Functional role of the beta subunit of high conductance calcium-activated potassium channels.

Mammalian high conductance, calcium-activated potassium (maxi-K) channels are composed of two dissimilar subunits, alpha and beta. We have examined the functional contribution of the beta subunit to the properties of maxi-K channels expressed heterologously in Xenopus oocytes. Channels from oocytes injected with cRNAs encoding both alpha and beta subunits were much more sensitive to activation by voltage and calcium than channels composed of the alpha subunit alone, while expression levels, single-channel conductance, and ionic selectivity appeared unaffected. Channels from oocytes expressing both subunits were sensitive to DHS-I, a potent agonist of native maxi-K channels, whereas channels composed of the alpha subunit alone were insensitive. Thus, alpha and beta subunits together contribute to the functional properties of expressed maxi-K channels. Regulation of co-assembly might contribute to the functional diversity noted among members of this family of potassium channels.

Kinetic time constants independent of previous single-channel activity suggest Markov gating for a large conductance Ca-activated K channel.

Models for the gating of ion channels usually assume that the rate constants for leaving any given kinetic state are independent of previous channel activity. Although such discrete Markov models have been successful in describing channel gating, there is little direct evidence for the Markov assumption of time-invariant rate constants for constant conditions. This paper tests the Markov assumption by determining whether the single-channel kinetics of the large conductance Ca-activated K channel in cultured rat skeletal muscle are independent of previous single-channel activity. The experimental approach is to examine dwell-time distributions conditional on adjacent interval durations. The time constants of the exponential components describing the distributions are found to be independent of adjacent interval duration, and hence, previous channel activity. In contrast, the areas of the different components can change. Since the observed time constants are a function of the underlying rate constants for transitions among the kinetic states, the observation of time constants independent of previous channel activity suggests that the rate constants are also independent of previous channel activity. Thus, the channel kinetics are consistent with Markov gating. An observed dependent (inverse) relationship between durations of adjacent open and shut intervals together with Markov gating indicates that there are two or more independent transition pathways connecting open and shut states. Finally, no evidence is found to suggest that gating is not at thermodynamic equilibrium: the inverse relationship was independent of the time direction of analysis.

Mechanism of maxi-K channel activation by dehydrosoyasaponin-I.

Dehydrosoyasaponin-I (DHS-I) is a potent activator of high-conductance, calcium-activated potassium (maxi-K) channels. Interaction of DHS-I with maxi-K channels from bovine aortic smooth muscle was studied after incorporating single channels into planar lipid bilayers. Nanomolar amounts of intracellular DHS-I caused the appearance of discrete episodes of high channel open probability interrupted by periods of apparently normal activity. Statistical analysis of these periods revealed two clearly separable gating modes that likely reflect binding and unbinding of DHS-I. Kinetic analysis of durations of DHS-I-modified modes suggested DHS-I activates maxi-K channels through a high-order reaction. Average durations of DHS-I-modified modes increased with DHS-I concentration, and distributions of these mode durations contained two or more exponential components. In addition, dose-dependent increases in channel open probability from low initial values were high order with average Hill slopes of 2.4-2.9 under different conditions, suggesting at least three to four DHS-I molecules bind to maximally activate the channel. Changes in membrane potential over a 60-mV range appeared to have little effect on DHS-I binding. DHS-I modified calcium- and voltage-dependent channel gating. 100 nM DHS-I caused a threefold decrease in concentration of calcium required to half maximally open channels. DHS-I shifted the midpoint voltage for channel opening to more hyperpolarized potentials with a maximum shift of -105 mV. 100 nM DHS-I had a larger effect on voltage-dependent compared with calcium-dependent channel gating, suggesting DHS-I may differentiate these gating mechanisms. A model specifying four identical, noninteracting binding sites, where DHS-I binds to open conformations with 10-20-fold higher affinity than to closed conformations, explained changes in voltage-dependent gating and DHS-I-induced modes. This model of channel activation by DHS-I may provide a framework for understanding protein structures underlying maxi-K channel gating, and may provide a basis for understanding ligand activation of other ion channels.

Oxidative regulation of large conductance calcium-activated potassium channels.

Reactive oxygen/nitrogen species are readily generated in vivo, playing roles in many physiological and pathological conditions, such as Alzheimer's disease and Parkinson's disease, by oxidatively modifying various proteins. Previous studies indicate that large conductance Ca(2+)-activated K(+) channels (BK(Ca) or Slo) are subject to redox regulation. However, conflicting results exist whether oxidation increases or decreases the channel activity. We used chloramine-T, which preferentially oxidizes methionine, to examine the functional consequences of methionine oxidation in the cloned human Slo (hSlo) channel expressed in mammalian cells. In the virtual absence of Ca(2+), the oxidant shifted the steady-state macroscopic conductance to a more negative direction and slowed deactivation. The results obtained suggest that oxidation enhances specific voltage-dependent opening transitions and slows the rate-limiting closing transition. Enhancement of the hSlo activity was partially reversed by the enzyme peptide methionine sulfoxide reductase, suggesting that the upregulation is mediated by methionine oxidation. In contrast, hydrogen peroxide and cysteine-specific reagents, DTNB, MTSEA, and PCMB, decreased the channel activity. Chloramine-T was much less effective when concurrently applied with the K(+) channel blocker TEA, which is consistent with the possibility that the target methionine lies within the channel pore. Regulation of the Slo channel by methionine oxidation may represent an important link between cellular electrical excitability and metabolism.

Paxilline inhibition of the alpha-subunit of the high-conductance calcium-activated potassium channel.

High conductance calcium-activated (maxi-K) channels are potently blocked by a family of indole diterpenes that includes paxilline. Paxilline stimulates binding of charybdotoxin (ChTX) to maxi-K channels in vascular smooth muscle and blocks these channels in electrophysiological experiments (Knaus et al., 1994b). These results suggested that paxilline blocked maxi-K channels at a site distance from the ChTX binding site located near the external entrance to the pore. Here we have examined block of the cloned alpha subunit (slo) of the maxi-K channel in excised membrane patches after internal application of paxilline. Paxilline caused a reversible inhibition of channel currents with slow washout kinetics. In the presence of 10 muM intracellular calcium, paxilline blocked currents elicited by brief voltage pulses with a Ki of 1.9 nM and a Hill coefficient near one. Changing the internal calcium by the fold caused a two to three fold change in the Ki for paxilline block, with less block occurring at high calcium concentrations. Paxilline reduced the maximum of the conductance-voltage relation in a calcium-sensitive manner with less block occurring at high calcium concentrations, and caused a 20 mV depolarizing shift in the midpoint for channel opening. The time-course of relief of paxilline block by elevated calcium was more rapid than washout of paxilline suggesting an allosteric interaction between calcium and paxilline.

Peptides isolated from the venom of Conus geographus block neuromuscular transmission.

The effects of a mixture of two peptides (GI and GII), purified from the venom of the marine gastropod, Conus geographus, were studied on neuromuscular transmission in the isolated mouse phrenic nerve--diaphragm and frog sciatic nerve--sartorius muscles. The GI--GII mixture rapidly blocked nerve-evoked contractions of the mouse diaphragm at bath concentrations greater than or equal to 0.2 microM but had no effect on contractions elicited by direct muscle stimulation. Paralytic concentrations of GI--GII had no significant effect on the compound nerve action potential of the bullfrog sciatic nerve. Similar concentrations of GI--GII produced a rapid reduction of endplate potential (epp) and miniature endplate potential amplitudes, apparently by a postsynaptic effect because the decrease in epp amplitude produced by subparalytic doses was not accompanied by significant alteration in the epp quantal content. The GI--GII mixture also inhibited [125I]alpha-bungarotoxin binding to endplate regions of the mouse diaphragm in a dose-dependent manner and was at least 10 times more potent than d-tubocurarine. We conclude that the blockage of vertebrate neuromuscular transmission by GI--GII is in part due to antagonism of acetylcholine binding to its receptor at motor endplates.

Automated electrophysiology in drug discovery.

Ion channels play essential roles in nervous system signaling, electrolyte transport, and muscle contraction. As such, ion channels are important therapeutic targets, and the search for compounds that modulate ion channels is accelerating. In order to identify and optimize ion channel modulators, assays are needed that are reliable and provide sufficient throughput for all stages of the drug discovery process. Electrophysiological assays offer the most direct and accurate characterization of channel activity and, by controlling membrane potential, can provide information about drug interactions with different conformational states. However, these assays are technically challenging and notoriously low-throughput. The recent development of several automated electrophysiology platforms has greatly increased the throughput of whole cell electrophysiological recordings, allowing them to play a more central role in ion channel drug discovery. While challenges remain, this new technology will facilitate the pharmaceutical development of ion channel modulators.

Calcium-activated potassium channels: regulation by calcium.

A wide variety of calcium-activated K channels has been described and can be conveniently separated into three classes based on differences in single-channel conductance, voltage dependence of channel opening, and sensitivity to blockers. Large-conductance calcium-activated K channels typically require micromolar concentrations of calcium to open, and their sensitivity to calcium increases with membrane depolarization, suggesting that they may be involved in repolarization events. Small-conductance calcium-activated K channels are generally more sensitive to calcium at negative membrane potentials, but their sensitivity to calcium is independent of membrane potential, suggesting that they may be involved in regulating membrane properties near the resting potential. Intermediate-conductance calcium-activated K channels are a loosely defined group, where membership is determined because a channel does not fit in either of the other two groups. Within each broad group, variations in calcium sensitivity and single-channel conductance have been observed, suggesting that there may be families of closely related calcium-activated K channels. Kinetic studies of the gating of calcium-activated potassium channels have revealed some basic features of the mechanisms involved in activation of these channels by calcium, including the number of calcium ions participating in channel opening, the number of major conformations of the channels involved in the gating process, and the number of transition pathways between open and closed states. Methods of analysis have been developed that may allow identification of models that give accurate descriptions of the gating of these channels. Although such kinetic models are likely to be oversimplifications of the behavior of a large macromolecule, these models may provide some insight into the mechanisms that control the gating of the channel, and are subject to falsification by new data.

Kinetic states and modes of single large-conductance calcium-activated potassium channels in cultured rat skeletal muscle.

1. Kinetic states and modes of a large-conductance Ca2+-activated K+ channel in excised patches of membrane from cultured rat skeletal muscle were studied with the patch clamp technique. Up to 10(6) open and shut intervals were analysed from each of seven different excised membrane patches containing a single channel. 2. Plots of the mean durations of consecutive groups of ten to fifty open and shut intervals were made to assess kinetic stability of the channel. Occasional abrupt decreases in the mean open interval duration from normal to different distinct levels, which were maintained for hundreds to thousands of consecutive intervals, indicated entry of the channel into different modes. 3. Four different kinetic modes were identified: normal mode, which included 96% of the intervals; intermediate open mode with 3.2% of the intervals; brief open mode with 0.5% of the intervals; and buzz mode with 0.1% of the intervals. The mean open interval durations were 61% of normal during the intermediate open mode, 12% of normal during the brief open mode, and 2.6% of normal during the buzz mode. 4. Most mode transitions were observed from the normal mode to one of the other modes and then back to normal. Sojourns in the normal mode lasted 5-1000 s. Sojourns in the intermediate open, brief open, and buzz modes lasted 1.5-150, 1-7, and 0.01-1 s, respectively. 5. During normal activity the distributions of interval durations were typically described by the sum of three to four exponential components for the open intervals and six to eight exponential components for the shut intervals, and this was the case for data obtained over a wide range of open channel probability resulting from different Ca2+i. These observations suggest that the channel can enter at least three to four open and six to eight shut states during normal activity. 6. The numbers of detected states for data sets of different sample sizes drawn from normal activity agreed with theoretical predictions, and were essentially independent of the segment of normal activity from which the data sets were drawn. These observations are consistent with relative stability of channel kinetics during normal activity. Detection of each additional open or shut state after the first was found to require a 3- to 10-fold increase in the number of analysed events. 7. The intermediate open mode differed from the normal mode in that the longest open component of the four normal open components was absent.

Accounting for the Ca(2+)-dependent kinetics of single large-conductance Ca(2+)-activated K+ channels in rat skeletal muscle.

1. The Ca(2+)-dependent kinetics of large-conductance Ca(2+)-activated K+ channels from cultured rat skeletal muscle were studied with the patch clamp technique. Data were collected in the absence of Na+ and Mg2+, which can alter the kinetics. About 2 x 10(5) open and shut intervals were analysed from each of five different excised membrane patches containing a single active channel. Analysis was restricted to activity in the normal mode, which includes 96% of the intervals. 2. The open probability (Popen) and dwell-time distributions of open and shut intervals were obtained at three to four different [Ca2+]i for each of the channels. Popen data were also obtained from some multichannel patches. 3. Increasing [Ca2+]i increased Popen. At a pH of 7.0 the Hill coefficient was 3.7 +/- 0.8 (range of 3.0-5.0) and a Popen of 0.5 occurred at 14 +/- 7 microM [Ca2+]i (K0.5) for data obtained at +30 mV (n = 6). At a pH of 7.2 the Hill coefficient was 3.0 +/- 0.5 (range of 2.2-3.7) and K0.5 was 9 +/- 6 microM-Ca2+ (n = 7). The large standard deviations for K0.5 reflect the observation that fourfold differences in K0.5 could be observed for different channels studied under the same experimental conditions. 4. Hill coefficients that can be greater than 3 suggest that the channel may bind four or more Ca2+ to become fully activated. The binding of four Ca2+ before opening would require a minimum of five shut states. This estimate of the minimum number of shut states is in general agreement with that obtained from the number of exponential components in the dwell-time distributions of shut intervals. Thus, two different methods give similar estimates of the minimum number of shut states. If the channel can open with different numbers of bound Ca2+, then this could give rise to the three to four open states suggested by the three to four exponential components in the open dwell-time distributions. 5. Kinetic schemes consistent with the Ca(2+)-dependent kinetics were developed by simultaneously fitting open and shut dwell-time distributions obtained at three to four different [Ca2+]i, using maximum likelihood techniques and corrections for missed events. Such simultaneous fitting can provide an increased ability to define models and rate constants.(ABSTRACT TRUNCATED AT 400 WORDS)

Postsynaptic block of frog neuromuscular transmission by conotoxin GI.

Conotoxin GI, a peptide neurotoxin contained in the venom of the marine snail Conus geographus, was applied to the cutaneous pectoris muscle of the frog, and the effects on the postsynaptic response to acetylcholine were examined. Conotoxin GI reversibly blocked nerve-evoked muscle contractions at concentrations greater than or equal to 3 to 4 microM. Micromolar concentrations of conotoxin GI significantly reduced the amplitude of miniature endplate potentials and membrane depolarizations produced by ionophoretic application of acetylcholine, suggesting that the toxin reduced the postsynaptic sensitivity to acetylcholine. The reduction in the sensitivity of the muscle to acetylcholine was not due to changes in muscle fiber resting membrane potential or input resistance. Conotoxin GI reduced the amplitudes but did not affect the rates of decay of focal, extracellularly recorded endplate currents or miniature endplate currents, suggesting that the toxin did not affect the lifetime of ion channels opened by acetylcholine. Miniature endplate currents decay five to six times more slowly than normal when acetylcholinesterase is blocked with neostigmine methyl sulfate due to repeated binding of acetylcholine to receptors as it diffuses from the synaptic cleft. Conotoxin GI reduced the amplitude and increased the rate of decay of miniature endplate currents recorded in the presence of neostigmine methyl sulfate, suggesting that the toxin reduced the binding of acetylcholine to endplate receptors. These results are consistent with the hypothesis that conotoxin GI blocks neuromuscular transmission at the frog endplate by reducing the binding of acetylcholine to receptors.

Opening and closing transitions for BK channels often occur in two steps via sojourns through a brief lifetime subconductance state.

Single channel currents were recorded with microsecond time resolution from large-conductance calcium-activated K+ channels to examine the details of the opening and closings transitions. Analysis of averaged closing transitions indicated that the initial average conductance step for closing was to the 90-95% closed channel current level. Averaged brief closings (approximately 50 microseconds) reopened from the initial 90-95% level, whereas averaged longer closings (> 300 microseconds) closed completely from this level over the next 50-100 microseconds. The 90-95% initial closed level in the averaged current records resulted typically from the average of both complete and partial closings. From 45-80% of the initial closings were complete and 20-55% were to brief lifetime (approximately 50 microseconds) subconductance levels at 65-90% of the completely closed level. Averaged opening transitions were typically mirror images of averaged closing transitions. To extend the analysis to the very brief conductance changes that underlie the flickers of the single channel current toward the closed current level, flickers, brief closings, and longer closings were averaged separately and their slopes compared. The slopes were similar (within the 3% resolution of the method), suggesting similar initial conductance steps. Similar initial closing properties for both the briefer and longer closings would be expected if the channel first passed through the kinetic and subconductance states associated with the briefer closings (including flickers) before entering the longer closed states. Such transitions would provide an explanation for the observation that openings and closings often occur in two steps.

Inverse relationship of the durations of adjacent open and shut intervals for C1 and K channels.

Ion channels in cell membranes, whether voltage-dependent or activated by ligands, make repeated transitions among open and shut states during activity. Information about the number of states and the transitional pathways between them can be obtained from the durations of open and shut intervals, as transitions to states of different lifetimes result in intervals of different mean durations. If there is only one open conformation, or state, then the durations of open intervals would be independent of the durations of adjacent shut intervals. On the other hand, if a channel has two or more open states with different mean lifetimes, and if each open state is entered directly from a different shut state with a different mean lifetime, then the open intervals should be related to the adjacent shut intervals. We now report that the durations of adjacent open and shut intervals for both a C1 channel and a large conductance Ca-activated K channel in skeletal muscle are inversely related; shorter open intervals are adjacent to longer shut intervals. These findings indicate that two or more shut states make direct transitions to two or more open states, and suggest that the lifetimes of adjacent open and shut states are inversely related.

Mechanism of iberiotoxin block of the large-conductance calcium-activated potassium channel from bovine aortic smooth muscle.

The interaction of iberiotoxin (IbTX) with the large-conductance calcium-activated potassium (maxi-K) channel was examined by measuring single-channel currents from maxi-K channels incorporated into planar lipid bilayers. Addition of nanomolar concentrations of IbTX to the external side of the channel produced long nonconducting silent periods, which were interrupted by periods of normal channel activity. The distributions of durations of blocked and unblocked periods were both described by single exponentials. The mean duration of the unblocked periods decreased in proportion with the external concentration of IbTX, while the mean duration of the blocked periods was not affected. These results suggest that IbTX blocks the maxi-K channel through a simple bimolecular binding reaction where the silent periods represent times when a single toxin molecule is bound to the channel. In symmetric solutions of 150 mM KCl, with a membrane potential of 40 mV, the mean duration of the blocked periods produced by IbTX was 840 s, and the association rate was 1.3 x 10(6) M-1 s-1, yielding an equilibrium dissociation constant of about 1 nM. Raising the internal potassium concentration increased the dissociation rate constant of IbTX in a manner which was well described by a saturable binding function for potassium. External tetraethylammonium ion increased the average duration of the unblocked periods without affecting the blocked periods, suggesting that tetraethylammonium and IbTX compete for the same site near the conductance pathway of the channel. Increasing the external concentration of monovalent cations from 25 to 300 mM with either potassium or sodium decreased the rate of binding of IbTX to the channel by approximately 24-fold, with little effect on the rate of toxin dissociation.(ABSTRACT TRUNCATED AT 250 WORDS)

Sampling, log binning, fitting, and plotting durations of open and shut intervals from single channels and the effects of noise.

(1) Analysis of the durations of open and shut intervals measured from single channels currents provides a means to investigate the mechanisms of channel gating. Durations of open and shut intervals are conveniently measured from single channel data by using a threshold level to indicate transitions between open and shut states. This paper presents a detailed characterization of sampling, binning, and noise errors associated with 50% threshold analysis, provides criteria to reduce these errors, methods to correct for them, and presents an efficient means of data handling for binning and plotting interval durations. (2) Measuring interval durations by sampling at a fixed rate introduces two types of errors, (a) the number of intervals of a given measured duration are increased (promoted) over that expected in the absence of sampling, producing a sampling promotion error, (b) sampling decreases the total fraction of true intervals that are detected, producing a sampling detection error. Sampling errors can be reduced to negligible levels if the actual or effective (after interpolation) sampling period is less than 10-20% of both the dead time and fastest time constant in the distribution of intervals. Dead time is given by the duration of a true interval that has a filtered amplitude equal to 50% of the true amplitude. (3) Methods are presented to correct for sampling promotion error during least squares and maximum likelihood fitting. Sampling detection error is more difficult to correct, but an empirical description of the sampling detection error can be used to calculate the effective fraction of detected events with sampling. (4) Noise in the single channel current record can produce two types of error. (a) If noise peaks in the absence of channel activity exceed the threshold for detection, then false channel events of brief duration are produced. Sufficient filtering will prevent this type of error. (b) Noise can also increase the total fraction of true intervals that are detected, producing a noise detection error. Increased filtering over that required to prevent false events is not necessarily the best method for reducing noise detection error, as increased filtering can prevent detection of the faster exponential components. (5) Noise detection error can be reduced in two ways: (a) an empirical description of the noise detection error can be used to calculate the effective fraction of detected events in the presence of noise. (b) The sampling period can be selected so that the sampling detection error cancels the noise detection error.(ABSTRACT TRUNCATED AT 400 WORDS)

Purification and reconstitution of the high-conductance, calcium-activated potassium channel from tracheal smooth muscle.

The high-conductance Ca(2+)-activated K+ (maxi-K) channel from bovine tracheal smooth muscle was purified to apparent homogeneity by a combination of conventional chromatographic techniques and sucrose density gradient centrifugation. Fractions with the highest specific activity for binding of monoiodotyrosine charybdotoxin, [125I]ChTX, were enriched approximately 2000-fold over the initial digitonin-solubilized material up to a specific activity of 1 nmol/mg protein. Silver staining after SDS-polyacrylamide gel electrophoresis of the fractions from the last step of the purification indicates that binding activity is correlated with a major component of the preparation that displays an apparent molecular weight of 62,000. Labeling the same preparation with 125I-Bolton-Hunter reagent reveals the existence of both 62 (alpha)- and 31 (beta)-kDa subunits, in an apparent stoichiometry of 1:1, comigrating with binding activity. The beta subunit is heavily glycosylated. Deglycosylation studies indicate that the beta subunit represents the protein to which [125I]ChTX is covalently incorporated in the presence of the bifunctional cross-linking reagent disuccinimidyl suberate. Binding of [125I]ChTX to the purified ChTX receptor displayed the same pharmacological profile that has been found previously for toxin binding to native membranes, including inhibition by iberiotoxin, limbatustoxin, tetraethylamonium, potassium, cesium, and barium. The purified preparation was reconstituted into liposomes which were then fused with artificial lipid bilayers. Single channels were readily observed with a conductance of 235 picosiemens in 150 mM KCl that displayed selectivity for potassium over chloride and that were blocked by ChTX. The open probability of these channels was increased by depolarizing membrane potentials and by raising the internal calcium concentration. These data suggest that the maxi-K channel purified from tracheal smooth muscle is composed of two subunits.

Fractal models are inadequate for the kinetics of four different ion channels.

The gating kinetics of single ion channels have been well described by models which assume that channels exist in a number of discrete kinetic states, with the rate constants for transitions among the states remaining constant in time. In contrast to such discrete Markov models, it has recently been considered whether gating might arise from transitions among a continuum of states, with the effective rate constants for leaving the collections of states given by a fractal scaling equation (Liebovitch, L.S., J. Fischbarg, J.P. Koniarek, I. Todorova, and M. Wang. 1987. Biochim. Biophys. Acta. 896:173-180; Liebovitch, L.S., and J.M. Sullivan. 1987. Biophys. J. 52:979-988). The present study compares discrete Markov with fractal continuum models to determine which best describes the gating kinetics of four different ion channels: GABA-activated Cl channels, ACh-activated end-plate channels, large conductance Ca-activated K (BK) channels, and fast Cl channels. Discrete Markov models always gave excellent descriptions of the distributions of open and shut times for all four channels. Fractal continuum models typically gave very poor descriptions of the shut times for all four channels, and also of the open times from end-plate and BK channels. The descriptions of the open times from GABA-activated and fast Cl channels by the fractal and Markov models were usually not significantly different. If the same model accounts for gating motions in proteins for both the open and shut states, then the Markov model ranked above the fractal model in 35 of 36 data sets of combined open and shut intervals, with the Markov model being tens to thousands of orders of magnitude more probable. We suggest that the examined fractal continuum model is unlikely to serve as a general mechanism for the gating of these four ion channels.

High-conductance calcium-activated potassium channels; structure, pharmacology, and function.

High-conductance calcium-activated potassium (maxi-K) channels comprise a specialized family of K+ channels. They are unique in their dual requirement for depolarization and Ca2+ binding for transition to the open, or conducting, state. Ion conduction through maxi-K channels is blocked by a family of venom-derived peptides, such as charybdotoxin and iberiotoxin. These peptides have been used to study function and structure of maxi-K channels, to identify novel channel modulators, and to follow the purification of functional maxi-K channels from smooth muscle. The channel consists of two dissimilar subunits, alpha and beta. The alpha subunit is a member of the slo Ca(2+)-activated K+ channel gene family and forms the ion conduction pore. The beta subunit is a structurally unique, membrane-spanning protein that contributes to channel gating and pharmacology. Potent, selective maxi-K channel effectors (both agonists and blockers) of low molecular weight have been identified from natural product sources. These agents, together with peptidyl inhibitors and site-directed antibodies raised against alpha and beta subunit sequences, can be used to anatomically map maxi-K channel expression, and to study the physiologic role of maxi-K channels in various tissues. One goal of such investigations is to determine whether maxi-K channels represent novel therapeutic targets.