Stretch-activated cation channels in human fibroblasts.

Nonconfluent fibroblasts are relatively depolarized when compared with confluent fibroblasts, and transient hyperpolarizations result from a range of external stimuli as well as internal cellular activities. This electrical activity ceases, along with growth and mitogenic activity, when the cells become confluent. A calcium-activated potassium conductance is thought to be responsible for these hyperpolarizations, but in human fibroblasts the large calcium-activated potassium channel is not stretch-activated. We report here the identification of single stretch-activated cation channels in human fibroblasts, using the cell-attached and inside-out patch clamp techniques. The most prominent channel had a conductance of approximately 60 pS (picoSeimens) in 140 mM potassium and was permeable to potassium and sodium. The channel showed significant adaptation of activity when stretch was maintained over a period of several seconds, but a static component persisted for much longer periods. Higher conductance channels were also observed in a few excised patches.     

A new pH-sensitive rectifying potassium channel in mitochondria from the embryonic rat hippocampus

Patch-clamp single-channel studies on mitochondria isolated from embryonic rat hippocampus revealed the presence of two different potassium ion channels: a large-conductance (288±4pS) calcium-activated potassium channel and second potassium channel with outwardly rectifying activity under symmetric conditions (150/150mM KCl). At positive voltages, this channel displayed a conductance of 67.84pS and a strong voltage dependence at holding potentials from -80mV to +80mV. The open probability was higher at positive than at negative voltages. Patch-clamp studies at the mitoplast-attached mode showed that the channel was not sensitive to activators and inhibitors of mitochondrial potassium channels but was regulated by pH. Moreover, we demonstrated that the channel activity was not affected by the application of lidocaine, an inhibitor of two-pore domain potassium channels, or by tertiapin, an inhibitor of inwardly rectifying potassium channels. In summary, based on the single-channel recordings, we characterised for the first time mitochondrial pH-sensitive ion channel that is selective for cations, permeable to potassium ions, displays voltage sensitivity and does not correspond to any previously described potassium ion channels in the inner mitochondrial membrane. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).     

Patch-clamp profile of ion channels in resting murine B lymphocytes

Summary Patch-clamp studies of single ion channel currents in freshly isolated murine B lymphocytes are characterized here according to their respective unitary conductances, ion selectivities, regulatory factors, distributions and kinetic behavior. The most prevalent ion channel in murine B lymphocytes is a large conductance (348 pS) nonselective anion channel. This report characterizes additional conductances including: two chloride channels (40 and 128 pS), a calcium-activated potassium channel (93 pS), and an outwardly rectifying potassium channel which displays two distinct conductances (18 and 30 pS). Like the anion channel, both chloride channels exhibit little activity in the cellattached patch configuration. The kinetic behavior of all of these channels is complex, with variable periods of bursting and flickering activity interspersed between prolonged closed/open intervals (dwell times). It is likely that some of these channels play an important role in the signal transduction of B cell activation.     

Functional analysis of native and recombinant ion channels using a high-capacity nonradioactive rubidium efflux assay.

A nonradioactive cell-based rubidium (Rb(+)) efflux assay for functional analysis of native and recombinant ion channels has been developed. Cells are first loaded with rubidium, a tracer for potassium, and after channel activation, rubidium distribution between intracellular and extracellular space is determined by atomic absorption spectroscopy. The relative amount of rubidium in the cell supernatant is a direct measure of channel activity. The broad utility of the method is demonstrated by analysis of a range of different ion channels. Ligand-gated ion channels like nicotinic acetylcholine receptors and purinergic P2X receptors were studied in native PC-12 cells. Calcium-activated potassium channels were analyzed in native (small-conductance calcium-activated potassium channel, SK(Ca)) as well as recombinant cell lines (large-conductance calcium-activated potassium channel, BK(Ca)). Also recombinant voltage-gated potassium channels (Kv1.1, Kv1.4) were amenable to this functional analysis. The method is particularly useful for identification of ion channel modulators in drug discovery since it allows functional analysis with high capacity.     

Calcium- and voltage-activated potassium channels in human macrophages.

Single calcium-activated potassium channel currents were recorded in intact and excised membrane patches from cultured human macrophages. Channel conductance was 240 pS in symmetrical 145 mM K+ and 130 pS in 5 mM external K+. Lower conductance current fluctuations (40% of the larger channels) with the same reversal potential as the higher conductance channels were noted in some patches. Ion substitution experiments indicated that the channel is permeable to potassium and relatively impermeable to sodium. The frequency of channel opening increased with depolarization and intracellular calcium concentration. At 10(-7) M (Ca++)i, channel activity was evident only at potentials of +40 mV or more depolarized, while at 10(-5) M, channels were open at all voltages tested (-40 to +60 mV). In intact patches, channels were seen at depolarized patch potentials of +50 mV or greater, indicating that the ionized calcium concentration in the macrophage is probably less than 10(-7) M.     

Apamin-sensitive, small-conductance, calcium-activated potassium channels mediate cholinergic inhibition of chick auditory hair cells

Acetylcholine released from efferent neurons in the cochlea causes inhibition of mechanosensory hair cells due to the activation of calcium-dependent potassium channels. Hair cells are known to have large-conductance, “BK”-type potassium channels associated with the afferent synapse, but these channels have different properties than those activated by acetylcholine. Whole-cell (tight-seal) and cell-attached patch-clamp recordings were made from short (outer) hair cells isolated from the chicken basilar papilla (cochlea equivalent). The peptides apamin and charybdotoxin were used to distinguish the calcium-activated potassium channels involved in the acetylcholine response from the BK-type channels associated with the afferent synapse. Differential toxin blockade of these potassium currents provides definitive evidence that ACh activates apamin-sensitive, “SK”-type potassium channels, but does not activate carybdotoxin-sensitive BK channels. This conclusion is supported by tentative identification of small-conductance, calcium-sensitive but voltage-insensitive potassium channels in cell-attached patches. The distinction between these channel types is important for understanding the segregation of opposing afferent and efferent synaptic activity in the hair cell, both of which depend on calcium influx. These different calcium-activated potassium channels serve as sensitive indicators for functionally significant calcium influx in the hair cell. Accepted: 12 August 1999     

Mitochondrial large-conductance potassium channel from Dictyostelium discoideum

In the present study, we describe the existence of a large-conductance calcium-activated potassium (BK_Ca) channel in the mitochondria of Dictyostelium discoideum. A single-channel current was recorded in a reconstituted system, using planar lipid bilayers. The large-conductance potassium channel activity of 258 ± 12 pS was recorded in a 50/150 mM KCl gradient solution. The probability of channel opening (the channel activity) was increased by calcium ions and NS1619 (potassium channel opener) and reduced by iberiotoxin (BK_Ca channel inhibitor). The substances known to modulate BK_Ca channel activity influenced the bioenergetics of D. discoideum mitochondria. In isolated mitochondria, NS1619 and NS11021 stimulated non-phosphorylating respiration and depolarized membrane potential, indicating the channel activation. These effects were blocked by iberiotoxin and paxilline. Moreover, the activation of the channel resulted in attenuation of superoxide formation, but its inhibition had the opposite effect. Immunological analysis with antibodies raised against mammalian BK_Ca channel subunits detected a pore-forming α subunit and auxiliary β subunits of the channel in D. discoideum mitochondria. In conclusion, we show for the first time that mitochondria of D. discoideum, a unicellular ameboid protozoon that facultatively forms multicellular structures, contain a large-conductance calcium-activated potassium channel with electrophysiological, biochemical and molecular properties similar to those of the channels previously described in mammalian and plant mitochondria.     

尼古丁调节大鼠冠状动脉平滑肌细胞大电导钙激活钾通道

目的:研究尼古丁对Wistar大鼠冠状动脉平滑肌大电导钙激活钾通道(BKca)活性的抑制作用及其细胞信号转导机制。方法:8周雄性Wistar大鼠随机分为两组:生理盐水组和尼古丁组;分别予以生理盐水和尼古丁2mg/(kg.d)注射21 d,蛋白酶法分离冠状动脉血管平滑肌细胞,将两组平滑肌细胞分别以对氯苯硫基环腺苷酸(CPT-cAMP,100μmol/L)和佛司可林(forskolin,10μmol/L)干预,单通道膜片钳记录干预前后平滑肌细胞单通道电流的平均开放时间(To)、平均关闭时间(Tc)、平均开放概率(Po)。结果:CPT-cAMP和Forskolin均能显著延长生理盐水组大鼠BKca的平均开放时间,缩短平均关闭时间,增加通道开放概率(P均<0.01)。对尼古丁组BKca的To、Tc、Po均无明显影响。结论:尼古丁促使冠状动脉血管收缩的生理机制是通过抑制cAMP/PKA途径诱导的大电导钙激活钾通道活性增加实现的。     

Single-channel recordings from two types of amiloride-sensitive epithelial Na+ channels

We report here the first evidence in intact epithelial cells of unit conductance events from amiloride-sensitive Na+ channels. The events were observed when patch-clamp recordings were made from the apical surface of cultured epithelial kidney cells (A6). Two types of channels were observed: one with a high selectivity to Na+ and one with relatively low selectivity. The characteristics of the low-selectivity channel are as follows: single-channel conductance ranged between 7 and 10 pS (mean = 8.4 +/- 1.3), the current-voltage (I-V) relationship displayed little if any nonlinearity over a range of +/- 80 mV (with respect to the patch pipette) and the channel Na+/K+ selectivity was approximately 3-4:1. Amiloride, a cationic blocker of the channel, reduced channel mean open time and increased channel mean closed times as the voltage of the cell interior was made more negative. Amiloride induced channel flickering at increased negative potentials (intracellular potential with respect to the patch) but did not alter the single-channel conductance or the I-V relationship from that observed in control patches. The characteristics of the high-selectivity channel are: a single-channel conductance of 1-3 pS (mean = 2.8 +/- 1.2), the current-voltage relationship is markedly nonlinear with a Na+/K+ selectivity greater than 20:1. The mean open and closed times for the two types of channels are quite different, the high-selectivity channel being open only about 10% of the time while the low-selectivity channel is open about 30% of the time.     

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

Embryonic muscle cells of the frog Xenopus laevis were isolated and grown in culture and single-channel recordings of potassium inward rectifier and acetylcholine (ACh) receptor currents were obtained from cell-attached membrane patches. Two classes of inward rectifier channels, which differed in conductance, were apparent. With 140 mM potassium chloride in the electrode, one channel class had a conductance of 28.8 ± 3.4 pS (n = 21), and, much more infrequently, a smaller channel class with a conductance of 8.6 ± 3.6 pS (n = 7) was recorded. Both channel classes had relatively long mean channel open times, which decreased with membrane hyperpolarization. The probability of finding a patch of membrane with an inward rectifier channel was high (66%) and many membrane patches contained more than one inward rectifier channel. The open state probability (with no applied potential) was high for both inward rectifier channel classes so that 70% of the time there was a channel open. Seventy-three percent of the membrane patches with ACh receptor channels (n = 11) also had at least one inward rectifier channel present when the patch electrode contained 0.1 μM ACh. Inward rectifier channels were also found at 71% of the sites of high ACh receptor density (n = 14), which were identified with rhodamine-conjugated α-bungarotoxin. The results indicate that the density of inward rectifier channels in this embryonic skeletal muscle membrane was relatively high and includes sites of membrane that have synaptic specializations. © 1996 John Wiley & Sons, Inc.     

Evidence for cooperativity between nicotinic acetylcholine receptors in patch clamp records

It is often assumed that ion channels in cell membrane patches gate independently. However, in the present study nicotinic receptor patch clamp data obtained in cell-attached mode from embryonic chick myotubes suggest that the distribution of steady-state probabilities for conductance multiples arising from concurrent channel openings may not be binomial. In patches where up to four active channels were observed, the probabilities of two or more concurrent openings were greater than expected, suggesting positive cooperativity. For the case of two active channels, we extended the analysis by assuming that 1) individual receptors (not necessarily identical) could be modeled by a five-state (three closed and two open) continuous-time Markov process with equal agonist binding affinity at two recognition sites, and 2) cooperativity between channels could occur through instantaneous changes in specific transition rates in one channel following a change in conductance state of the neighboring channel. This allowed calculation of open and closed sojourn time density functions for either channel conditional on the neighboring channel being open or closed. Simulation studies of two channel systems, with channels being either independent or cooperative, nonidentical or identical, supported the discriminatory power of the optimization algorithm. The experimental results suggested that individual acetylcholine receptors were kinetically identical and that the open state of one channel increased the probability of opening of its neighbor.     

Drug receptors on single enteric neurons

There are many substances contained within enteric nerves which excite or inhibit other nerves when these substances are applied to single neurons. The actions of these substances and of drugs which mimic these actions is to open or close membrane ion channels. The effects on membrane potential are dependent on the nature of the ions which pass through the channel and whether the channel is opened or closed. In the enteric nervous system, drugs can act at one of three broad classes of receptors: [1] those which are part of an ion channel complex and which open either cation channels or chloride channels, both of which result in membrane depolarization [2] those which open potassium channels resulting in hyperpolarization or [3] those which close potassium channels resulting in depolarization. Receptors which open potassium channels are coupled to the channel via a G-protein while receptors which close potassium channels are coupled to the channel, in some cases, via a cyclic AMP-dependent system while in other cases another second messenger system is involved.     

Single potassium channel of anomalous (inward) rectification in mollusk neurons

Currents passing through individual potassium channels with anomalous (inward) rectification were recorded at the neuronal membrane ofPlanorbarius corneus using the patch clamp technique. These currents could be detected, whether in "right side out" or "inside out" configurations in the presence of 50 mM potassium ions or one of the potassium channel blockers: tetraethylammonium (TEA), barium, or cesium (2–20 mM) on the external side of the membrane. Inward currents were observed in individual channels at potentials more negative than level of potassium equilibrium potential (E_k); conductance of these measured 81±12 pS (n=11). At more positive potentials than E_k, conductance fell to zero. Potassium channels with anomalous (inward) rectification inPlanorbarius corneus resemble equivalent channels in other cells in their kinetics: time scale of the open state may be described by a single exponential function. This would imply that the ionic channel has a single open state. Time scale of the closed state was biexponential, thus indicating the possible existence of two kinetically different nonconducting states of the potassium channel with anomalous (inward) rectification at the neuronal membrane ofPlanorbarius corneus.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 21, No. 1, pp. 31–38, January–February, 1989.     

Dual effect of tamoxifen on arterial KCa channels does not depend on the presence of the beta1 subunit

Tamoxifen has been reported to directly activate large conductance calcium-activated potassium (KCa) channels through the KCa beta1 subunit, suggesting a cardio-protective role of this compound. The present study using knock-out (KO) mice for the KCa channel beta1 subunit was aimed at understanding the molecular mechanisms of the effects of tamoxifen on arterial smooth muscle KCa channels. Single channel studies were conducted in excised patches from cerebral artery myocytes from both wild-type and KO animals. The present data demonstrated that tamoxifen can inhibit arterial KCa channels due to a major decrease in channel open probability (P(o)), a mechanism different from the reduction in single channel amplitude reported previously and also observed in the present work. A tamoxifen-induced decrease in P(o) was present in arterial KCa channels from both wild-type and beta1 KO animals. This inhibition was concentration-dependent and partially reversible with a half-maximal concentration constant IC(50) of 2.6 microm. The effect of tamoxifen was actually dual Single channel kinetic analysis showed that tamoxifen shortens both mean closed time and mean open time; the latter is probably due to an intermediate duration voltage-independent blocking mechanism. Thus, tamoxifen block would predominate when KCa channel P(o) is >0.1-0.2, limiting the maximum P(o), whereas a leftward shift in voltage or Ca(2+) activation curves can be observed for P(o) values lower than those values. This dual effect of tamoxifen appears to be independent of the beta1 subunit. The molecular specificity of tamoxifen, or eventually other xenoestrogen derivatives, for the KCa channel beta1 subunit is uncertain.     

Protein kinase C may regulate resting anion conductance in vascular smooth muscle cells

The blocker of protein kinase C(PKC) activated large-conductance channel(337.1 pS) in cell attached patch mode in cultured vascular smooth muscle cells. The channel showed time-dependent inactivation whose time course became faster as the amplitude of the command potential was increased. These characteristics of large-conductance channel activated by the application of the PKC blocker were very similar to those of voltage-dependent Cl channels in these cells, indicating the channel activated by the drug is Cl channel. Since voltage-dependent Cl channels were reported to be only activated by forming inside-out patch, these findings suggest Cl permeability of vascular smooth muscle cells is at least partially regulated by protein kinase C.     

Single channel recordings from calcium-activated potassium channels in cultured rat muscle

Single channel recordings from cultured rat skeletal muscle have revealed a large conductance (230 pS) channel with a high selectivity for K⁺ over Na⁺. In excised patches of membrane, the probability of channel opening is sensitive to micromolar concentrations of calcium ions at the intracellular surface of the patch. Channel openings appear grouped together into bursts whose duration increases with Ca²⁺ and membrane depolarization. Statistical analysis of the individual open times during each burst showed that there are two distinct open states of similar conductance but dissimilar average lifetimes. These channels might contribute to a macroscopic calcium-activated potassium conductance in rat skeletal muscle and other preparations.     

Ion channels: open at last

Previous X-ray studies of have focused on the closed state of the potassium channel. Now the structure of a calcium-activated bacterial potassium channel has revealed the nature of the channel's open state. This provides a first view at high resolution of ion channel gating.     

Electrostatics of the intracellular vestibule of K+ channels

Previous calculations using continuum electrostatic calculations showed that a fully hydrated monovalent cation is electrostatically stabilized at the center of the cavity of the KcsA potassium channel. Further analysis demonstrated that this cavity stabilization was controlled by a balance between the unfavorable reaction field due to the finite size of the cavity and the favorable electrostatic field arising from the pore helices. In the present study, continuum electrostatic calculations are used to investigate how the stability of an ion in the intracellular vestibular cavity common to known potassium channels is affected as the inner channel gate opens and the cavity becomes larger and contiguous with the intracellular solution. The X-ray structure of the calcium-activated potassium channel MthK, which was crystallized in the open state, is used to construct models of the KcsA channel in the open state. It is found that, as the channel opens, the barrier at the helix bundle crossing decreases to approximately 0 kcal/mol, but that the ion in the cavity is also significantly destabilized. The results are compared and contrasted with additional calculations performed on the KvAP (voltage-activated) and KirBac1.1 (inward rectifier) channels, as well as models of the pore domain of Shaker in the open and closed state. In conclusion, electrostatic factors give rise to energetic constraints on ion permeation that have important functional consequences on the various K+ channels, and partly explain the presence or absence of charged residues near the inner vestibular entry.