Characteristics of two basolateral potassium channel populations in human colonic crypts.

The basolateral membrane of human colonic crypt cells contains Ca2+ and cAMP activated, Ba2+ blockable, low conductance (23 pS) K+ channels, which probably play an important part in intestinal Cl- secretion. This study has defined more clearly the basolateral K+ conductive properties of human colonic crypts using patch clamp recording techniques. High conductance (138 pS) K+ channels were seen in 25% of patches (one or two channels per patch), and significantly inhibited by the addition of 5 mM Ba2+, 1 mM quinidine or 20 mM tetraethylammonium chloride (TEA) to the cytosolic side of excised inside-out patches, whereas 1 mM diphenylamine-2-carboxylic acid (DPC) had no effect. In contrast, clusters of the 23 pS K+ channel (two to six channels per patch) were present in > 75% of patches, and channel activity was inhibited by quinidine and DPC, but not by TEA. Activity of the 138 pS K+ channel in inside-out patches was abolished almost completely by removal of bath Ca2+, but in contrast with its effect on the 23 pS K+ channel, addition of 0.1 mM carbachol had no effect on the 138 pS K+ channel in cell attached patches. It is concluded that human colonic crypt cells possess two discrete basolateral K+ channel populations, which can be distinguished by their responses to K+ channel blockers, and their different sensitivities to changes in intracellular Ca2+ concentration.     

Single-channel properties of the reconstituted voltage-regulated Na channel isolated from the electroplax of Electrophorus electricus.

The tetrodotoxin-binding protein purified from electroplax of Electrophorus electricus has been reincorporated into multilamellar vesicles that were used for patch recording. When excised patches of these reconstituted membranes were voltage clamped in the absence of neurotoxins, voltage-dependent single-channel currents were recorded. These displayed properties qualitatively and quantitatively similar to those reported for Na channels from nerve and muscle cells, including uniform single-channel conductances of the appropriate magnitude (approximately equal to 11 pS in 95 mM Na+), mean open times of approximately equal to 1.9 msec, and 7-fold selectively for Na+ over K+. Currents averaged from many depolarizations showed initial voltage-dependent activation and subsequent inactivation. In the presence of batrachotoxin, channels were observed with markedly different properties, including conductances of 20-25 pS (95 mM Na+), mean open times of approximately equal to 28 msec, and no indication of inactivation. Collectively, these findings indicate that the tetrodotoxin-binding protein of electroplax is a voltage-regulated sodium channel.     

Ca2+-activated synexin forms highly selective, voltage-gated Ca2+ channels in phosphatidylserine bilayer membranes.

Synexin, a cytosolic protein that mediates Ca2+-dependent membrane fusion, was incorporated into acidic phospholipid bilayers, formed at the tip of a patch pipet. The pipet was filled with a high-Ca2+ solution (50 mM) and immersed in a chamber containing a low-Ca2+ solution (1 mM). Brief exposures of the bilayer to synexin increased the capacitance of the bilayer by a factor of 10 and decreased the membrane resistance by a factor of 20. Reduction of Ca2+ in the chamber to 1 microM caused an abrupt increase in the current required to hold the pipet potential at 0 mV. Under certain conditions channel events could be detected, often occurring in bursts. Consistently, open-time histograms were found to be voltage-dependent and to exhibit one time constant in the time range examined here. The slope conductance for the synexin channel was estimated as 10.2 +/- 2.1 pS for the large Ca2+ gradient with low chamber Ca2+. However, for symmetrical, low-Cl- solutions containing 25 mM Ca2+ the conductance was 26.5 +/- 5.2 pS. Ion-replacement studies showed the synexin channel to much prefer Ca2+ over Ba2+ or Mg2+. Cd2+, a potent blocker of other voltage-gated Ca2+ channels at 100 microM, blocked synexin channels only at very high concentrations (greater than or equal to 10 mM). Similarly, nifedipine, an inhibitor of the nonactivating Ca2+ channel, was effective only at extremely high concentrations (greater than 300 microM). The high selectivity for Ca2+ and the lack of response of the channel to various drugs known to block Ca2+ channels thus distinguish the synexin channel from other types of Ca2+ channels hitherto reported.     

Modification of single Na+ channels by batrachotoxin.

The modifications in the properties of voltage-gated Na+ channels caused by batrachotoxin were studied by using the patch clamp method for measuring single channel currents from excised membranes of N1E-115 neuroblastoma cells. The toxin-modified open state of the Na+ channel has a decreased conductance in comparison to that of normal Na+ channels. The lifetime of the modified open state is drastically prolonged, and channels now continue to open during a maintained depolarization so that the probability of a channel being open becomes constant. Modified and normal open states of Na+ channels coexist in batrachotoxin-exposed membrane patches. Unlike the normal condition, Na+ channels exposed to batrachotoxin open spontaneously at large negative potentials. These spontaneous openings apparently cause the toxin-induced increase in Na+ permeability which, in turn, causes membrane depolarization.     

Purified skeletal muscle 1,4-dihydropyridine receptor forms phosphorylation-dependent oligomeric calcium channels in planar bilayers.

The purified 1,4-dihydropyridine receptor from skeletal muscle has been incorporated into planar bilayers, and its channel characteristics have been investigated. Conductances showed the characteristics of an L-type Ca2+ channel: divalent cation selectivity (PBa/PNa approximately equal to 30), blockage of Na+ conductance by micromolar Ca2+, and blockage of the Ca2+ channel by D890 and by Cd2+. The alpha 1 subunit of the receptor must be phosphorylated by the cAMP-dependent protein kinase to give channel activity. BAY K 8644 did not activate nonphosphorylated channels, and (+)-PN200-110 caused dramatic prolongation of mean open times when applied after phosphorylation. Channel properties were found to be dependent on association of receptor molecules in the bilayer. Single receptor molecules form channels of 0.9 pS (100 mM Ba2+) and show no voltage-dependent gating. Upon association, both voltage-dependent gating and higher conductance events are recovered; stabilized conductance levels assume values of even multiples of 0.9 pS, predominately 7.5 and 15 pS and multiples of these values up to 60 pS. Thus, individual channels become functionally coupled (synchronous opening and closing) with association, reinstating the characteristics of one larger unitary channel. It is concluded that the L-type Ca2+ channel represents an oligomer of 1,4-dihydropyridine-receptor protein complexes, each of which constitutes a channel, where the array of channels (oligochannel) opens and closes in concerted action.     

Patch clamp recordings of single ion channel activation by gonadotrophin-releasing hormone in ovine pituitary gonadotrophs

Gonadotrophs of the ovine pars tuberalis have been studied using the patch clamp technique for recording of single ion channel currents. We report that gonadotrophin-releasing hormone (GnRH) acts on these cells to open an inward-current cation channel which is permeable to Ca2+. When measured in cell-attached patches with 5 mM extracellular Ca2+, the GnRH-activated channel has a unit slope conductance of 8.0 +/- 2.6 pS (range 4-14 pS). The channel conductance is increased to 13.6 +/- 2.4 pS when the external medium contains 95 mM Ba2+ as the charge carrier. GnRH action appears to be mediated through an internal messenger system, since GnRH does not need to be in direct contact with these channels in order to cause their opening. This internal messenger system is unlikely to be Ca2+ itself. In addition, two other voltage-dependent outward-current channels have also been detected, both of which are permeable to K+, but differentiated in the cell-attached recording mode by widely different conductance values of 20-30 and 100-120 pS, respectively, and a reversal potential of -90 to -100 mV. The higher conductance channel is sensitive to internal Ca2+, and its probability of opening is increased in the presence of GnRH.     

Properties of a potassium channel in cultured human gastric cells (HGT-1) possessing specific omeprazole binding sites.

The HGT-1 human gastric cell line is similar to acid secreting parietal cells in that it possesses H2 receptors, histamine sensitive adenyl cyclase, and Cl- channels, which are activated by histamine by a cyclic adenosine monophosphate (cAMP) dependent mechanism. To discover if HGT-1 cells have additional properties found in parietal cells, [3H]omeprazole and patch clamp recording techniques were used to evaluate specific omeprazole binding sites and K+ channels in the plasma membrane. HGT-1 cells exhibited [3H]omeprazole binding in the non-stimulated state, which increased 100% in the presence of 1 mM histamine. High conductance (about 155 pS) K+ channels were active spontaneously in 17% of cell attached or excised inside out patches in non-stimulated subconfluent HGT-1 cells. In inside out patches, channel activity increased fivefold during depolarisation, ion substitution experiments confirmed that the channels were highly selective for K+, and channel activity was almost abolished by removal of Ca2+ or addition of 5 mM Ba2+. In quiescent cell attached patches, 0.1 mM dibutyryl cAMP failed to activate K+ channels. In contrast, 6.7 microM A23187 (a Ca2+ ionophore) increased intracellular Ca2+ concentration from mean (SEM) 14 (3) nM to 248 (30) nM and activated K+ channels in 21% of patches. It is concluded that the plasma membrane of HGT-1 cells possesses (a) specific 3H-omeprazole binding sites, which may reflect the omeprazole sensitive H+,K(+)-ATPase present in gastric parietal cells; and (b) Ca(2+)-activated K+ channels, which may be located in the basolateral membrane of human gastric parietal cells and play a part in acid secretion triggered by Ca(2+)-mediated secretory agonists.     

High molecular weight proteins purified from cardiac junctional sarcoplasmic reticulum vesicles are ryanodine-sensitive calcium channels

The cardiac high molecular weight proteins/ryanodine receptors were purified to homogeneity from junctional sarcoplasmic reticulum membranes and shown to exhibit large conductance calcium channel activity. High molecular weight proteins were solubilized from junctional sarcoplasmic reticulum in zwitterionic detergent and purified by size-exclusion chromatography followed by sucrose density gradient centrifugation. The purified proteins exhibited an apparent Mr = 400,000-350,000, and bound [3H]ryanodine with a Kd of 4.6 nM and a Bmax of 140-280 pmol/mg protein. High molecular weight proteins demonstrated divalent cation channel activity after incorporation into planar lipid bilayers. Two channel types were identified. Large conductance channels had a slope conductance of 96 +/- 13 pS and a Erev of 42 +/- 9 mV (n = 5); small conductance channels had a slope conductance of 5.5 +/- 1 pS [1.0 microM cis CaCl2; 50 mM trans Ba(OH)2]. Reducing cis calcium from 1 microM to 1 nM reduced the large conductance channel open time from 7 +/- 1% to 0.1% (holding potential, -100 mV). Adding ATP (1 mM) to the cis chamber increased channel open time from 6 +/- 1% to 52 +/- 4% (holding potential, -100 mV); 10 nM ryanodine increased and 100 microM ryanodine decreased percent of open time of the 96 pS channel, without altering unitary channel conductance. The large conductance channel was similar to the calcium release channel detected in native canine cardiac junctional sarcoplasmic reticulum vesicles. Our data suggest that the ryanodine receptor, the calcium-release channel, and the high molecular weight proteins are all identical proteins containing allosteric regulatory sites for calcium, ATP, and ryanodine.     

Single-channel events and gating behavior of the cardiac gap junction channel.

The activity of gap junction channels between pairs of neonatal rat heart cells in culture was studied under control conditions and during uncoupling procedures by using dual whole-cell voltage clamp techniques. Under control conditions gap junctional conductance ranged from 0.05 to 35 nS. In cell pairs exhibiting low gap junctional conductance (less than 500 pS), single-channel events with a unitary conductance of 53 +/- 2 pS (5 experiments; 186 events) were apparent. Event duration and open-time probability were estimated to be 0.95 sec and 0.17, respectively. When the junctional conductance in well-coupled cell pairs (with initial junctional conductance, greater than 5 nS) was reduced by cytoplasmic acidification or application of heptanol, single-channel events could be visualized. Compared to low-conductance controls, unitary channel conductance was unaltered (for acidification the conductance was 58 +/- 3 pS in 11 experiments with 253 events; for heptanol the conductance was 61 +/- 1 pS in 2 experiments with 171 events), while the probability of channels being open was decreased. The constancy of unitary channel conductance under control conditions and during uncoupling procedures suggests that opening and closing of the gap junction channel are all-or-none processes during which no stable subconductance states are formed.     

Single anion-selective channels in basolateral membrane of a mammalian tight epithelium.

Basolateral membrane chloride permeability of surface cells from rabbit urinary bladder epithelium was studied using the patch-clamp technique. Two types of anion-selective channel were observed. One channel type showed inward rectification and had a conductance of 64 pS at-50 mV when bathed symmetrically by saline solution containing 150 mM chloride; the other resembled high-conductance voltage-dependent anion channels (VDACs). Both channels had the selectivity sequence Cl-approximately equal to Br-approximately equal to I- approximately equal to SCN- approximately equal to NO3- greater than F- greater than acetate greater than gluconate greater than Na+ approximately equal to K+ and were sensitive to the anion exchange inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid. Basolateral chloride conductance in urinary bladder is apparently due to the 64 pS anion channel, which is active at physiological potentials. Imperfect selectivity of this channel against cations might also account for the low, but finite, sodium permeability of the basolateral membrane.     

Blocking and isolation of a calcium channel from neurons in mammals and cephalopods utilizing a toxin fraction (FTX) from funnel-web spider poison

A Ca2+-channel blocker derived from funnel-web spider toxin (FTX) has made it possible to define and study the ionic channels responsible for the Ca2+ conductance in mammalian Purkinje cell neurons and the preterminal in squid giant synapse. In cerebellar slices, FTX blocked Ca2+-dependent spikes in Purkinje cells, reduced the spike afterpotential hyperpolarization, and increased the Na+-dependent plateau potential. In the squid giant synapse, FTX blocked synaptic transmission without affecting the presynaptic action potential. Presynaptic voltage-clamp results show blockage of the inward Ca2+ current and of transmitter release. FTX was used to isolate channels from cerebellum and squid optic lobe. The isolated product was incorporated into black lipid membranes and was analyzed by using patch-clamp techniques. The channel from cerebellum exhibited a 10- to 12-pS conductance in 80 mM Ba2+ and 5-8 pS in 100 mM Ca2+ with voltage-dependent open probabilities and kinetics. High Ba2+ concentrations at the cytoplasmic side of the channel increased the average open time from 1 to 3 msec to more than 1 sec. A similar channel was also isolated from squid optic lobe. However, its conductance was higher in Ba2+, and the maximum opening probability was about half of that derived from cerebellar tissue and also was sensitive to high cytoplasmic Ba2+. Both channels were blocked by FTX, Cd2+, and Co2+ but were not blocked by omega-conotoxin or dihydropyridines. These results suggest that one of the main Ca2+ conductances in mammalian neurons and in the squid preterminal represents the activation of a previously undefined class of Ca2+ channel. We propose that it be termed the "P" channel, as it was first described in Purkinje cells.     

Voltage-activated calcium channels that must be phosphorylated to respond to membrane depolarization

Two classes of calcium channels were activated by membrane depolarization in cell-free membrane patches from GH3 cells, an electrically excitable cell line derived from a mammalian pituitary tumor. One class had a conductance of approximately 10 pS in 90 mM barium, had a threshold of activation near -40 mV, and was inactivated rapidly at holding potentials more positive than -80 mV. The other class, with a conductance of approximately 23 pS and a threshold nearer -20 mV, did not inactivate in barium but stopped responding to depolarization altogether when the cytoplasmic side of the patch was exposed to a standard physiological saline solution. Buffering the concentration of calcium ions to less than 10 nM on the cytoplasmic side did not prevent this loss of activity. However, activity was restored and maintained for the duration of the patch when the catalytic subunit of cAMP-dependent protein kinase was added with MgATP to the cytoplasmic side of the membrane. Cell-free patch formation in the presence of the dihydropyridine, BAY K 8644, also delayed the loss of activity, but unlike the catalytic subunit plus ATP, BAY K 8644 alone did not restore activity when it was added after the channels no longer responded to depolarization. Evidently the dihydropyridine-sensitive class of voltage-activated calcium channels must be phosphorylated in order to open when the membrane is depolarized. That hypothesis provides a simple framework for understanding the modulation of calcium channel gating by neurotransmitters, calcium ions, and dihydropyridines.     

Chloride channels in normal and cystic fibrosis human erythrocyte membrane

Electrophysiological studies on human RBCs have been difficult due to fragility and small size of cells, and little is known of ionic conductive pathways present in the RBC membrane in health and disease. We report on anionic channels in cells of healthy donors (control) and cystic fibrosis (CF) patients. Anion channel activity (8-12 pS, linear) was induced in cell-attached configuration by forskolin (50 microM) and in excised inside-out configuration by PKA (100 nM) and ATP (1 mM) but control and CF RBCs differed by their respective kinetics and gating properties. These channels were permeable to ATP (100 mM, symmetrical Tris-ATP). These data suggest either the existence of two different anionic channel types or regulation of a single channel type either by the CFTR (cystic fibrosis transmembrane regulator) protein or by different cytosolic factors. Another anionic channel type displaying outward rectification (approximately 80 pS, outward conductance) was present in 30% of CF cell patches but was not observed in normal cell patches. The frequently recorded activity of this channel in CF patches suggests a down-regulation in normal RBCs.     

On the mechanism of drug-induced blockade of Na+ currents: interaction of antiarrhythmic compounds with DPI-modified single cardiac Na+ channels

In patch-clamped membranes from neonatal rat cardiocytes, elementary Na+ currents were recorded at 19 degrees C for study of the inhibitory influence of several antiarrhythmic drugs including lidocaine, diprafenone, propafenone, and prajmalium on DPI-modified cardiac Na+ channels. Diprafenone (20 mumol/l) and lidocaine (300 mumol/l) induced a voltage- and time-dependent block of reconstructed macroscopic sodium current (INa). The drugs depressed the sustained, noninactivating INa component (which reflects the number and open probability of DPI-modified Na+ channels) effectively, in a voltage- and time-dependent fashion. Once opened, DPI-modified Na+ channels are highly drug-sensitive. Antiarrhythmic drugs (propafenone, diprafenone, and, to a lesser extent, lidocaine) provoke a flicker block, that is, the long-lasting openings are chopped into a large number of short and grouped openings. This indicates rapid transitions between a drug-associated, blocked state and a drug-free, conducting state. The latter has a unitary conductance of 12 pS, very similar to the control value in the absence of antiarrhythmic drugs. The decrease in open time of drug-treated DPI-modified Na+ channels is concentration-dependent. Hill coefficients for propafenone of about 1.0 and for prajmalium of about 0.7 were calculated. A blocking rate constant of 6.1 x 10(7) mol-1sec-1 for propafenone, but of 1.5 x 10(7) mol-1sec-1 for prajmalium was obtained at -30 mV. The unblocking rate constant for propafenone was, also at -30 mV, about twice as large as the unblocking rate constant for prajmalium. The open channel block kinetics are essentially voltage-dependent. The affinity of the channel-associated drug receptor increases on membrane depolarization. The blocking rate constant was inversely related to the number of Na+ ions moving through the open channel. It is concluded that the manifestation of this voltage- and Na+-dependent flicker block is intimately related to removal of fast Na+ inactivation.     

Single-channel recording in myelinated nerve fibers reveals one type of Na channel but different K channels.

Amphibian myelinated nerve fibers were treated with collagenase and protease. Axons with retraction of the myelin sheath were patch-clamped in the nodal and paranodal region. One type of Na channel was found. It has a single-channel conductance of 11 pS (15 degrees C) and is blocked by tetrodotoxin. Averaged events show the typical activation and inactivation kinetics of macroscopic Na current. Three potential-dependent K channels were identified (I, F, and S channel). The I channel, being the most frequent type, has a single-channel conductance of 23 pS (inward current, 105 mM K on both sides of the membrane), activates between -60 and -30 mV, deactivates with intermediate kinetics, and is sensitive to dendrotoxin. The F channel has a conductance of 30 pS, activates between -40 and 60 mV, and deactivates with fast kinetics. The former inactivates within tens of seconds; the latter inactivates within seconds. The third type, the S channel, has a conductance of 7 pS and deactivates slowly. All three channels can be blocked by external tetraethylammonium chloride. We suggest that these distinct K channel types form the basis for the different components of macroscopic K current described previously.     

L- and T-type Ca2+ channels in canine cardiac Purkinje cells. Single-channel demonstration of L-type Ca2+ window current.

Canine cardiac Purkinje cells contain both L- and T-type calcium currents, yet the single Ca2+ channels have not been characterized from these cells. Additionally, previous studies have shown an overlap between the steady-state inactivation and activations curves for L-type Ca2+ currents, suggesting the presence of L-type Ca2+ "window" current. We used the on-cell, patch-clamp technique to study Ca2+ channels from isolated cardiac Purkinje cells. Patches contained one or more Ca2+ channels 75% of the time. L-type channels were seen in 69% and T-type channels in 73% of these patches. With 110 mM Ba2+ as the charge carrier, the conductances of the L- and T-type Ca2+ channels were 24.2 +/- 0.8 pS (n = 9) and 9.0 +/- 0.5 pS (n = 8), respectively (mean +/- SEM). With 110 mM Ca2+ as the charge carrier, the conductance of the L-type Ca2+ channel decreased to 9.7 +/- 1.2 pS (n = 4), whereas the T-type Ca2+ channel conductance was unchanged. Voltage-dependent inactivation was shown for both L- and T-type Ca2+ channels, although for L-type Ca2+ channel with Ba2+ as the charge carrier, inactivation took at least 30 seconds at a potential of +40 mV. After channel inactivation was complete, L-type Ca2+ channel reopenings were observed following repolarizing steps into the window voltage range. Thus, our data identify both L- and T-type Ca2+ channels in cardiac Purkinje cells and demonstrate, at the single-channel level, L-type channel transitions expected for a window current. Window current may play an important role in shaping the action potential and in arrhythmogenesis.     

Giant multilevel cation channels formed by Alzheimer disease amyloid beta-protein [A beta P-(1-40)] in bilayer membranes.

We have recently shown that the Alzheimer disease 40-residue amyloid beta-protein [A beta P-(1-40)] can form cation-selective channels when incorporated into planar lipid bilayers by fusion of liposomes containing the peptide. Since A beta P-(1-40) comprises portions of the putative extracellular and membrane-spanning domains of the amyloid precursor protein (APP751), we suggested that the channel-forming property could be the underlying cause of amyloid neurotoxicity. The peptide has been proposed to occur in vivo in both membrane-bound and soluble forms, and we now report that soluble A beta P-(1-40) can also form similar channels in solvent-free lipid bilayers formed at the tip of a patch pipet, as well as in the planar lipid bilayer system. As in the case of liposome-mediated incorporation, the amyloid channel activity in the patch pipet exhibits multiple conductance levels between 40 and 400 pS, cation selectivity, and sensitivity to tromethamine (Tris). Further studies with A beta P channels incorporated into planar lipid bilayers from the liposome complex have also revealed that the channel activity can express spontaneous transitions to a much higher range of conductances between 400 and 4000 pS. Under these conditions, the amyloid channel continues to be cation selective. Amyloid channels were insensitive to nitrendipine at either conductance range. We calculate that if such channels were expressed in cells, the ensuing ion fluxes down their electrochemical potential gradients would be homeostatically dissipative. We therefore interpret these data as providing further support for the concept that cell death in Alzheimer disease may be due to amyloid ion-channel activity.     

Horizontal cell gap junctions: single-channel conductance and modulation by dopamine.

Horizontal cells form an electrically coupled network for the transmission of inhibitory signals in the outer retina. In teleosts, horizontal cell coupling is modulated by the neurotransmitter dopamine. Using voltage-clamped pairs of teleost horizontal cells, we have examined the effects of dopamine on the conductance and gating properties of the cell-to-cell channels that mediate electrical synaptic transmission. Variance analysis of the junctional current noise showed that dopamine substantially reduced the open probability of gap junction channels, from 0.75 to 0.14. Direct observation of unitary junctional gating events in poorly coupled cell pairs indicated that these channels have a unitary conductance of 50-60 pS. The elementary conductance of channels in cell pairs treated with dopamine (48.7 +/- 6.6 pS) was statistically indistinguishable from channels in untreated cells (53.2 +/- 7.2 pS). Uncoupling with octanol also yielded a similar unitary conductance (61.1 +/- 11.1 pS). Our results suggest that dopamine reduces the open probability of gap junctional channels by decreasing their open duration.     

Single sodium channels from human ventricular muscle in planar lipid bilayers

Sodium channels from human ventricular muscle membrane vesicles were incorporated into planar lipid bilayers and the steady-state behavior of single sodium channels were examined in the presence of batrachotoxin. In symmetrical 500 mM NaCl the averaged single channel conductance was 24.7 ± 1.3 pS and the channel fractional open time was 0.85 ± 0.04. The activation midpoint potential was −99.5 ± 3.1 mV. Extracellular tetrodotoxin blocked the channel with a κ_1/2 of 414 nM at 0 mV. In 7 out of 13 experiments subconductance states were observed (9.2 ± 1.2 pS). When sodium chloride concentration was lowered to 100 mM, single channel conductance decreased to 19.0 ± 0.9 pS, steady-state activation shifted by −17.3 ± 5.1 mV, tetrodotoxin sensitivity increased to 324 nM, and sub-conductance states were invariably observed in single channel records (7.9 ± 0.7 pS). In the planar lipid bilayer system the properties of cardiac sodium channels from different species are not very different, but there are significant differences between sodium channels from human heart and from human CNS. Received: 6 February 2001, Returned for revision: 28 February 2001, Revision received: 27 April 2001, Accepted: 2 May 2001