Single-channel Kinetics Research Articles

Interaction of charybdotoxin S10A with single maxi-K channels: kinetics of blockade depend on the presence of the beta 1 subunit.

The maxi-K channel from bovine aortic smooth muscle consists of a pore-forming alpha subunit and a regulatory beta1 subunit that modifies the biophysical and pharmacological properties of the alpha subunit. In the present study, we examine ChTX-S10A blocking kinetics of single maxi-K channels in planar lipid bilayers from smooth muscle or from tsA-201 cells transiently transfected with either alpha or alpha+beta 1 subunits. Under low external ionic strength conditions, maxi-K channels from smooth muscle showed ChTX-S10A block times, 48 +/- 12 s, that were similar to those expressing alpha+beta 1 subunits, 51 +/- 16 s. In contrast, with the alpha subunit alone, ChTX-S10A block times were much shorter, 5 +/- 0.6 s, and were qualitatively similar to previously reported values for the skeletal muscle maxi-K channel. Increasing the external ionic strength caused a decrease in ChTX-S10A block times for maxi-K channel complexes of alpha+beta 1 subunits but not of alpha subunits alone. These findings indicate that it may be possible to predict the association of beta 1 subunits with native maxi-K channels by monitoring the kinetics of ChTX blockade of single channels, and they suggest that maxi-K channels in skeletal muscle do not contain a beta 1 subunit like the one present in smooth muscle. To further test this hypothesis, we examined the binding and cross-linking properties of [(125)I]-IbTX-D19Y/Y36F to both bovine smooth muscle and rabbit skeletal muscle membranes. [(125)I]-IbTX-D19Y/Y36F binds to rabbit skeletal muscle membranes with the same affinity as it does to smooth muscle membranes. However, specific cross-linking of [(125)I]-IbTX-D19Y/Y36F was observed into the beta 1 subunit of smooth muscle but not in skeletal muscle. Taken together, these data suggest that studies of ChTX block of single maxi-K channels provide an approach for characterizing structural and functional features of the alpha/beta 1 interaction.

Dynorphins directly inhibit neuronal nicotinic acetylcholine receptors in PC12 cells.

The authors have previously reported that dynorphin A (1-17), an endogenous kappa opioid agonist, inhibits the current mediated through neuronal nicotinic acetylcholine receptors (nAChRs) without the involvement of opioid receptors or G-proteins. We have further characterized this action to elucidate the mechanisms. The nicotine-induced current was studied in PC12 cells using patch-clamp techniques. In the whole-cell configuration, four kinds of dynorphins with different lengths, dynorphin A (1-17) (1-13) (2-13) and (1-8), similarly inhibited the nicotine-induced inward current at 1 microM and accelerated the current decay. The inhibition by dynorphin A (1-17) was not antagonized by the increasing concentrations of nicotine. The current-voltage relationship revealed that dynorphin's inhibition was voltage independent at the membrane potentials from -30 to -70 mV. The inhibition was not affected by pretreatment with pertussis toxin (PTX) or inclusion of staurosporine into the pipette solution. The inhibitory effect of dynorphin A (1-17) was well preserved in the outside-out patch configuration. Analysis of the nicotine-induced noise and single-channel kinetics revealed that dynorphin A(1-17) reduced open time without changing the amplitude of the unitary current. We found that the inhibitory effect on neuronal nAChRs is shared by all four dynorphins studied. The inhibition appears to be non-competitive and voltage independent. The outside-out recording together with other experiments indicated that a major part of this inhibition is not mediated through cytoplasmic messengers, but based on the direct action of dynorphins on neuronal nAChRs leading to the reduction of open time.

Inhibition of αβ Epithelial Sodium Channels by External Protons Indicates That the Second Hydrophobic Domain Contains Structural Elements for Closing the Pore

We have examined the effect of extracellular protons on the activity of epithelial sodium channels (ENaCs). We found that αβ channels, but not αβγ or αγ channels, are inhibited by low extracellular pH. External protons induced short and long closed states that markedly decreased the open probability of αβ channels. External protons did not change the single-channel conductance or amiloride binding. Analysis of the proton-induced changes on the kinetics of single channels indicates that at least two protons sequentially bind to the extracellular domain at sites that are not in the ion pathway. Conformational changes induced by protonation of those sites are transmitted to the second hydrophobic domain (M2) of the subunits to induce closure of the pore. The results suggest that elements located in the carboxy-terminal half of M2 participate in the gating mechanism of ENaCs.

Cooperative Block of the Plant Endomembrane Ion Channel by Ruthenium Red

Effects of ruthenium red (RR) on the slow Ca 2+-activated Ca 2+-permeable vacuolar channel have been studied by patch-clamp technique. Applied to the cytosolic side of isolated membrane patches, RR at concentrations of 0.1–5 μM produced two distinct effects on single channel kinetics, long lasting closures and a flickering block of the open state. The first effect was largely irreversible, whereas the second one could be washed out. The extent of flickering block steeply increased ( zδ = ∼1.35) with the increase of cytosol-positive voltage, dragging RR into the channel pore. At least two RR ions are involved in the block according to Hill coefficient n = ∼1.30 for the dose response curves. The on-rate rate of the drug binding linearly depended on the RR concentration, implying that one RR ion already plugged the pore. The blocked state was further stabilized by binding of the second RR. This stabilization was in excess of that predicted by independent binding as the dependence of unblocking rate on RR concentration revealed. A cooperative model was therefore employed to describe the kinetic behavior of RR binding. At zero voltage the half-blocking RR concentration of 36 μM and the bimolecular on-rate constant of 1.8 × 10 8 M −1 s −1 were estimated.

Gating kinetics of single large-conductance Ca2+-activated K+ channels in high Ca2+ suggest a two-tiered allosteric gating mechanism.

The Ca2+-dependent gating mechanism of large-conductance calcium-activated K+ (BK) channels from cultured rat skeletal muscle was examined from low (4 microM) to high (1,024 microM) intracellular concentrations of calcium (Ca2+i) using single-channel recording. Open probability (Po) increased with increasing Ca2+i (K0. 5 11.2 +/- 0.3 microM at +30 mV, Hill coefficient of 3.5 +/- 0.3), reaching a maximum of approximately 0.97 for Ca2+i approximately 100 microM. Increasing Ca2+i further to 1,024 microM had little additional effect on either Po or the single-channel kinetics. The channels gated among at least three to four open and four to five closed states at high levels of Ca2+i (>100 microM), compared with three to four open and five to seven closed states at lower Ca2+i. The ability of kinetic schemes to account for the single-channel kinetics was examined with simultaneous maximum likelihood fitting of two-dimensional (2-D) dwell-time distributions obtained from low to high Ca2+i. Kinetic schemes drawn from the 10-state Monod-Wyman-Changeux model could not describe the dwell-time distributions from low to high Ca2+i. Kinetic schemes drawn from Eigen's general model for a ligand-activated tetrameric protein could approximate the dwell-time distributions but not the dependency (correlations) between adjacent intervals at high Ca2+i. However, models drawn from a general 50 state two-tiered scheme, in which there were 25 closed states on the upper tier and 25 open states on the lower tier, could approximate both the dwell-time distributions and the dependency from low to high Ca2+i. In the two-tiered model, the BK channel can open directly from each closed state, and a minimum of five open and five closed states are available for gating at any given Ca2+i. A model that assumed that the apparent Ca2+-binding steps can reach a maximum rate at high Ca2+i could also approximate the gating from low to high Ca2+i. The considered models can serve as working hypotheses for the gating of BK channels.

Modulation of the Nicotinic Acetylcholine Receptor by Dioscorine in Clonal Rat Phaeochlomocytoma (PC12) Cells

Dioscorine is a toxin isolated from the tubers of tropical yam, Dioscorea hispida Schlussel that has insecticidal and antifeedant activities. The effects of dioscorine on the neuronal nicotinic acetylcholine receptor in rat clonal phaeochlomocytoma (PC12) cells were studied using whole-cell and single-channel patch clamp techniques. Dioscorine at concentrations of 0.45–450 μMM accelerated the desensitization of current induced by 100 μMM acetylcholine and suppressed the current in a dose-dependent manner. Dioscorine itself did not induce any current at concentrations ranging from 0.45 to 450 μMM. At the single-channel level, 4.5–450 μMM dioscorine, when co-applied with 10 μMM acetylcholine, markedly shortened the open time and caused bursts to appear in a dose-dependent manner. The mean open time, mean closed time, and burst duration were decreased by dioscorine. These changes of single-channel kinetics result in a significant decrease in the total charge carried through the open channels, explaining the suppressive effect of dioscorine on acetylcholine-induced whole-cell currents. The suppressive effect of dioscorine on the acetylcholine-induced current is suggested to play an important role in the toxic actions in animals.

Regulation of type 1 inositol 1,4,5-trisphosphate-gated calcium channels by InsP3 and calcium: Simulation of single channel kinetics based on ligand binding and electrophysiological analysis.

Cytosolic calcium acts as both a coagonist and an inhibitor of the type 1 inositol 1,4,5-trisphosphate (InsP3)-gated Ca channel, resulting in a bell-shaped Ca dependence of channel activity (Bezprozvanny, I., J. Watras, and B.E. Ehrlich. 1991. Nature. 351:751-754; Finch, E.A., T.J. Turner, and S.M. Goldin. 1991. Science. 252: 443-446; Iino, M. 1990. J. Gen. Physiol. 95:1103-1122). The ability of Ca to inhibit channel activity, however, varies dramatically depending on InsP3 concentration (Combettes, L., Z. Hannaert-Merah, J.F. Coquil, C. Rousseau, M. Claret, S. Swillens, and P. Champeil. 1994. J. Biol. Chem. 269:17561-17571; Kaftan, E.J., B.E. Ehrlich, and J. Watras. 1997. J. Gen. Physiol. 110:529-538). In the present report, we have extended the characterization of the effect of cytosolic Ca on both InsP3 binding and InsP3-gated channel kinetics, and incorporated these data into a mathematical model capable of simulating channel kinetics. We found that cytosolic Ca increased the Kd of InsP3 binding approximately 3.5-fold, but did not influence the maximal number of binding sites. The ability of Ca to decrease InsP3 binding is consistent with the rightward shift in the bell-shaped Ca dependence of InsP3-gated Ca channel activity. High InsP3 concentrations are able to overcome the Ca-dependent inhibition of channel activity, apparently due to a low affinity InsP3 binding site (Kaftan, E.J., B.E. Ehrlich, and J. Watras. 1997. J. Gen. Physiol. 110:529-538). Constants from binding analyses and channel activity determinations were used to develop a mathematical model that fits the complex Ca-dependent regulation of the type 1 InsP3-gated Ca channel. This model accurately simulated both steady state data (channel open probability and InsP3 binding) and kinetic data (channel activity and open time distributions), and yielded testable predictions with regard to the regulation of this intracellular Ca channel. Information gained from these analyses, and our current molecular model of this Ca channel, will be important for understanding the basis and regulation of intracellular Ca waves and oscillations in intact cells.

Unitary current analysis of L-type Ca2+ channels in human fetal ventricular myocytes.

L-type calcium channels were studied in cell-attached patches from ventricular cell membranes of human fetal heart. Experiments were performed in the presence of 70 mM Ba2+ as the charge carrier at 22 degrees C to 24 degrees C. Unitary current sweeps were evoked by 300-msec depolarizing pulses to 0 mV from a holding potential of -50 mV at 0.5 Hz. Recorded currents were blocked by nisoldipine (1 microM) and stimulated by (-)Bay K 8644 (1 microM). During control, channel activity was seen in 13.9%+/-4.2% of the total 200 sweeps. Ensemble average current amplitude was 0.03+/-0.01 pA (n = 6) and average conductance was 20.4+/-0.2 pS (n = 5). Analysis of single channel kinetics showed open time and closed time histograms were best fit by one and two exponentials, respectively. Mean open time was tau(o) = 0.99+/-0.05 msec (n = 6). Mean closed time fast (tau(cf)) and slow (tau(cs)) component values were tau(cf) = 0.85+/-0.09 msec and tau(cs) = 8.0+/-0.94 msec (n = 6), respectively. With intrapipette (-)Bay K 8644 (1 microM), mean open time was best fit by two exponentials, tau(of) = 0.9+/-0.2 msec (n = 10) and tau(os) = 13.4+/-2.6 msec (n = 10); mean close time values were tau(cf) = 0.6+/-0.1 msec (n = 10) and tau(cs) = 9.8+/-1.9 msec (n = 10), respectively. With (-)Bay K 8644, channel activity was 66.5%+/-7.4%, the ensemble average current was 0.52+/-0.04 pA (n = 10) and the conductance 20.7+/-0.5 pS (n = 5). (1) the data establishes the characteristics of L-type Ca channels of human fetal hearts and their modulation by dihydropyridines; (2) the open time kinetics differ from those of avian embryonic and rat fetal hearts; and (3) the findings provide new and relevant information for understanding the physiologic behavior of unitary Ca2+ channels in the developing human heart and the baseline comparison for diseases that implicate Ca2+ channels in their etiology, such as autoimmune-associated congenital heart block.

Functional integrity of green fluorescent protein conjugated glycine receptor channels

The alpha subunit (αZ1) of the zebrafish glycine receptor (GlyR) has been N-terminus fused with green fluorescent protein (GFP). We found that both pharmacological and electrophysiological properties of this chimeric αZ1-GFP are indistinguishable from those of the wild-type receptor when expressed in Xenopus oocytes and cell lines. The apparent affinities of this receptor for agonists (glycine, taurine and GABA), and the antagonist (strychnine) are unchanged, and single channel kinetics are not altered. In the same expression systems, αZ1-GFP was visualized using fluorescence microscopy. Fluorescence was distributed anisotropically across cellular membranes. In addition to the Golgi apparatus and endoplasmic reticulum, its presence was also detected on the plasmalemma, localized at discrete hot-spots which were identified as sites of high membrane turnover. Overall, the preservation in αZ1-GFPs of the wild type receptor functional properties makes it a promising new tool for further in situ investigations of GlyR expression, distribution and function.

Gating of cystic fibrosis transmembrane conductance regulator chloride channels by adenosine triphosphate hydrolysis. Quantitative analysis of a cyclic gating scheme.

Gating of the cystic fibrosis transmembrane conductance regulator (CFTR) involves a coordinated action of ATP on two nucleotide binding domains (NBD1 and NBD2). Previous studies using nonhydrolyzable ATP analogues and NBD mutant CFTR have suggested that nucleotide hydrolysis at NBD1 is required for opening of the channel, while hydrolysis of nucleotides at NBD2 controls channel closing. We studied ATP-dependent gating of CFTR in excised inside-out patches from stably transfected NIH3T3 cells. Single channel kinetics of CFTR gating at different [ATP] were analyzed. The closed time constant (tauc) decreased with increasing [ATP] to a minimum value of approximately 0.43 s at [ATP] >1.00 mM. The open time constant (tauo) increased with increasing [ATP] with a minimal tauo of approximately 260 ms. Kinetic analysis of K1250A-CFTR, a mutant that abolishes ATP hydrolysis at NBD2, reveals the presence of two open states. A short open state with a time constant of approximately 250 ms is dominant at low ATP concentrations (10 microM) and a much longer open state with a time constant of approximately 3 min is present at millimolar ATP. These data suggest that nucleotide binding and hydrolysis at NBD1 is coupled to channel opening and that the channel can close without nucleotide interaction with NBD2. A quantitative cyclic gating scheme with microscopic irreversibility was constructed based on the kinetic parameters derived from single-channel analysis. The estimated values of the kinetic parameters suggest that NBD1 and NBD2 are neither functionally nor biochemically equivalent.

Two Regions of Sulfonylurea Receptor Specify the Spontaneous Bursting and ATP Inhibition of KATP Channel Isoforms

KATP channels are heteromultimers of KIR6.2 and a sulfonylurea receptor, SUR, an ATP binding cassette (ABC) protein with several isoforms. KIR6.2 forms a channel pore whose spontaneous activity and ATP sensitivity are modulated by the receptor via an unknown interaction(s). Side by side comparison of single-channel kinetics and steady-state ATP inhibition of human beta-cell, SUR1/KIR6.2, versus cardiac, SUR2A/KIR6.2 channels demonstrate that the latter have a greater mean burst duration and open probability in the absence of nucleotides and approximately 4-fold higher IC50(ATP). We have used matched chimeras of SUR1 and SUR2A to show that the kinetics, which determine the maximal open probability (Pomax), and the ATP sensitivity are functionally separable and to identify the two segments of SUR responsible for these isoform differences. A region within the first five transmembrane domains specifies the interburst kinetics, whereas a C-terminal segment determines the sensitivity to inhibitory ATP. The separable effects of SUR on ATP inhibition and channel kinetics implies that the cytoplasmic C terminus of SUR either directly modulates the affinity of a weak ATP binding site on the inward rectifier or affects linkage between the binding site and the gate. This is the first identification of parts of an ABC protein that interact with an ion channel subunit to modulate the spontaneous activity and ATP sensitivity of the heteromeric channel.

Heparin modulates the single channel kinetics of reconstituted AMPA receptors from rat brain

Glutamate receptors specifically activated by α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) have been reported to interact with the highly sulfated glycosaminoglycan, heparin, and to subsequently express lower binding affinity for [3H]AMPA. The present study examined whether heparin also modifies the kinetic properties of single channel activity expressed by isolated AMPA receptors from rat forebrain. Upon application of 280 nM AMPA, the partially purified receptors reconstituted in lipid bilayers expressed bursting channel activity that was inhibited by dinitroquinoxaline-2-3,-dione (DNQX). Treating the receptors with heparin (10 μg/ml) produced no change in conductance but the mean burst length for 280 nM AMPA was nearly doubled. Heparin also prolonged the lifetime of open states of the individual ion channels 3–5-fold, perhaps by causing a decrease in the closing rate constant for channel gating. Heparin had no effect on the lifetime of the closed state or on the amplitude of currents. The single channel open time was voltage-dependent and an increase of applied voltage caused a decrease in the heparin effect on channel open times. While the lifetime of the open channel was increased 3–4 times by heparin at 20 mV, there was no significant change induced at 43 mV. The equivalent electric charge of the channel gate was increased by 40%. The heparin effects were specific as another polysaccharide, dextran, and a monomeric constituent of heparin, glucosamine 2,3-disulfate, failed to have any effect on the receptors. These findings suggest that heparin-containing extracellular matrix components can interact with AMPA receptors and influence their functional properties. Synapse 31:203–209, 1999. © 1999 Wiley-Liss, Inc.

Heparin modulates the single channel kinetics of reconstituted AMPA receptors from rat brain.

Glutamate receptors specifically activated by alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) have been reported to interact with the highly sulfated glycosaminoglycan, heparin, and to subsequently express lower binding affinity for [3H]AMPA. The present study examined whether heparin also modifies the kinetic properties of single channel activity expressed by isolated AMPA receptors from rat forebrain. Upon application of 280 nM AMPA, the partially purified receptors reconstituted in lipid bilayers expressed bursting channel activity that was inhibited by dinitroquinoxaline-2-3,-dione (DNQX). Treating the receptors with heparin (10 microg/ml) produced no change in conductance but the mean burst length for 280 nM AMPA was nearly doubled. Heparin also prolonged the lifetime of open states of the individual ion channels 3-5-fold, perhaps by causing a decrease in the closing rate constant for channel gating. Heparin had no effect on the lifetime of the closed state or on the amplitude of currents. The single channel open time was voltage-dependent and an increase of applied voltage caused a decrease in the heparin effect on channel open times. While the lifetime of the open channel was increased 3-4 times by heparin at 20 mV, there was no significant change induced at 43 mV. The equivalent electric charge of the channel gate was increased by 40%. The heparin effects were specific as another polysaccharide, dextran, and a monomeric constituent of heparin, glucosamine 2,3-disulfate, failed to have any effect on the receptors. These findings suggest that heparin-containing extracellular matrix components can interact with AMPA receptors and influence their functional properties.

Voltage-insensitive gating after charge-neutralizing mutations in the S4 segment of Shaker channels.

Shaker channel mutants, in which the first (R362), second (R365), and fourth (R371) basic residues in the S4 segment have been neutralized, are found to pass potassium currents with voltage-insensitive kinetics when expressed in Xenopus oocytes. Single channel recordings clarify that these channels continue to open and close from -160 to +80 mV with a constant opening probability (Po). Although Po is low ( approximately 0.15) in these mutants, mean open time is voltage independent and similar to that of control Shaker channels. Additionally, these mutant channels retain characteristic Shaker channel selectivity, sensitivity to block by 4-aminopyridine, and are partially blocked by external Ca2+ ions at very negative potentials. Furthermore, mean open time is approximately doubled, in both mutant channels and control Shaker channels, when Rb+ is substituted for K+ as the permeant ion species. Such strong similarities between mutant channels and control Shaker channels suggests that the pore region has not been substantially altered by the S4 charge neutralizations. We conclude that single channel kinetics in these mutants may indicate how Shaker channels would behave in the absence of voltage sensor input. Thus, mean open times appear primarily determined by voltage-insensitive transitions close to the open state rather than by voltage sensor movement, even in control, voltage-sensitive Shaker channels. By contrast, the low and voltage-insensitive Po seen in these mutant channels suggests that important determinants of normal channel opening derive from electrostatic coupling between S4 charges and the pore domain.

Effects of Nitenpyram on the Neuronal Nicotinic Acetylcholine Receptor-Channel in Rat Phaeochromocytoma PC12 Cells

Nitenpyram, (E)-N-(6-chloro-3-pyridylmethyl)-N-ethyl-N'-methyl-2-nitro-vinylidenediamine, is known to act on the nicotinic acetylcholine receptor-channel (AChR). We examined the effects of nitenpyram on the neuronal type of the nicotinic AChR in rat clonal phaeochromocytoma PC12 cells using a patch clamp technique to clarify the mechanisms of action at the single-channel level. Nitenpyram itself induced single-channel currents mediated by the neuronal nicotinic AChR. Co-application of ACh and nitenpyram opened the channels exhibiting the two conductance states. The proportion of main conductance levels was decreased and that of subconductance levels was increased in the presence of nitenpyram. The open time and closed time distribution, but not for the burst duration, for the main conductance state currents with co-application of ACh and nitenpyram were similar to those of ACh-induced current. These changes of single-channel kinetics result in a decrease in probability of openings of main conductance state currents explaining the effects of nitenpyram on the neuronal nicotinic AChR. The effects of nitenpyram on the acetylcholine-induced current are deemed directly responsible for the toxic actions in animals.

Subunit composition determines the single channel kinetics of the epithelial sodium channel.

We have further characterized at the single channel level the properties of epithelial sodium channels formed by coexpression of alpha with either wild-type beta or gamma subunits and alpha with carboxy-terminal truncated beta (betaT) or gamma (gammaT) subunits in Xenopus laevis oocytes. alphabeta and alphabetaT channels (9.6 and 8.7 pS, respectively, with 150 mM Li+) were found to be constitutively open. Only upon inclusion of 1 microM amiloride in the pipette solution could channel activity be resolved; both channel types had short open and closed times. Mean channel open probability (Po) for alphabeta was 0.54 and for alphabetaT was 0.50. In comparison, alphagamma and alphagammaT channels exhibited different kinetics: alphagamma channels (6.7 pS in Li+) had either long open times with short closings, resulting in a high Po (0.78), or short openings with long closed times, resulting in a low Po (0. 16). The mean Po for all alphagamma channels was 0.48. alphagammaT (6.6 pS in Li+) behaved as a single population of channels with distinct kinetics: mean open time of 1.2 s and closed time of 0.4 s, with a mean Po of 0.6, similar to that of alphagamma. Inclusion of 0. 1 microM amiloride in the pipette solution reduced the mean open time of alphagammaT to 151 ms without significantly altering the closed time. We also examined the kinetics of amiloride block of alphabeta, alphabetaT (1 microM amiloride), and alphagammaT (0.1 microM amiloride) channels. alphabeta and alphabetaT had similar blocking and unblocking rate constants, whereas the unblocking rate constant for alphagammaT was 10-fold slower than alphabetaT. Our results indicate that subunit composition of ENaC is a main determinant of Po. In addition, channel kinetics and Po are not altered by carboxy-terminal deletion in the beta subunit, whereas a similar deletion in the gamma subunit affects channel kinetics but not Po.

Mathematical model of the CA1 region of the rat hippocampus

A mathematical transcription of the intrinsic circuit of the CA1 region of the rat dorsal hippocampus was made and the model parameters adjusted according to experimental data from intracellular recordings and single channel kinetics. This model was able to simulate well the profile of the field potentials recorded extracellularly and the well known phenomenon of the paired-pulse depression. The results suggest that the depression of the second pulse, often interpreted in the literature as resulting from inhibition, can also be due to `shunting' effects on the CA1 pyramids' membrane. The rhythmic oscillations of the field potential (EEG) was obtained as an emergent property of the network dynamics. The frequency of the field oscillation followed the main synaptic input in the region (Schaffer collaterals).

Patch clamp on the luminal membrane of exocrine gland acini from frog skin (Rana esculenta) reveals the presence of cystic fibrosis transmembrane conductance regulator-like Cl- channels activated by cyclic AMP.

Chloride channels in the luminal membrane of exocrine gland acini from frog skin (Rana esculenta) constituted a single homogeneous population. In cell-attached patches, channels activated upon exposure to isoproterenol, forskolin, or dibutyryl-cAMP and isobutyl-1-methyl-xanthine rectified in the outward direction with a conductance of 10.0 +/- 0.4 pS for outgoing currents. Channels in stimulated cells reversed at 0 mV applied potential, whereas channels in unstimulated cells reversed at depolarized potentials (28.1 +/- 6.7 mV), indicating that Cl- was above electrochemical equilibrium in unstimulated, but not in stimulated, cells. In excised inside-out patches with 25 mM Cl- on the inside, activity of small (8-pS) linear Cl--selective channels was dependent upon bath ATP (1.5 mM) and increased upon exposure to cAMP-dependent protein kinase. The channels displayed a single substate, located just below 2/3 of the full channel amplitude. Halide selectivity was identified as PBr > PI > PCl from the Goldman equation; however, the conductance sequence when either halide was permeating the channel was GCl > GBr >> GI. In inside-out patches, the channels were blocked reversibly by 5-nitro-2-(3-phenylpropylamino)benzoic acid, glibenclamide, and diphenylamine-2-carboxylic acid, whereas 4, 4-diisothiocyanatostilbene-2,2-disulfonic acid blocked channel activity completely and irreversibly. Single-channel kinetics revealed one open state (mean lifetime = 158 +/- 72 ms) and two closed states (lifetimes: 12 +/- 4 and 224 +/- 31 ms, respectively). Power density spectra had a double-Lorentzian form with corner frequencies 0.85 +/- 0.11 and 27.9 +/- 2.9 Hz, respectively. These channels are considered homologous to the cystic fibrosis transmembrane conductance regulator Cl- channel, which has been localized to the submucosal skin glands in Xenopus by immunohistochemistry (Engelhardt, J.F., S.S. Smith, E. Allen, J.R. Yankaskas, D.C. Dawson, and J.M. Wilson. 1994. Am. J. Physiol. 267: C491-C500) and, when stimulated by cAMP-dependent phosphorylation, are suggested to function in chloride secretion.

Molecular determinants of KATP channel inhibition by ATP.

ATP-sensitive K+ (KATP) channels are both inhibited and activated by intracellular nucleotides, such as ATP and ADP. The inhibitory effects of nucleotides are mediated via the pore-forming subunit, Kir6.2, whereas the potentiatory effects are conferred by the sulfonylurea receptor subunit, SUR. The stimulatory action of Mg-nucleotides complicates analysis of nucleotide inhibition of Kir6. 2/SUR1 channels. We therefore used a truncated isoform of Kir6.2, that expresses ATP-sensitive channels in the absence of SUR1, to explore the mechanism of nucleotide inhibition. We found that Kir6.2 is highly selective for ATP, and that both the adenine moiety and the beta-phosphate contribute to specificity. We also identified several mutations that significantly reduce ATP inhibition. These are located in two distinct regions of Kir6.2: the N-terminus preceding, and the C-terminus immediately following, the transmembrane domains. Some mutations in the C-terminus also markedly increased the channel open probability, which may account for the decrease in apparent ATP sensitivity. Other mutations did not affect the single-channel kinetics, and may reduce ATP inhibition by interfering with ATP binding and/or the link between ATP binding and pore closure. Our results also implicate the proximal C-terminus in KATP channel gating.

Alcohol modulation of single GABA(A) receptor-channel kinetics.

Alcohol modulation of single-channel kinetics of GABA(A) receptor currents was studied with rat dorsal root ganglion neurons using the excised outside-out patch clamp technique. GABA (1 microM) alone or GABA (1 microM) plus ethanol (30-300 mM) or n-Octanol (30-300 microM) were applied by pressure ejection to evoke single-channel currents. The main single-channel conductance was not changed by either ethanol or n-Octanol at 25 pS. Both alcohols exerted the same effects on the single-channel kinetics, although n-Octanol was more potent than ethanol. The frequency of openings, the mean open time, the percentage of open time, the frequency of bursts, and the mean burst duration were all increased, but the mean closed time was decreased. These changes in channel kinetics account for the increase in whole-cell current amplitude caused by ethanol and n-Octanol.