conductance which remained even with isotonic CsCl-EGTA internal medium. The activation kinetics of the Ca channel were studied in 100 mM-Ba solution at low temperatures (9-13 degrees C). From a comparison of the time constants of activation with the time constants of the tail currents, it was concluded that the Ca channel follows Hodgkin-Huxley-type m2 kinetics. A slow component that deviated from m2 kinetics was frequently observed at relatively large positive potentials. The steady-state fluctuations of Ba current showed a power density spectrum reasonably well fitted by a sum of two Lorentzian functions. The spectrum has a low-frequency component which indicates kinetics close to the macroscopic activation process of the Ca channel and a high-frequency component that indicates very fast flickering kinetics operating in the Ca channel.

Steady state current noise from the intrinsic gating of inward rectifier channels

Steady-state current noise from the intrinsic gating of inward rectifier channels in the eggs of the marine polychaete Neanthes arenaceodentata was recorded under voltage clamp conditions. Lorentzian-shaped power spectra with corner frequencies near 1 Hz and zero-frequency asymptotes of 1 - 5 X 10(-23) A2/Hz were obtained for test potentials 15-45 mV positive to EK in solutions containing 10-40 mM Ko. The spectra are compatible with the predictions of a three-state kinetic model for inward rectification in which the single channel rectification is independent of voltage. The single channel conductance derived from this interpretation is 8 pS with 40 mM Ko.

Inward rectifier current noise in frog skeletal muscle

Inwardly rectifying K+ currents were studied in cut muscle fibres from frogs using the Vaseline-gap voltage-clamp method. Both faces of the membrane were exposed to 120 mM-K+ methylsulphate solution. At small negative potentials, -10 and -21 mV, the current noise spectrum, after subtraction of a control spectrum at the zero current potential, could be fitted by a Lorentzian spectral component, usually with an additional 1/f component, where f is the frequency. At more negative potentials the 1/f component predominated. The zero frequency amplitude of the Lorentzian averaged 2.6 X 10(-24) A2 Hz-1 at -10 mV and 4.6 X 10(-24) A2 Hz-1 at -21 mV, with a mean half-power frequency, fc, of 34 Hz and 45 Hz, respectively. The time constant of the K+ current activation upon hyperpolarization agrees with that calculated from fc, and the Lorentzian disappears upon replacement of external K+ by tetraethylammonium (TEA+) or Rb+. Thus, the Lorentzian component appears to be ascribable to fluctuations originating in the inwardly rectifying mechanism. The noise spectra and macroscopic currents were interpreted by assuming that the inwardly rectifying K+ conductance is proportional to the product of two parameters: ps representing the state of the mechanism that gives rise to the observable macroscopic current relaxations and to the current fluctuations resulting in the observed Lorentzian spectra, and pf describing the instantaneous rectification of the single-channel conductance. Alternatively, pf may represent another mechanism in series with ps, but which fluctuates too rapidly to measure. Using this model the limiting single-channel conductance, gamma, was found to be approximately 9 pS. The corresponding specific density of channels is about 1 micron-2, assuming uniform distribution over all regions of the membrane. A preliminary value for gamma ( DeCoursey & Hutter , 1982) was derived without consideration of instantaneous rectification. Systematic errors in these results due to voltage decrement in the T-tubules are evaluated in an Appendix, and are found to be tolerably small in the voltage range studied.

Some properties of single potassium channels in cultured oligodendrocytes

K+ channels were studied in oligodendrocytes in cultures of mouse spinal cord. Single channel currents were measured using the gigaseal technique. The conductance of the channels varied greatly i.e. from 6 to 125 pS (38 +/- 28 SD, N = 21). In some patches there were up to three current levels of the same size. At -70 mV the open state probability was 0.51 +/- 0.17 and the average duration of an opening 70 +/- 20 ms for 4 channels with conductance from 16-57 pS. These analyses exclude brief flickering (less than 2 ms) or long closed periods (seconds to minutes). These times were not markedly affected by pulling the patch off the cell or by superfusing the isolated patch with media containing 10 mmol X 1(-1) TEA or EGTA without Ca2+. At membrane potentials between -90 and -30 mV there was a small but consistent effect of depolarization to increase the open state probability. Large positive or negative voltage steps decreased the open state probability. Current voltage measurements on intact cells showed a striking decrease in membrane conductance at these large membrane potentials. The leakage conductance of the patch also exhibited some K+ selectivity. The oligodendrocyte membrane appears to contain about one K+ channel per 5 micron 2. The known electrical properties of cultured oligodendrocytes can essentially be explained by the distribution and properties of these K+ channels.

Conductance properties of single inwardly rectifying potassium channels in ventricular cells from guinea-pig heart

Single ventricular cells were enzymatically isolated from adult guinea-pig hearts (Isenberg & Klöckner, 1982). The patch-clamp technique (Hamill, Marty, Neher, Sakmann & Sigworth, 1981) was used to examine the conductance properties of an inward-rectifying K+ channel present in their sarcolemmal membrane. When the K+ concentration on the extracellular side of the patch was between 10.8 and 300 mM, inward current steps were observed at potentials more negative than the K+ equilibrium potential (EK). At more positive potentials no current steps were detectable, demonstrating the strong rectification of the channel. The zero-current potential extrapolated from the voltage dependence of the inward currents depends on the external K4 concentration [K+]o in a fashion expected for a predominantly K+-selective ion channel. It is shifted by 49 mV for a tenfold change in [K+]o. The conductance of the channel depends on the square root of [K+]o. In approximately symmetrical transmembrane K+ concentrations (145 mM-external K+), the single-channel conductance is 27 pS (at 19-23 degrees C). In normal Tyrode solution (5.4 mM-external K+) we calculate a single-channel conductance of 3.6 pS. The size of inward current steps at a fixed negative membrane potential V increases with [K+]o. The relation between step size and [K+]o shows saturation. Assuming a Michaelis-Menten scheme for binding of permeating K+ to the channel, an apparent binding constant of 210 mM is calculated for a membrane potential of -100 mV. For this potential the current at saturating [K+]o is estimated as 6.5 pA. The rectification of the single-channel conductance at membrane potentials positive to EK occurs within 1.5 ms of stepping the membrane potential from a potential of high conductance to one of low conductance. In addition to the main conductance state, the channel can adopt several substates of conductance. The main state could be the result of the simultaneous opening of four conducting subunits, each of which has a conductance of about 7 pS in 145 mM-external K+. The density of the inward-rectifying K+ channels in the ventricular sarcolemma is 0-10 channel/10 micron2 of surface membrane; the average of twenty-eight patches was 1 channel/1.8 micron2. It is concluded that the inward-rectifying K+ channels mediate the resting K+ conductance of ventricular heart muscle and the current termed IK1 in conventional voltage-clamp experiments.

Drug-ionic channel interactions: single-channel measurements

Ionic channels of excitable membranes are the basic site where ionic fluxes take place during the generation of action potentials. A variety of natural toxins, chemicals, and therapeutic drugs have been found to modify the gating kinetics of the Na+ channels, thereby altering the excitation pattern. Studies of such chemical modulations of Na+ channel gating provide the basis for understanding the mechanisms underlying the epilepsies and the actions of anticonvulsant drugs. Certain chemicals and toxins have been found to drastically slow the kinetics of the opening and closing of the Na+ channel. For example, batrachotoxin, the grayanotoxins, and the pyrethroids modify a population of the Na+ channels to give rise to an extremely slow opening and closing. Patch clamp techniques developed during the past few years permit measurements of the opening and closing of individual ionic channels. When an isolated membrane patch is depolarized, squared inward currents of about 1 picoampere in amplitude and 2 ms in duration are observed at 10 degrees C. After exposure of the membrane to batrachotoxin, open time is prolonged, single-current amplitude is greatly reduced, and channel opening is observed at large negative potentials, where no opening is expected to occur in normal preparations. In the batrachotoxin-poisoned membrane there are two separate groups of Na+ channels: one exhibiting normal characteristics and the other exhibiting a prolonged opening and reduced amplitude.

Properties of an inward rectifying K channel in the membrane of guinea-pig atrial cardioballs

Single channel outward current fluctuations are recorded in excised (outside-out) membrane patches of isolated atrial cells in culture (cardioballs) from hearts of adult guinea-pigs. The ionic channel displays a high selectivity to K ions. Accordingly the reversal potential of the single channel current is close to the K equilibrium potential. The open channel conductance is unaffected by the membrane potential but depends on the K concentration of the outside solution (19.7pS at 2 mM Ko to 30.7pS at 20 mM Ko). The open state probability (Po) of the channel shows a marked voltage dependence. Po amounts to c.0.9 at -40 mV and decreases to c.0.1 at +40 mV. Under the assumption of no channel interaction a macroscopic steady state current voltage relationship is reconstructed from the single channel data. The relationship displays inward-going rectification. The rectification is due to the voltage dependence of Po. The I-V curve displays a negative slope at membrane potentials positive to -15 mV. In bathing solutions containing Ba ions (0.2 mM) Po is reduced by rapid closures which interrupt the open state events. The unit channel conductance is unaffected by Ba ions. The channel block exerted by Ba ions is augmented with increasing membrane hyperpolarization. The results suggest that the channel studied may represent a background K conductance.