Calcium-activated potassium channels: regulation by calcium

Effects of trypsin on large-conductance Ca2+-activated K+ channels of guinea-pig outer hair cells

High-conductance Ca(2+)-activated K(+) (BK(Ca)) channels from isolated adult guinea-pig outer hair cells were studied in inside-out membrane patches. They had a 300 pS unitary conductance and were inhibited by tetraethyl ammonium (1 mM), iberiotoxin (33 nM) and charybdotoxin (50 nM). In symmetrical 144 mM KCl their K(+) permeability (P(K)) was 5.4 x 10(-13) cm(3)/s; this was reduced to around 4.5 x 10(-13) cm(3)/s with 160 mM Na(+) in place of K(+) on either internal or external membrane surface. BK(Ca) channels from trypsin-isolated hair cells had a high open probability, that depended on both membrane voltage (16 mV/e-fold change) and the concentration of calcium ions at their intracellular surface ([Ca(2+)](i)). The Hill coefficient was 3-4. About 50% of BK(Ca) channels from mechanically isolated outer hair cells had similar characteristics; the remainder had the same high conductance but a low open probability. Trypsin (<0.5 mg/ml) applied to the intracellular face of these 'inactive' channels markedly increased their open probability. It is possible that exposure to trypsin during cell isolation removes an inactivating beta subunit. This would account for the absence of 'inactive' BK(Ca) channels in trypsin-isolated cells.

Electrophysiological properties of BK channels in Xenopus motor nerve terminals

Single channel properties of Ca(2+)-activated K(+) (BK or Maxi-K) channels have been investigated in presynaptic membranes in Xenopus motoneurone-muscle cell cultures. The occurrence and density of BK channels increased with maturation/synaptogenesis and was not uniform: highest at the release face of bouton-like synaptic varicosities in contact with muscle cells, and lowest in varicosities that did not contact muscle cells. The Ca(2+) affinity of the channel (K(d)= 7.7 microM at a membrane potential of +20 mV) was lower than those of BK channels that have been characterized in other terminals. Hill coefficients varied between 1.5 and 2.8 at different potentials and open probability increased e-fold per 16 mV change in membrane potential over a range of [Ca(2+)](i) from 1 microM to 1 mM. The maximal activation rate of ensembled single BK channel currents was in the submillisecond range at > or =+20 mV. The activation rate increased approximately 10-fold in response to a [Ca(2+)](i) increase from 1 to 100 microM, but increased only approximately 2-fold with a voltage change from +20 to +130 mV. The fastest activation kinetics of BK channels in cell-attached patches resembled that in inside-out patches with [Ca(2+)](i) of 100 microM or more, suggesting that many BK channels are located very close to calcium channels. Given the low Ca(2+) affinity and rapid Ca(2+) binding/unbinding properties, we conclude that BK channels in this preparation are adapted to play an important role in regulation of neurotransmitter release, and they are ideal reporters of local [Ca(2+)] at the inner membrane surface.

Carbonic anhydrase inhibitors are specific openers of skeletal muscle BK channel of K+-deficient rats

Carbonic-anhydrase (CA) inhibitors are used in the treatment of hypokalaemic periodic paralysis (hypoPP) and related channelopathies but their mechanism of action is unknown. Patch-clamp experiments and molecular modeling investigations were performed to evaluate the mechanism of actions of CA inhibitors on skeletal muscle Ca2+-activated-K+ (BK) channel of K+-deficient rats used as animal model of hypoPP. CA inhibitors showing different degree of CA inhibition such as acetazolamide (ACTZ), dichlorphenamide (DCP), hydrochlorthiazide (HCT), etoxzolamide (ETX), methazolamide (MTZ), and bendroflumethiazide (BFT), which lacks inhibitory effects on CA enzymes, were tested in vitro on BK channels. The application of ACTZ, BFT, ETX, and DCP to excised patches activated the BK channel with potency: ACTZ(DE50=7.3x10(-6)M)>BFT(DE50=5.93x10(-5)M)>ETX(DE50=1.17x10(-4)M)>>DCP. In contrast, MTZ and HCT failed to activate the BK channel. Molecular modeling studies showed that the capability of CA inhibitors to open the BK channel was related to the presence in their structures of an intra-molecular hydrogen bond with calculated inter-atomic distances ranging between 1.82 A degrees and 3.01 A degrees and of an aromatic ring poor of electrons. ACTZ, BFT, ETX, and DCP showed these pharmacofores, while MTZ and HCT did not. Our data indicate that the activation of BK channel is a property of CA inhibitors that interact with the channel subunit/s and that this effect is not related to their capability to inhibit the CA enzymes.

Rhythmical contractions in pulmonary arteries of monocrotaline-induced pulmonary hypertensive rats

Rhythmical contractions accompanied by an increase in cytosolic Ca2+ concentrations were produced in ring preparations of endothelium-denuded pulmonary arteries from monocrotaline-treated rats, but not in those from vehicle-treated rats, 2-3 h after a resting tension of 15 mN (150-180% of the initial wall length of the artery) was applied. The rhythmical contractions were abolished by nicardipine and ryanodine. Cyclopiazonic acid reduced the relaxation phase of the rhythmical contractions, finally leading to a sustained contraction. Similarly, apamin caused a sustained contraction, whereas charybdotoxin increased the amplitude of the rhythmical contractions. Glibenclamide had no apparent effects on them. Indomethacin and the prostaglandin H2/thromboxane A2 receptor antagonist SQ29548 abolished the rhythmical contractions and reduced the tension, but the thromboxane synthase inhibitor ozagrel had no effect. These results suggest that optimal stretch induces rhythmical contractions in the pulmonary arteries of monocrotaline-induced pulmonary hypertensive rats, to which both Ca2+ influx through voltage-operated Ca2+ channels and Ca2+ release from the endoplasmic reticulum seem to contribute. It is also suggested that small-conductance Ca(2+)-activated K+ channels participate in the relaxation phase of rhythmical contractions. Furthermore, prostaglandin H2 released from nonendothelial cells is likely to play a pivotal role in the induction of rhythmical contractions.

Developmental differences in Ca2+-activated K+ channel activity in ovine basilar artery

A primary determinant of vascular smooth muscle (VSM) tone and contractility is the resting membrane potential, which, in turn, is influenced heavily by K+ channel activity. Previous studies from our laboratory and others have demonstrated differences in the contractility of cerebral arteries from near-term fetal and adult animals. To test the hypothesis that these contractility differences result from maturational changes in voltage-gated K+ channel function, we compared this function in VSM myocytes from adult and fetal sheep cerebral arteries. The primary current-carrying, voltage-gated K+ channels in VSM myocytes are the large conductance Ca2+-activated K+ channels (BKCa) and voltage-activated K+ (KV) channels. We observed that at voltage-clamped membrane potentials of +60 mV in perforated whole cell studies, the normalized outward current densities in fetal myocytes were >30% higher than in those of the adult (P < 0.05) and that these were predominantly due to iberiotoxin-sensitive currents from BKCa channels. Excised, insideout membrane patches revealed nearly identical unitary conductances and Hill coefficients for BKCa channels. The plot of log intracellular [Ca2+] ([Ca2+]i) versus voltage for half-maximal activation (V(1/2)) yielded linear and parallel relationships, and the change in V(1/2) for a 10-fold change in [Ca2+] was also similar. Channel activity increased e-fold for a 19 +/- 2-mV depolarization for adult myocytes and for an 18 +/- 1-mV depolarization for fetal myocytes (P > 0.05). However, the relationship between BKCa open probability and membrane potential had a relative leftward shift for the fetal compared with adult myocytes at different [Ca2+]i. The [Ca2+] for half-maximal activation (i.e., the calcium set points) at 0 mV were 8.8 and 4.7 microM for adult and fetal myocytes, respectively. Thus the increased BKCa current density in fetal myocytes appears to result from a lower calcium set point.

Exocytosis at the ribbon synapse of retinal bipolar cells studied in patches of presynaptic membrane

The distribution of exocytic sites and ion channels in the synaptic terminal of retinal bipolar cells was investigated by measuring capacitance and conductance changes in cell-attached patches of presynaptic membrane. Patch depolarization evoked capacitance and conductance increases that were inhibited by blocking Ca(2+) influx or loading the terminal with EGTA. The increase in capacitance declined as the depolarization approached the reversal potential for Ca(2+), indicating that it was a result of Ca(2+)-dependent exocytosis. The conductance increase was caused by K(Ca) channels that were also activated by Ca(2+) influx. Two observations indicated that sites of exocytosis and endocytosis colocalized with clusters of Ca(2+) channels and K(Ca) channels; the initial rate of exocytosis was correlated with the activation of K(Ca) channels, and exocytosis did not occur in the 41% of patches lacking this conductance. Electron microscopy demonstrated that there were approximately 16 vesicles docked to the plasma membrane at each active zone marked by a ribbon, but vesicles were also attached to the rest of the membrane at a density of 1.5/microm(2). The density of ribbons was 0.10 +/- 0.02/microm(2), predicting that approximately 43% of cell-attached patches would lack an active zone. The density of Ca(2+) channel clusters assayed by capacitance and conductance responses was therefore similar to the density of ribbons. These results are consistent with the idea that Ca(2+) channel clusters were colocalized with ribbons but do not exclude the possibility that calcium channels also occurred at other sites. The wide distribution of vesicles docked to the plasma membrane suggests that exocytosis might also be triggered by the spread of Ca(2+) from Ca(2+) channel clusters.

The cytoplasmic tail of large conductance, voltage- and Ca2+-activated K+ (MaxiK) channel is necessary for its cell surface expression

The large conductance, voltage- and Ca(2+)-activated K(+) channel (MaxiK) is expressed in several renal segments and functions in cell volume regulation and flow-mediated K(+) secretion. Previously, we cloned two MaxiK channel isoforms, named rbslo1 and rbslo2, from rabbit renal cells. rbslo1 has a 58-amino acid insertion after the S8 hydrophobic domain, whereas rbslo2 is truncated and cannot be activated. Here we use the sequence differences between the two variants to examine their plasma membrane processing. Plasma membrane localization of rbslo1 and 2 expressed in HEK293 cells was assayed by electrophysiology, immunocytochemistry, and biochemistry studies. Consistent with its functional silence, rbslo2 localized primarily within the cytoplasm, presumably in the endoplasmic reticulum and Golgi region. Coexpression with MaxiK beta subunits did not alter the cellular localization of either rbslo1 or rbslo2. When rbslo1 and 2 are cotransfected in non-polarized cells, they colocalized primarily within the cell with only rbslo1 detected at the plasma membrane. When transfected into polarized, medullary-thick ascending limb (mTAL) cells, rbslo1 is expressed at the apical membrane whereas the majority of rbslo2 localized throughout the cytoplasm. Given the high degree of similarity between the two isoforms, we conclude that the cytoplasmic tail of rbslo1 is important for the cell surface expression of MaxiK channels.

4-aminopyridine- and dendrotoxin-sensitive potassium channels influence excitability of vagal mechano-sensitive endings in guinea-pig oesophagus

1. Distension-sensitive vagal afferent fibres from the guinea-pig oesophagus were recorded extracellularly in vitro. Most recorded units were spontaneously active firing at 3.2+/-0.3 Hz (n=41, N=41) and had low thresholds (less than 1 mm) to circumferential stretch. Dynamic and adapted phases of stretch-evoked firing, as well as a silent period were linearly dependent on the amplitude of stretch. 2. High K+ (7-12 mM) Krebs solution dose-dependently increased both spontaneous and stretch-evoked firing and reduced the duration of the silent period. 3. Charybdotoxin (ChTX, 100 nM) slightly increased spontaneous and stretch-evoked firing and decreased the silent period, while neither iberiotoxin (100 nM) nor apamin (0.5 microM) had significant effects. omega-Conotoxin GVIA (0.5 microM) did not significantly affect firing of vagal mechanoreceptors. 4. In the majority of single units, 4-aminopyridine (4-AP) concentration-dependently (EC(50) approximately 28 microM) increased spontaneous firing, strongly reduced the silent period but did not affect stretch (3 mm)-induced firing. Firing evoked by 1-2 mm was increased by 4-AP. 5. Alpha-dendrotoxin (DnTX, 300 nM) and DnTX K (30 nM) slightly increased spontaneous and stretch-evoked firing. There was no additive effect on spontaneous firing when ChTX and DnTX K were applied simultaneously. 6. Barium (100 microM) increased stretch-induced firing, probably due to an increase in intramural tension. Glibenclamide (10 microM) had no effect on spontaneous or stretch-induced firing. 7. The results indicate that voltage-gated 4-AP- and dendrotoxin-sensitive K+ channels are the main type of K+ channels that influence excitability of vagal mechano-sensitive endings of the guinea-pig oesophagus. They were involved in control of spontaneous firing and in stretch-induced firing evoked by moderate stretch, but none of the K+ channels appeared to be involved in adaptation to maintained stretch by their slowly adapting vagal mechanoreceptors.

Characterization of K(+) currents using an in situ patch clamp technique in body wall muscle cells from Caenorhabditis elegans

The properties of K(+) channels in body wall muscle cells acutely dissected from the nematode Caenorhabditis elegans were investigated at the macroscopic and unitary level using an in situ patch clamp technique. In the whole-cell configuration, depolarizations to potentials positive to -40 mV gave rise to outward currents resulting from the activation of two kinetically distinct voltage-dependent K(+) currents: a fast activating and inactivating 4-aminopyridine-sensitive component and a slowly activating and maintained tetraethylammonium-sensitive component. In cell-attached patches, voltage-dependent K(+) channels, with unitary conductances of 34 and 80 pS in the presence of 5 and 140 mM external K(+), respectively, activated at membrane potentials positive to -40 mV. Excision revealed that these channels corresponded to Ca(2+)-activated K(+) channels exhibiting an unusual sensitivity to internal Cl(-) and whose activity progressively decreased in inside-out conditions. After complete run-down of these channels, one third of inside-out patches displayed activity of another Ca(2+)-activated K(+) channel of smaller unitary conductance (6 pS at 0 mV in the presence of 5 mM external K(+)). In providing a detailed description of native K(+) currents in body wall muscle cells of C. elegans, this work lays the basis for further comparisons with mutants to assess the function of K(+) channels in this model organism that is highly amenable to molecular and classical genetics.

Elimination of the BK(Ca) channel's high-affinity Ca(2+) sensitivity

We report here a combination of site-directed mutations that eliminate the high-affinity Ca(2+) response of the large-conductance Ca(2+)-activated K(+) channel (BK(Ca)), leaving only a low-affinity response blocked by high concentrations of Mg(2+). Mutations at two sites are required, the "Ca(2+) bowl," which has been implicated previously in Ca(2+) binding, and M513, at the end of the channel's seventh hydrophobic segment. Energetic analyses of mutations at these positions, alone and in combination, argue that the BK(Ca) channel contains three types of Ca(2+) binding sites, one of low affinity that is Mg(2+) sensitive (as has been suggested previously) and two of higher affinity that have similar binding characteristics and contribute approximately equally to the power of Ca(2+) to influence channel opening. Estimates of the binding characteristics of the BK(Ca) channel's high-affinity Ca(2+)-binding sites are provided.

A BK(Ca) to K(v) switch during spermatogenesis in the rat seminiferous tubules

Spermatogenesis is a complex cellular event during which the diploid germ cells differentiate and divide by mitosis and meiosis at specific time points along the spermatogenic cycle to generate the haploid spermatozoa. For this complex event to go in an orderly manner, cell differentiation and division must be precisely controlled by signals arising from within and outside the seminiferous tubules. Changes in the membrane potential of the germ cells are likely to be an important part of the signaling mechanism. We have applied the whole-cell patch clamp technique to identify and characterize ion channels in different spermatogenic cells from immature and mature rat testes fractionated by discontinuous Percoll gradient. A voltage- and Ca(2+)- dependent, outwardly rectifying current with gating and pharmacologic properties resembling the large conductance K(+) channels (BK(Ca)) was recorded from the spermatogonia and primary spermatocytes. Another voltage-dependent, outwardly rectifying current that was sensitive to 4-aminopyridine, a K(v) channel blocker, was detected in spermatocytes and early spermatids. This current is likely caused by the smaller conductance, voltage-sensitive K(+) channels (K(v)). In some spermatogonia, both the BK(Ca) channels and the K(v) channels could be simultaneously detected in the same cell. It appears that during the course of spermatogenesis, there is up-regulation of K(v) but down-regulation of BK(Ca). Reverse transcription-polymerase chain reaction, Western blot analysis, and immunohistochemistry further confirmed the differential expression of the ion channels in different spermatogenic cells. We conclude that these ion channels may play an important role in the control of spermatogenesis.

Ca(2+) influx and opening of Ca(2+)-activated K(+) channels in muscle fibers from control and mdx mice

Using the patch-clamp technique, we demonstrate that, in depolarized cell-attached patches from mouse skeletal muscle fibers, a short hyperpolarization to resting value is followed by a transient activation of Ca(2+)-activated K(+) channels (K(Ca)) upon return to depolarized levels. These results indicate that sparse sites of passive Ca(2+) influx at resting potentials are responsible for a subsarcolemmal Ca(2+) load high enough to induce K(Ca) channel activation upon muscle activation. We then investigate this phenomenon in mdx dystrophin-deficient muscle fibers, in which an elevated Ca(2+) influx and a subsequent subsarcolemmal Ca(2+) overload are suspected. The number of Ca(2+) entry sites detected with K(Ca) was found to be greater in mdx muscle. K(Ca) activity reflecting subsarcolemmal Ca(2+) load was also found to be independent of the activity of leak channels carrying inward currents at negative potentials in mdx muscle. These results indicate that the sites of passive Ca(2+) influx newly described in this study could represent the Ca(2+) influx pathways responsible for the subsarcolemmal Ca(2+) overload in mdx muscle fibers.

K+ currents generated by NMDA receptor activation in rat hippocampal pyramidal neurons

Long lasting outward currents mediated by Ca2+-activated K+ channels can be induced by Ca2+ influx through N-methyl-D-aspartate (NMDA)-receptor channels in voltage-clamped hippocampal pyramidal neurons. Using specific inhibitors, we have attempted to identify the channels that underlie these outward currents. At a holding potential of -50 mV, applications of 1 mM NMDA to the soma of cultured hippocampal pyramidal neurons induced the expected inward currents. In 44% of cells tested, these were followed by outward currents (average amplitude 60 +/- 7 pA) that peaked 2.5 s after the initiation of the inward NMDA currents and decayed with a time constant of 1.4 s. In 43% of those cells exhibiting an outward current, SK channel inhibitors, UCL 1848 (100 nM) and apamin (100 nM) abolished the outward current. In the remainder of the cells, the outward currents were either insensitive or only partly inhibited (44 +/- 4%) by 100 nM UCL 1848. In these cells, the outward currents were reduced by the slow afterhyperpolarization (sAHP) inhibitors, muscarine (3 microM; 43 +/- 9%), UCL 1880 (3 microM; 34 +/- 10%), and UCL 2027 (3 microM; 57 +/- 6%). Neither the BK channel inhibitor, charybdotoxin (100 nM), nor the Na+/K+ ATPase inhibitor, ouabain (100 microM), reduced these outward currents. Irrespective of the pharmacology, the time course of the outward current did not differ. Interestingly, no correlation was observed between the presence of a slow apamin-insensitive afterhyperpolarization and an outward current insensitive to SK channel blockers following NMDA-receptor activation. It is concluded that an NMDA-mediated rise in [Ca2+]i can result in the activation of apamin-sensitive SK channels and of the channels that underlie the sAHP. The activation of these channels may, however, depend on their location relative to NMDA receptors as well as on the spatial Ca2+ buffering within individual neurons.

Modulation of the Ca2+-activated large conductance K+ channel by intracellular pH in human renal proximal tubule cells

The Ca2+-activated and voltage-sensitive large conductance K+ channel (BK channel) with a slope conductance of about 300 pS is present in the surface membrane of cultured human renal proximal tubule epithelial cells (RPTECs). In this study we examined the effects of cytoplasmic pH (pH(i)) on activity and gating kinetics of the BK channel by using the inside-out configuration of the patch-clamp technique. At a constant cytoplasmic Ca(2+) concentration ([Ca2+]i), membrane depolarization raised channel open probability (P(o)), and lowering pH(i) shifted the P(o)-membrane potential (V(m)) relationship to the positive voltage direction. However, the value of the gating charge was not affected by changes in pH(i), suggesting that the effects of pH(i) on P(o) were not due to an alternation of the voltage sensitivity. At constant V(m), lowering pH(i) suppressed the [Ca2+]i-dependent channel activation and shifted the P(o)-[Ca2+]i relationship in the direction of higher [Ca2+]i with a reduction of maximal P(o). Furthermore, both the mean open and mean closed times of the BK channels at pH(i) 6.3 in the presence of 10(-4) M [Ca2+](i) were shorter than those at pH(i) 7.3 in the presence of 10(-5) M [Ca2+]i, even though these two different conditions gave a similar P(o). The data indicate that cytoplasmic H+ suppresses P(o) of the BK channel in RPTECs, which involves the mechanism independent of Ca2+ activation. Our preliminary kinetic analysis also supported this notion.

Mechanism of generation of spontaneous miniature outward currents (SMOCs) in retinal amacrine cells

A subtype of retinal amacrine cells displayed a distinctive array of K(+) currents. Spontaneous miniature outward currents (SMOCs) were observed in the narrow voltage range of -60 to -40 mV. Depolarizations above approximately -40 mV were associated with the disappearance of SMOCs and the appearance of transient (I(to)) and sustained (I(so)) outward K(+) currents. I(to) appeared at about -40 mV and its apparent magnitude was biphasic with voltage, whereas I(so) appeared near -30 mV and increased linearly. SMOCs, I(to), and a component of I(so) were Ca(2+) dependent. SMOCs were spike shaped, occurred randomly, and had decay times appreciably longer than the time to peak. In the presence of cadmium or cobalt, SMOCs with pharmacologic properties identical to those seen in normal Ringer's could be generated at voltages of -20 mV and above. Their mean amplitude was Nernstian with respect to [K(+)](ext) and they were blocked by tetraethylammonium. SMOCs were inhibited by iberiotoxin, were insensitive to apamin, and eliminated by nominally Ca(2+)-free solutions, indicative of BK-type Ca(2+)-activated K(+) currents. Dihydropyridine Ca(2+) channel antagonists and agonists decreased and increased SMOC frequencies, respectively. Ca(2+) permeation through the kainic acid receptor had no effect. Blockade of organelle Ca(2+) channels by ryanodine, or intracellular Ca(2+) store depletion with caffeine, eradicated SMOCs. Internal Ca(2+) chelation with 10 mM BAPTA eliminated SMOCs, whereas 10 mM EGTA had no effect. These results suggest a mechanism whereby Ca(2+) influx through L-type Ca(2+) channels and its subsequent amplification by Ca(2+)-induced Ca(2+) release via the ryanodine receptor leads to a localized elevation of internal Ca(2+). This amplified Ca(2+) signal in turn activates BK channels in a discontinuous fashion, resulting in randomly occurring SMOCs.

Channels underlying neuronal calcium-activated potassium currents

In many cell types rises in cytosolic calcium, either due to influx from the extracellular space, or by release from an intracellular store activates calcium dependent potassium currents on the plasmalemma. In neurons, these currents are largely activated following calcium influx via voltage gated calcium channels active during the action potentials. Three types of these currents are known: I(c), I(AHP) and I(sAHP). These currents can be distinguished by clear differences in their pharmacology and kinetics. Activation of these potassium currents modulates action potential time course and the repetitive firing properties of neurons. Single channel studies have identified two types of calcium-activated potassium channel which can also be separated on biophysical and pharmacological grounds and have been named BK and SK channels. It is now clear that BK channels underlie I(c) whereas SK channels underlie I(AHP). The identity of the channels underlying I(sAHP) are not known. In this review, we discuss the properties of the different types of calcium-activated potassium channels and the relationship between these channels and the macroscopic currents present in neurons.

ATP-stimulated Ca(2+)-activated K(+) efflux pathway and differentiation of human placental cytotrophoblast cells

The aim of this study was to determine whether extracellular ATP ([ATP](o)) stimulated a Ca(2+)-activated K(+) efflux in trophoblast cells that was dependent on extracellular Ca(2+) ([Ca(2+)](o)). Cytotrophoblast cells, isolated from human placenta, were examined following 18 h (relatively undifferentiated) and 66 h (multinucleate cells) of culture. Potassium efflux was measured using (86)Rb as a trace marker. Intracellular Ca(2+) ([Ca(2+)](i)) was examined by microfluorometry using fura 2. [ATP](o) significantly increased (86)Rb efflux to a peak that declined to control (18-h cells) or an elevated plateau (66-h cells) and was inhibited by 100 nM charybdotoxin. Removing [Ca(2+)](o) significantly reduced (86)Rb efflux in both groups as did application of 150 microM GdCl(3). [ATP](o) significantly increased [Ca(2+)](i) in both groups of cells. The response was reduced by removing [Ca(2+)](o) and applying 150 microM GdCl(3). For both (86)Rb efflux and microfluorometry experiments, the response to [ATP](o) was more dependent on [Ca(2+)](o) in 66-h cells compared with 18-h cells (approximately 70% greater). Cytotrophoblast cells exhibit an [ATP](o)-stimulated Ca(2+)-activated K(+) efflux. The dependency of this pathway on [Ca(2+)](o) is greater in the 66-h multinucleate syncytiotrophoblast-like cells, suggesting that the mechanism for Ca(2+) entry may be altered during differentiation of trophoblast cells.

Cloning and characterization of glioma BK, a novel BK channel isoform highly expressed in human glioma cells

Voltage-dependent large-conductance Ca2+-activated K+ channels (BK channels) are widely expressed in excitable and nonexcitable cells. BK channels exhibit diverse electrophysiological properties, which are attributable in part to alternative splicing of their alpha-subunits. BK currents have been implicated in the growth control of glial cells, and BK channels with novel biophysical properties have recently been characterized in human glioma cells. Here we report the isolation, cloning, and functional characterization of glioma BK (gBK), a novel splice isoform of hSlo, the gene that encodes the alpha-subunits of human BK channels. The primary sequence of gBK is 97% identical to its closest homolog hbr5, but it contains an additional 34-amino-acid exon at splice site 2 in the C-terminal tail of BK channels. hSlo transcripts containing this novel exon are expressed ubiquitously in various normal tissues as well as in neoplasmic samples, suggesting that the novel exon may modulate important physiological functions of BK channels. Expression of gBK in Xenopus oocytes gives rise to iberiotoxin-sensitive (IbTX) currents, with an IC(50) for IbTX of 5.7 nm and a Hill coefficient of 0.76. Single gBK channels have a unitary conductance of similar250 pS, and the currents show significantly slower activation and higher Ca2+ sensitivity than hbr5. Ca2+ sensitivity was enhanced specifically at physiologically relevant [Ca2+]i (100-500 nm). Examination of biopsies from patients with malignant gliomas has revealed specific overexpression of BK channels in gliomas compared with nonmalignant human cortical tissues. Importantly, tumor malignancy grades have correlated positively with BK channel expression, suggesting an important role for the gBK channel in glioma biology.

Consequences of the stoichiometry of Slo1 alpha and auxiliary beta subunits on functional properties of large-conductance Ca2+-activated K+ channels

Auxiliary beta subunits play a major role in defining the functional properties of large-conductance, Ca2+-dependent BK-type K+ channels. In particular, both the beta1 and beta2 subunits produce strong shifts in the voltage dependence of channel activation at a given Ca2+. Beta subunits are thought to coassemble with alpha subunits in a 1:1 stoichiometry, such that a full ion channel complex may contain up to four beta subunits per channel. However, previous results raise the possibility that ion channels with less than a full complement of beta subunits may also occur. The functional consequence of channels with differing stoichiometries remains unknown. Here, using expression of alpha and beta subunits in Xenopus oocytes, we show explicitly that functional BK channels can arise with less than four beta subunits. Furthermore, the results show that, for both the beta1 and beta2 subunits, each individual beta subunit produces an essentially identical, incremental effect on the voltage dependence of gating. For channels arising from alpha + beta2 subunits, the number of beta2 subunits per channel also has a substantial impact on properties of steady-state inactivation and recovery from inactivation. Thus, the stoichiometry of alpha:beta subunit assembly can play a major functional role in defining the apparent Ca2+ dependence of activation of BK channels and in influencing the availability of BK channels for activation.

Natural bile acids and synthetic analogues modulate large conductance Ca2+-activated K+ (BKCa) channel activity in smooth muscle cells

Bile acids have been reported to produce relaxation of smooth muscle both in vitro and in vivo. The cellular mechanisms underlying bile acid-induced relaxation are largely unknown. Here we demonstrate, using patch-clamp techniques, that natural bile acids and synthetic analogues reversibly increase BK(Ca) channel activity in rabbit mesenteric artery smooth muscle cells. In excised inside-out patches bile acid-induced increases in channel activity are characterized by a parallel leftward shift in the activity-voltage relationship. This increase in BK(Ca) channel activity is not due to Ca(2+)-dependent mechanism(s) or changes in freely diffusible messengers, but to a direct action of the bile acid on the channel protein itself or some closely associated component in the cell membrane. For naturally occurring bile acids, the magnitude of bile acid-induced increase in BK(Ca) channel activity is inversely related to the number of hydroxyl groups in the bile acid molecule. By using synthetic analogues, we demonstrate that such increase in activity is not affected by several chemical modifications in the lateral chain of the molecule, but is markedly favored by polar groups in the side of the steroid rings opposite to the side where the methyl groups are located, which stresses the importance of the planar polarity of the molecule. Bile acid-induced increases in BK(Ca) channel activity are also observed in smooth muscle cells freshly dissociated from rabbit main pulmonary artery and gallbladder, raising the possibility that a direct activation of BK(Ca) channels by these planar steroids is a widespread phenomenon in many smooth muscle cell types. Bile acid concentrations that increase BK(Ca) channel activity in mesenteric artery smooth muscle cells are found in the systemic circulation under a variety of human pathophysiological conditions, and their ability to enhance BK(Ca) channel activity may explain their relaxing effect on smooth muscle.

Calcium-activated potassium channel SK1- and IK1-like immunoreactivity in injured human sensory neurones and its regulation by neurotrophic factors

Calcium-activated potassium ion channels SK and IK (small and intermediate conductance, respectively) may be important in the pathophysiology of pain following nerve injury, as SK channels are known to impose a period of reduced excitability after each action potential by afterhyperpolarization. We studied the presence and changes of human SK1 (hSK1)- and hIK1-like immunoreactivity in control and injured human dorsal root ganglia (DRG) and peripheral nerves and their regulation by key neurotrophic factors in cultured rat sensory neurones. Using specific antibodies, hSK-1 and hIK-1-like immunoreactivity was detected in a majority of large and small/medium-sized cell bodies of human DRG. hSK1 immunoreactivity was decreased significantly in cell bodies of avulsed human DRG (n = 8, surgery delay 8 h to 12 months). There was a decrease in hIK1-like immunoreactivity predominantly in large cells acutely (<3 weeks after injury), but also in small/medium cells of chronic cases. Twenty-three injured peripheral nerves were studied (surgery delay 8 h to 12 months); in five of these, hIK1-like immunoreactivity was detected proximally but not distally to injury, whereas neurofilament staining confirmed the presence of nerve fibres in both regions. These five nerves, unlike the others, had all undergone Wallerian degeneration previously and the loss of hIK1-like immunoreactivity may therefore reflect reduced axonal transport of this ion channel across the injury site in regenerated fibres, as well as decreased expression in the cell body. In vitro studies of neonatal rat DRG neurones showed that nerve growth factor (NGF) significantly increased the percentage of hSK1-positive cells, whereas neurotrophin 3 (NT-3) and glial cell line-derived neurotrophic factor (GDNF) failed to show a significant effect. NT-3 stimulated hIK1 expression, while NGF and GDNF were ineffective. As expected, NGF increased expression of the voltage-gated sodium channel SNS1/PN3 in this system. Decreased retrograde transport of these neurotrophic factors in injured sensory neurones may thus reduce expression of these ion channels and increase excitability. Blockade of IK1-like and other potassium channels by aminopyridines (4-AP and 3,4-DAP) may also explain the paraesthesiae induced by these medications. Selective potassium channel openers are likely to represent novel therapies for pain following nerve injury.

Gating and conductance properties of BK channels are modulated by the S9-S10 tail domain of the alpha subunit. A study of mSlo1 and mSlo3 wild-type and chimeric channels

The COOH-terminal S9-S10 tail domain of large conductance Ca(2+)-activated K(+) (BK) channels is a major determinant of Ca(2+) sensitivity (Schreiber, M., A. Wei, A. Yuan, J. Gaut, M. Saito, and L. Salkoff. 1999. Nat. Neurosci. 2:416-421). To investigate whether the tail domain also modulates Ca(2+)-independent properties of BK channels, we explored the functional differences between the BK channel mSlo1 and another member of the Slo family, mSlo3 (Schreiber, M., A. Yuan, and L. Salkoff. 1998. J. Biol. Chem. 273:3509-3516). Compared with mSlo1 channels, mSlo3 channels showed little Ca(2+) sensitivity, and the mean open time, burst duration, gaps between bursts, and single-channel conductance of mSlo3 channels were only 32, 22, 41, and 37% of that for mSlo1 channels, respectively. To examine which channel properties arise from the tail domain, we coexpressed the core of mSlo1 with either the tail domain of mSlo1 or the tail domain of mSlo3 channels, and studied the single-channel currents. Replacing the mSlo1 tail with the mSlo3 tail resulted in the following: increased open probability in the absence of Ca(2+); reduced the Ca(2+) sensitivity greatly by allowing only partial activation by Ca(2+) and by reducing the Hill coefficient for Ca(2+) activation; decreased the voltage dependence approximately 28%; decreased the mean open time two- to threefold; decreased the mean burst duration three- to ninefold; decreased the single-channel conductance approximately 14%; decreased the K(d) for block by TEA(i) approximately 30%; did not change the minimal numbers of three to four open and five to seven closed states entered during gating; and did not change the major features of the dependency between adjacent interval durations. These observations support a modular construction of the BK channel in which the tail domain modulates the gating kinetics and conductance properties of the voltage-dependent core domain, in addition to determining most of the high affinity Ca(2+) sensitivity.

Rapidly inactivating and non-inactivating calcium-activated potassium currents in frog saccular hair cells

1. Using a semi-intact epithelial preparation we examined the Ca(2+)-activated K(+) (K(Ca)) currents of frog (Rana pipiens) saccular hair cells. After blocking voltage-dependent K(+) (K(V)) currents with 4-aminopyridine (4-AP) an outward current containing inactivating (I(transient)) and non-inactivating (I(steady)) components remained. 2. The contribution of each varied greatly from cell to cell, with I(transient) contributing from 14 to 90 % of the total outward current. Inactivation of I(transient) was rapid (tau approximately 2-3 ms) and occurred within the physiological range of membrane potentials (V(1/2) = -63 mV). Recovery from inactivation was also rapid (tau approximately 10 ms). 3. Suppression of both I(transient) and I(steady) by depolarizations that approached the Ca(2+) equilibrium potential and by treatments that blocked Ca(2+) influx (application Ca(2+)-free saline or Cd(2+)), suggest both are Ca(2+) dependent. Both were blocked by iberiotoxin, a specific blocker of large-conductance K(Ca) channels (BK), but not by apamin, a specific blocker of small-conductance K(Ca) channels. 4. Ensemble-variance analysis showed that I(transient) and I(steady) flow through two distinct populations of channels, both of which have a large single-channel conductance (~100 pS in non-symmetrical conditions). Together, these data indicate that both I(transient) and I(steady) are carried through BK channels, one of which undergoes rapid inactivation while the other does not. 5. Inactivation of I(transient) could be removed by extracellular papain and could later be restored by intracellular application of the 'ball' domain of the auxiliary subunit (beta2) thought to mediate BK channel inactivation in rat chromaffin cells. We hypothesize that I(transient) results from the association of a similar beta subunit with some of the BK channels and that papain removes inactivation by cleaving extracellular sites required for this association.

Sequential and opposite regulation of two outward K(+) currents by ET-1 in cultured striatal astrocytes

In the brain, astrocytes represent a major target for endothelins (ETs), a family of peptides that can be released by several cell types and that have potent and multiple effects on astrocytic functions. Four types of K(+) currents (I(K)) were detected in various proportions by patch-clamp recordings of cultured striatal astrocytes, including the A-type I(K), the inwardly rectifying I(K IR), the Ca(2+)-dependent I(K) (I(K Ca)), and the delayed-rectified I(K) (I(K DR)). Variations in the shape of current-voltage relationships were related mainly to differences in the proportion of these currents. ET-1 was found to regulate with opposite effects the two more frequently recorded outward K(+) currents in striatal astrocytes. Indeed, this peptide induced an initial activation of I(K Ca) (composed of SK and BK channels) and a delayed long-lasting inhibition of I(K DR). In current-clamp recordings, the activation of I(K Ca) correlated with a transient hyperpolarization, whereas the inhibition of I(K DR) correlated with a sustained depolarization. These ET-1-induced sequential changes in membrane potential in astrocytes may be important for the regulation of voltage gradients in astrocytic networks and the maintenance of K(+) homeostasis in the brain microenvironment.

Glutamate-mediated extrasynaptic inhibition: direct coupling of NMDA receptors to Ca(2+)-activated K+ channels

NMDA receptors (NMDARs) typically contribute to excitatory synaptic transmission in the CNS. While Ca(2+) influx through NMDARs plays a critical role in synaptic plasticity, direct actions of NMDAR-mediated Ca(2+) influx on neuronal excitability have not been well established. Here we show that Ca(2+) influx through NMDARs is directly coupled to activation of BK-type Ca(2+)-activated K+ channels in outside-out membrane patches from rat olfactory bulb granule cells. Repetitive stimulation of glutamatergic synapses in olfactory bulb slices evokes a slow inhibitory postsynaptic current (IPSC) in granule cells that requires both NMDARs and BK channels. The slow IPSC is enhanced by glutamate uptake blockers, suggesting that extrasynaptic NMDARs underlie the response. These findings reveal a novel inhibitory action of extrasynaptic NMDARs in the brain.

Dihydroxyeicosatrienoic acids are potent activators of Ca(2+)-activated K(+) channels in isolated rat coronary arterial myocytes

1. Dihydroxyeicosatrienoic acids (DHETs), which are metabolites of arachidonic acid (AA) and epoxyeicosatrienoic acids (EETs), have been identified as highly potent endogenous vasodilators, but the mechanisms by which DHETs induce relaxation of vascular smooth muscle are unknown. Using inside-out patch clamp techniques, we examined the effects of DHETs on the large conductance Ca(2+)-activated K(+) (BK) channels in smooth muscle cells from rat small coronary arteries (150-300 microM diameter). 2. 11,12-DHET potently activated BK channels with an EC(50) of 1.87 +/- 0.57 nM (n = 5). Moreover, the three other regioisomers 5,6-, 8,9- and 14,15-DHET were equipotent with 11,12-DHET in activating BK channels. The efficacy of 11,12-DHET in opening BK channels was much greater than that of its immediate precursor 11,12-EET. In contrast, AA did not significantly affect BK channel activity. 3. The voltage dependence of BK channels was dramatically modulated by 11,12-DHET. With physiological concentrations of cytoplasmic Ca(2+) (200 nM), the voltage at which the channel open probability was half-maximal (V(1/2)) was shifted from a baseline of 115.6 +/- 6.5 mV to 95.0 +/- 10.1 mV with 5 nM 11,12-DHET, and to 60.0 +/- 8.4 mV with 50 nM 11,12-DHET. 4. 11,12-DHET also enhanced the sensitivity of BK channels to Ca(2+) but did not activate the channels in the absence of Ca(2+). 11,12-DHET (50 nM) reduced the Ca(2+) EC(50) of BK channels from a baseline of 1.02 +/- 0.07 microM to 0.42 +/- 0.11 microM. 5. Single channel kinetic analysis indicated that 11,12-DHET did not alter BK channel conductance but did reduce the first latency of BK channel openings in response to a voltage step. 11,12-DHET dose-dependently increased the open dwell times, abbreviated the closed dwell times, and decreased the transition rates from open to closed states. 6. We conclude that DHETs hyperpolarize vascular smooth muscle cells through modulation of the BK channel gating behaviour, and by enhancing the channel sensitivities to Ca(2+) and voltage. Hence, like EETs, DHETs may function as endothelium-derived hyperpolarizing factors.

Properties of a Ca(2+)-activated large conductance K(+) channel with ATP sensitivity in human renal proximal tubule cells

The properties of a native Ca(2+)-activated large conductance K(+) channel (BK channel) present in the surface membrane of cultured human renal proximal tubule epithelial cells (RPTECs) were investigated by using the patch-clamp technique. The slope conductance of the BK channel was about 295 pS, and the channel was selective to K(+) over Na(+), with a selectivity ratio of about 12.2. The activity of the channel was almost maximally enhanced by 10(-4 )M or more Ca(2+) in the cytoplasmic surface of the patch membrane and was markedly diminished by reducing the cytoplasmic Ca(2+) to 10(-6) M at the membrane potential of about 0 mV. The depolarization of the patch membrane also enhanced the channel activity, and hyperpolarization lowered it. K(+) channel blockers, Ba(2+) (0.1-1 mM), tetraethylammonium (1 mM), and charybdotoxin (100 nM), were effective for the suppression of channel activity. A significant feature of the K(+) channel was that channel activity maintained by 10(-5)-10(-4 )M Ca(2+) in inside-out patches was inhibited by the addition of ATP (1-10 mM) to the bath solution. ATPgammaS, and a nonhydrolyzable ATP analogue, 5'-adenylylimidodiphosphate (AMP-PNP), also had inhibitory effects on channel activity. However, an inhibitor of ATP-sensitive K(+) channels, glibenclamide (0.1 mM), induced no appreciable change in channel activity from both intra- and extracellular sides. These results suggest that besides the common natures of the BK channel family such as regulation by cytoplasmic Ca(2+) and membrane potential, the BK channel in RPTECs is directly inhibited by intracellular ATP independent of phosphorylation processes and sulfonylurea receptor.

Contribution of potential EF hand motifs to the calcium-dependent gating of a mouse brain large conductance, calcium-sensitive K(+) channel

1. The large conductance, calcium-sensitive K(+) channel (BK(Ca) channel) is a unique member of the K(+)-selective ion channel family in that activation is dependent upon both direct calcium binding and membrane depolarization. Calcium binding acts to dynamically shift voltage-dependent gating in a negative or left-ward direction, thereby adjusting channel opening to changes in cellular membrane potential. 2. We hypothesized that the intrinsic calcium-binding site within the BK(Ca) channel alpha subunit may contain an EF hand motif, the most common, naturally occurring calcium binding structure. Following identification of six potential sites, we introduced a single amino acid substitution (D/E to N/Q or A) at the equivalent of the -z position of a bona fide EF hand that would be predicted to lower calcium binding affinity at each of the six sites. 3. Using macroscopic current recordings of wild-type and mutant BK(Ca) channels in excised inside-out membrane patches from HEK 293 cells, we observed that a single point mutation in the C-terminus (Site 6, FLD(923)QD to N), adjacent to the 'calcium bowl' described by Salkoff and colleagues, shifted calcium-sensitive gating right-ward by 50--65 mV over the range of 2--12 microM free calcium, but had little effect on voltage-dependent gating in the absence of calcium. Combining this mutation at Site 6 with a similar mutation at Site 1 (PVD(81)EK to N) in the N-terminus produced a greater shift (70--90 mV) in calcium-sensitive gating over the same range of calcium. We calculated that these combined mutations decreased the apparent calcium binding affinity approximately 11-fold (129.5 microM vs. 11.3 microm) compared to the wild-type channel. 4. We further observed that a bacterially expressed protein encompassing Site 6 of the BK(Ca) channel C-terminus and bovine brain calmodulin were both able to directly bind (45)Ca(2+) following denaturation and polyacrylamide gel electrophoresis (e.g. SDS-PAGE). 5. Our results suggest that two regions within the mammalian BK(Ca) channel alpha subunit, with sequence similarities to an EF hand motif, functionally contribute to the calcium-sensitive gating of this channel.

Gating properties conferred on BK channels by the beta3b auxiliary subunit in the absence of its NH(2)- and COOH termini

Both beta1 and beta2 auxiliary subunits of the BK-type K(+) channel family profoundly regulate the apparent Ca(2)+ sensitivity of BK-type Ca(2)+-activated K(+) channels. Each produces a pronounced leftward shift in the voltage of half-activation (V(0.5)) at a given Ca(2)+ concentration, particularly at Ca(2)+ above 1 microM. In contrast, the rapidly inactivating beta3b auxiliary produces a leftward shift in activation at Ca(2)+ below 1 microM. In the companion work (Lingle, C.J., X.-H. Zeng, J.-P. Ding, and X.-M. Xia. 2001. J. Gen. Physiol. 117:583-605, this issue), we have shown that some of the apparent beta3b-mediated shift in activation at low Ca(2)+ arises from rapid unblocking of inactivated channels, unlike the actions of the beta1 and beta2 subunits. Here, we compare effects of the beta3b subunit that arise from inactivation, per se, versus those that may arise from other functional effects of the subunit. In particular, we examine gating properties of the beta3b subunit and compare it to beta3b constructs lacking either the NH(2)- or COOH terminus or both. The results demonstrate that, although the NH(2) terminus appears to be the primary determinant of the beta3b-mediated shift in V(0.5) at low Ca(2)+, removal of the NH(2) terminus reveals two other interesting aspects of the action of the beta3b subunit. First, the conductance-voltage curves for activation of channels containing the beta3b subunit are best described by a double Boltzmann shape, which is proposed to arise from two independent voltage-dependent activation steps. Second, the presence of the beta3b subunit results in channels that exhibit an anomalous instantaneous outward current rectification that is correlated with a voltage dependence in the time-averaged single-channel current. The two effects appear to be unrelated, but indicative of the variety of ways that interactions between beta and alpha subunits can affect BK channel function. The COOH terminus of the beta3b subunit produces no discernible functional effects.

Contribution of presynaptic calcium-activated potassium currents to transmitter release regulation in cultured Xenopus nerve-muscle synapses

Using Xenopus nerve-muscle co-cultures, we have examined the contribution of calcium-activated potassium (K(Ca)) channels to the regulation of transmitter release evoked by single action potentials. The presynaptic varicosities that form on muscle cells in these cultures were studied directly using patch-clamp recording techniques. In these developing synapses, blockade of K(Ca) channels with iberiotoxin or charybdotoxin decreased transmitter release by an average of 35%. This effect would be expected to be caused by changes in the late phases of action potential repolarization. We hypothesize that these changes are due to a reduction in the driving force for calcium that is normally enhanced by the local hyperpolarization at the active zone caused by potassium current through the K(Ca) channels that co-localize with calcium channels. In support of this hypothesis, we have shown that when action potential waveforms were used as voltage-clamp commands to elicit calcium current in varicosities, peak calcium current was reduced only when these waveforms were broadened beginning when action potential repolarization was 20% complete. In contrast to peak calcium current, total calcium influx was consistently increased following action potential broadening. A model, based on previously reported properties of ion channels, faithfully reproduced predicted effects on action potential repolarization and calcium currents. From these data, we suggest that the large-conductance K(Ca) channels expressed at presynaptic varicosities regulate transmitter release magnitude during single action potentials by altering the rate of action potential repolarization, and thus the magnitude of peak calcium current.

A novel MaxiK splice variant exhibits dominant-negative properties for surface expression

We identified a novel MaxiK alpha subunit splice variant (SV1) from rat myometrium that is also present in brain. SV1 has a 33-amino acid insert in the S1 transmembrane domain that does not alter S1 overall hydrophobicity, but makes the S0-S1 linker longer. SV1 was transfected in HEK293T cells and studied using immunocytochemistry and electrophysiology. In non-permeabilized cells, N-terminal c-Myc- or C-terminal green fluorescent protein-tagged SV1 displayed no surface labeling or currents. The lack of SV1 functional expression was due to endoplasmic reticulum (ER) retention as determined by colabeling experiments with a specific ER marker. To explore the functional role of SV1, we coexpressed SV1 with the alpha (human SLO) and beta1 (KCNMB1) subunits of the MaxiK channel. Coexpression of SV1 inhibited surface expression of alpha and beta1 subunits approximately 80% by trapping them in the ER. This inhibition seems to be specific for MaxiK channel subunits since SV1 was unable to prevent surface expression of the Kv4.3 channel or to interact with green fluorescent protein. These results indicate a dominant-negative role of SV1 in MaxiK channel expression. Moreover, they reveal down-regulation by splice variants as a new mechanism that may contribute to the diverse levels of MaxiK channel expression in non-excitable and excitable cells.

Targeting acute ischemic stroke with a calcium-sensitive opener of maxi-K potassium channels

During ischemic stroke, neurons at risk are exposed to pathologically high levels of intracellular calcium (Ca++), initiating a fatal biochemical cascade. To protect these neurons, we have developed openers of large-conductance, Ca++-activated (maxi-K or BK) potassium channels, thereby augmenting an endogenous mechanism for regulating Ca++ entry and membrane potential. The novel fluoro-oxindoles BMS-204352 and racemic compound 1 are potent, effective and uniquely Ca++-sensitive openers of maxi-K channels. In rat models of permanent large-vessel stroke, BMS-204352 provided significant levels of cortical neuroprotection when administered two hours after the onset of occlusion, but had no effects on blood pressure or cerebral blood flow. This novel approach may restrict Ca++ entry in neurons at risk while having minimal side effects.

Maxi-K potassium channels: form, function, and modulation of a class of endogenous regulators of intracellular calcium

Large-conductance calcium-activated (maxi-K, BK) potassium channels are widely distributed in the brain. Maxi-K channels function as neuronal calcium sensors and contribute to the control of cellular excitability and the regulation of neurotransmitter release. Little is currently known of any significant role of maxi-K channels in the genesis of neurological disease. Recent advances in the molecular biology and pharmacology of these channels have revealed sources of phenotypic variability and demonstrated that they can be successfully modulated by pharmacological agents. A potential role is suggested in the treatment of conditions such as ischemic stroke and cognitive disorders.

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.

Effects of fatty acids on BK channels in GH(3) cells

Ca(2+)-activated K(+) (BK) channels in GH(3) cells are activated by arachidonic acid (AA). Because cytosolic phospholipase A(2) can produce other unsaturated free fatty acids (FFA), we examined the effects of FFA on BK channels in excised patches. Control recordings were made at several holding potentials. The desired FFA was added to the bath solution, and the voltage paradigm was repeated. AA increased the activity of BK channels by 3.6 +/- 1.6-fold. The cis FFA, palmitoleic, oleic, linoleic, linolenic, eicosapentaenoic, and the triple bond analog of AA, eicosatetraynoic acid, all increased BK channel activity, whereas stearic (saturated) or the trans isomers elaidic, linolelaidic, and linolenelaidic had no effect. The cis unsaturated FFA shifted the open probability vs. voltage relationships to the left without a change in slope, suggesting no change in the sensitivity of the voltage sensor. Measurements of membrane fluidity showed no correlation between the change of membrane fluidity and the change in BK channel activation. In addition, AA effects on BK channels were unaffected in the presence of N-acetylcysteine. Arachidonyl-CoA, a membrane impermeable analog of AA, activates channels when applied to the cytosolic surface of excised patches, suggesting an effect of FFAs from the cytosolic surface of BK channels. Our data imply a direct interaction between cis FFA and the BK channel protein.

Intracellular Ca2+ and Cl- channel activation in secretory cells

Molecular and functional evidence indicates that a variety of Ca(2+)-dependent chloride (Cl(Ca)) channels are involved in fluid secretion from secretory epithelial cells in different tissues and species. Most Cl(Ca) channels so far characterized have an I- permeability greater than Cl-, and most are sensitive to 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS). Whole-cell Cl(Ca) currents show outward rectification. Single-channel current voltage relationships are linear with conductances ranging from 2 to 30 pS. Some Cl(Ca) channels are blocked by Ca(2+)-calmodulin-dependent protein kinase (CAMKII) inhibitors. Others, such as the Cl(Ca) channels of parotid and submandibular acinar cells, appear to be directly regulated by Ca2+. In native cells, the Cl(Ca) channels are located on the apical plasma membrane and activated by localized mechanisms of Ca2+ release. This positioning allows the Cl(Ca) channel to respond specifically to localized Ca2+ signals that do not invade other regions of the cell. The Cl(Ca) follows the rising phase of the Ca2+ signal, but in the falling phase hysteresis occurs where the Cl(Ca) current decays more rapidly than the underlying Ca2+. The future elucidation of the identity and mechanisms of regulation of Cl(Ca) channels will be critical to our understanding of stimulus-secretion coupling.

Inhibition of a mammalian large conductance, calcium-sensitive K+ channel by calmodulin-binding peptides

The large conductance, calcium-sensitive K+ channel (BKCa channel) is a voltage-activated ion channel in which direct calcium binding shifts gating to more negative cellular membrane potentials. We hypothesized that the calcium-binding domain of BKCa channels may mimic the role played by calmodulin (CaM) in the activation of calcium-CaM-dependent enzymes, in which a tonic inhibitory constraint is removed on CaM binding. To examine such a hypothesis, we used peptides from the autoregulatory domains of CaM kinase II (CK291-317) and cNOS (the constitutive nitric oxide synthase; cNOS725-747) as probes for the calcium-dependent activation of murine BKCa channels transiently expressed in HEK 293 cells. We found that these CaM-binding peptides produced potent, time-dependent inhibition of mammalian BKCa channel current following voltage-dependent activation. Inhibition was observed in both the presence and the absence of cytosolic free calcium. Similar application of CK291-31 had no effect on either the amplitude or kinetics of voltage-dependent, macroscopic currents recorded from rabbit smooth muscle Kv1.5 potassium channels transiently expressed in HEK 293 cells. Cytosolic application of both CK291-317 and tetraethylammonium (TEA) produced an additive and non-competitive block of BKCa current. This finding suggests that the peptide-binding site is distinct (e.g. outside the pore region of the channel) from that of TEA. Our results are thus consistent with a model in which the BKCa channel's voltage-dependent gating process is under an intramolecular constraint that is relieved upon calcium binding. The intrinsic calcium sensor of the channel may thus interact with an inhibitory domain present in the BKCa channel, and by doing so, remove an inhibitory 'constraint' that permits voltage-dependent gating to occur at more negative potentials.

Role of the beta1 subunit in large-conductance Ca(2+)-activated K(+) channel gating energetics. Mechanisms of enhanced Ca(2+) sensitivity

Over the past few years, it has become clear that an important mechanism by which large-conductance Ca(2+)-activated K(+) channel (BK(Ca)) activity is regulated is the tissue-specific expression of auxiliary beta subunits. The first of these to be identified, beta1, is expressed predominately in smooth muscle and causes dramatic effects, increasing the apparent affinity of the channel for Ca(2+) 10-fold at 0 mV, and shifting the range of voltages over which the channel activates -80 mV at 9.1 microM Ca(2+). With this study, we address the question: which aspects of BK(Ca) gating are altered by beta1 to bring about these effects: Ca(2+) binding, voltage sensing, or the intrinsic energetics of channel opening? The approach we have taken is to express the beta1 subunit together with the BK(Ca) alpha subunit in Xenopus oocytes, and then to compare beta1's steady state effects over a wide range of Ca(2+) concentrations and membrane voltages to those predicted by allosteric models whose parameters have been altered to mimic changes in the aspects of gating listed above. The results of our analysis suggest that much of beta1's steady state effects can be accounted for by a reduction in the intrinsic energy the channel must overcome to open and a decrease in its voltage sensitivity, with little change in the affinity of the channel for Ca(2+) when it is either open or closed. Interestingly, however, the small changes in Ca(2+) binding affinity suggested by our analysis (K(c) 7.4 microM --> 9.6 microM; K(o) = 0.80 microM --> 0.65 microM) do appear to be functionally important. We also show that beta1 affects the mSlo conductance-voltage relation in the essential absence of Ca(2+), shifting it +20 mV and reducing its apparent gating charge 38%, and we develop methods for distinguishing between alterations in Ca(2+) binding and other aspects of BK(Ca) channel gating that may be of general use.

Characterization and gene expression of high conductance calcium-activated potassium channels displaying mechanosensitivity in human odontoblasts

Odontoblasts form a layer of cells responsible for the dentin formation and possibly mediate early stages of sensory processing in teeth. Several classes of ion channels have previously been identified in the odontoblast or pulp cell membrane, and it is suspected that these channels assist in these events. This study was carried out to characterize the K(Ca) channels on odontoblasts fully differentiated in vitro using the patch clamp technique and to investigate the HSLO gene expression encoding the alpha-subunit of these channels on odontoblasts in vivo. In inside-out patches, K(Ca) channels were identified on the basis of their K(+) selectivity, conductance, voltage, and Ca(2+) dependence. In cell-attached patches, these channels were found to be activated by application of a negative pressure as well as an osmotic shock. By reverse transcription-polymerase chain reaction, a probe complementary to K(Ca) alpha-subunit mRNA was constructed and used for in situ hybridization on human dental pulp samples. Transcripts were expressed in the odontoblast layer. The use of antibodies showed that the K(Ca) channels were preferentially detected at the apical pole of the odontoblasts. These channels could be involved in mineralization processes. Their mechanosensitivity suggests that the fluid displacement within dentinal tubules could be transduced into electrical cell signals.

Rectification and rapid activation at low Ca2+ of Ca2+-activated, voltage-dependent BK currents: consequences of rapid inactivation by a novel beta subunit

A family of accessory beta subunits significantly contributes to the functional diversity of large-conductance, Ca(2+)- and voltage-dependent potassium (BK) channels in native cells. Here we describe the functional properties of one variant of the beta subunit family, which confers properties on BK channels totally unlike any that have as yet been observed. Coexpression of this subunit (termed beta3) with Slo alpha subunits results in rectifying outward currents and, at more positive potentials, rapidly inactivating ( approximately 1 msec) currents. The underlying rapid inactivation process results in an increase in the apparent activation rate of macroscopic currents, which is coupled with a shift in the activation range of the currents at low Ca(2+). As a consequence, the currents exhibit more rapid activation at low Ca(2+) relative to any other BK channel subunit combinations that have been examined. In part because of the rapid inactivation process, single channel openings are exceedingly brief. Although variance analysis suggests a conductance in excess of 160 pS, fully resolved single channel openings are not observed. The inactivation process results from a cytosolic N-terminal domain of the beta3 subunit, whereas an extended C-terminal domain does not participate in the inactivation process. Thus, the beta3 subunit appears to use a rapid inactivation mechanism to produce a current with a relatively rapid apparent activation time course at low Ca(2+). The beta3 subunit is a compelling example of how the beta subunit family can finely tune the gating properties of Ca(2+)- and voltage-dependent BK channels.

A novel type of ATP block on a Ca(2+)-activated K(+) channel from bullfrog erythrocytes

Using the patch-clamp technique, we have identified an intermediate conductance Ca(2+)-activated K(+) channel from bullfrog (Rana catesbeiana) erythrocytes and have investigated the regulation of channel activity by cytosolic ATP. The channel was highly selective for K(+) over Na(+), gave a linear I-V relationship with symmetrical 117.5 mM K(+) solutions and had a single-channel conductance of 60 pS. Channel activity was dependent on Ca(2+) concentration (K(1/2) = 600 nM) but voltage-independent. These basic characteristics are similar to those of human and frog erythrocyte Ca(2+)-activated K(+) (Gardos) channels previously reported. However, cytoplasmic application of ATP reduced channel activity with block exhibiting a novel bell-shaped concentration dependence. The channel was inhibited most by approximately 10 microM ATP (P(0) reduced to 5% of control) but less blocked by lower and higher concentrations of ATP. Moreover, the novel type of ATP block did not require Mg(2+), was independent of PKA or PKC, and was mimicked by a nonhydrolyzable ATP analog, AMP-PNP. This suggests that ATP exerts its effect by direct binding to sites on the channel or associated regulatory proteins, but not by phosphorylation of either of these components.

Subthreshold oscillation of the membrane potential in magnocellular neurones of the rat supraoptic nucleus

Electrophysiological properties and ionic basis of subthreshold oscillation of the membrane potential were examined in 104 magnocellular neurones of the rat supraoptic nucleus using intracellular recording techniques in a brain slice preparation. Subthreshold oscillation of the membrane potential occurring in all neurones examined was voltage dependent. Oscillation was initiated 7-12 mV negative to the threshold of fast action potentials. Oscillation was the result of neither excitatory nor inhibitory synaptic activity nor of electric coupling. Frequency analyses revealed a broad band frequency distribution of subthreshold oscillation waves (range 10-70 Hz). The frequency band of 15-33 Hz was observed in neurones depolarized close to the threshold of discharge. Subthreshold oscillation was blocked by TTX (1.25-2.5 microM) as well as by TEA (15 mM). Subthreshold oscillation was not blocked by low Ca(2+)-high Mg(2+) superfusate, CdCl(2), TEA (1-4.5 mM), 4-aminopyridine, apamin, charybdotoxin, iberiotoxin, BaCl(2), carbachol and CsCl. During application of TTX, stronger depolarization induced high-threshold oscillation of the membrane potential at a threshold of about -32 mV. These oscillation waves occurred at a mean frequency of about 35 Hz and were blocked by CdCl(2). Effects of ion channel antagonists suggest that subthreshold oscillation is generated by the interaction of a subthreshold sodium current and a subthreshold potassium current. The generation of high-threshold oscillation during TTX involves a high-threshold calcium current. Subthreshold oscillation of the membrane potential may be important for the inter-neuronal synchronization of discharge and for the amplification of synaptic events.

Tracking presynaptic Ca2+ dynamics during neurotransmitter release with Ca2+-activated K+ channels

Neurotransmitter release during action potentials is thought to require transient, localized [Ca2+]i as high as hundreds of micromolar near presynaptic release sites. Most experimental attempts to characterize the magnitude and time course of these Ca2+ domains involve optical methods that sample large volumes, require washout of endogenous buffers and often affect Ca2+ kinetics and transmitter release. Endogenous calcium-activated potassium (KCa) channels colocalize with presynaptic Ca2+ channels in Xenopus nerve-muscle cultures. We used these channels to quantify the rapid, dynamic changes in [Ca2+]i at active zones during synaptic activity. Confirming Ca2+-domain predictions, these KCa channels revealed [Ca2+]i over 100 microM during synaptic activity and much faster buildup and decay of Ca2+ domains than shown using other techniques.

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.

Ca(2+) channels involved in the generation of the slow afterhyperpolarization in cultured rat hippocampal pyramidal neurons

The advantages of using isolated cells have led us to develop short-term cultures of hippocampal pyramidal cells, which retain many of the properties of cells in acute preparations and in particular the ability to generate afterhyperpolarizations after a train of action potentials. Using perforated-patch recordings, both medium and slow afterhyperpolarization currents (mI(AHP) and sI(AHP), respectively) could be obtained from pyramidal cells that were cultured for 8-15 days. The sI(AHP) demonstrated the kinetics and pharmacologic characteristics reported for pyramidal cells in slices. In addition to confirming the insensitivity to 100 nM apamin and 1 mM TEA, we have shown that the sI(AHP) is also insensitive to 100 nM charybdotoxin but is inhibited by 100 microM D-tubocurarine. Concentrations of nifedipine (10 microM) and nimodipine (3 microM) that maximally inhibit L-type calcium channels reduced the sI(AHP) by 30 and 50%, respectively. However, higher concentrations of nimodipine (10 microM) abolished the sI(AHP), which can be partially explained by an effect on action potentials. Both nifedipine and nimodipine at maximal concentrations were found to reduce the HVA calcium current in freshly dissociated neurons to the same extent. The N-type calcium channel inhibitor, omega-conotoxin GVIA (100 nM), irreversibly inhibited the sI(AHP) by 37%. Together, omega-conotoxin (100 nM) and nifedipine (10 microM) inhibited the sI(AHP) by 70%. 10 microM ryanodine also reduced the sI(AHP) by 30%, suggesting a role for calcium-induced calcium release. It is concluded that activation of the sI(AHP) in cultured hippocampal pyramidal cells is mediated by a rise in intracellular calcium involving multiple pathways and not just entry via L-type calcium channels.

Elevated subsarcolemmal Ca2+ in mdx mouse skeletal muscle fibers detected with Ca2+-activated K+ channels

Duchenne muscular dystrophy results from the lack of dystrophin, a cytoskeletal protein associated with the inner surface membrane, in skeletal muscle. The cellular mechanisms responsible for the progressive skeletal muscle degeneration that characterizes the disease are still debated. One hypothesis suggests that the resting sarcolemmal permeability for Ca(2+) is increased in dystrophic muscle, leading to Ca(2+) accumulation in the cytosol and eventually to protein degradation. However, more recently, this hypothesis was challenged seriously by several groups that did not find any significant increase in the global intracellular Ca(2+) in muscle from mdx mice, an animal model of the human disease. In the present study, using plasma membrane Ca(2+)-activated K(+) channels as subsarcolemmal Ca(2+) probe, we tested the possibility of a Ca(2+) accumulation at the restricted subsarcolemmal level in mdx skeletal muscle fibers. Using the cell-attached configuration of the patch-clamp technique, we demonstrated that the voltage threshold for activation of high conductance Ca(2+)-activated K(+) channels is significantly lower in mdx than in control muscle, suggesting a higher subsarcolemmal [Ca(2+)]. In inside-out patches, we showed that this shift in the voltage threshold for high conductance Ca(2+)-activated K(+) channel activation could correspond to a approximately 3-fold increase in the subsarcolemmal Ca(2+) concentration in mdx muscle. These data favor the hypothesis according to which an increased calcium entry is associated with the absence of dystrophin in mdx skeletal muscle, leading to Ca(2+) overload at the subsarcolemmal level.

Stretch-induced activation of Ca(2+)-activated K(+) channels in mouse skeletal muscle fibers

High-conductance Ca(2+)-activated K(+) (K(Ca)) channels were studied in mouse skeletal muscle fibers using the patch-clamp technique. In inside-out patches, application of negative pressure to the patch induced a dose-dependent and reversible activation of K(Ca) channels. Stretch-induced increase in channel activity was found to be of the same magnitude in the presence and in the absence of Ca(2+) in the pipette. The dose-response relationships between K(Ca) channel activity and intracellular Ca(2+) and between K(Ca) channel activity and membrane potential revealed that voltage and Ca(2+) sensitivity were not altered by membrane stretch. In cell-attached patches, in the presence of high external Ca(2+) concentration, stretch-induced activation was also observed. We conclude that membrane stretch is a potential mode of regulation of skeletal muscle K(Ca) channel activity and could be involved in the regulation of muscle excitability during contraction-relaxation cycles.