An investigation of the occurrence and properties of the mitochondrial intermediate-conductance Ca2+-activated K+ channel mtKCa3.1

The mitochondrial intermediate-conductance Ca²⁺-activated K⁺ channel mtK_Ca3.1 has recently been discovered in the HCT116 colon tumor-derived cell line, which expresses relatively high levels of this protein also in the plasma membrane. Electrophysiological recordings revealed that the channel can exhibit different conductance states and kinetic modes, which we tentatively ascribe to post-translational modifications. To verify whether the localization of this channel in mitochondria might be a peculiarity of these cells or a more widespread feature we have checked for the presence of mtK_Ca3.1 in a few other cell lines using biochemical and electrophysiological approaches. It turned out to be present at least in some of the cells investigated. Functional assays explored the possibility that mtK_Ca3.1 might be involved in cell proliferation or play a role similar to that of the Shaker-type K_V1.3 channel in lymphocytes, which interacts with outer mitochondrial membrane-inserted Bax thereby promoting apoptosis (Szabò, I. et al., Proc. Natl. Acad Sci. USA 105 (2008) 14861–14866). A specific K_Ca3.1 inhibitor however did not have any detectable effect on cell proliferation or death.     

Cytoprotective Channels in Mitochondria

Several ion channels are expressed in the inner and outer membranes of mitochondria, but the exact function of these channels is not completely understood. The opening of certain channels is thought to induce the process of cell death or apoptosis. However, other channels of the inner mitochondrial membrane help protect against ischemic injury and oxidative stress. Mitochondrial ATP-sensitive K⁺ channels (mitoK_ATP) and mitochondrial Ca²⁺-activated K⁺ channels (mitoK_Ca) are the primary protective channels that have been identified. In addition to their thermogenic role, certain isoforms of uncoupling proteins are also shown to have protective roles in certain experimental models. This review attempts to provide an updated overview of the proposed mechanism for the protective function of these membrane proteins. Controversies and unanswered questions regarding these channels will also be discussed.     

Ca2+-activated K+ currents inNecturus choroid plexus

Summary The tight-seal whole-cell recording method has been used to studyNecturus choroid plexus epithelium. A cell potential of –59±2 mV and a whole cell resistance of 56±6 M were measured using this technique. Application of depolarizing step potentials activated voltage-dependent outward currents that developed with time. For example, when the cell was bathed in 110mm NaCl Ringer solution and the interior of the cell contained a solution of 110mm KCl and 5nm Ca²⁺, stepping the membrane potential from a holding value of –50 to –10 mV evoked outward currents which, after a delay of greater than 50 msec, increased to a steady state in 500 msec. The voltage dependence of the delayed currents suggests that they may be currents through Ca²⁺-activated K^_ channels. Based on the voltage dependence of the activation of Ca²⁺-activated K⁺ channels, we have devised a general method to isolate the delayed currents. The delayed currents were highly selective for K⁺ as their reversal potential at different K⁺ concentration gradients followed the Nernst potential for K⁺. These currents were reduced by the addition of TEA⁺ to the bath solution and were eliminated when Cs⁺ or Na⁺ replaced intracellular K⁺. Increasing the membrane potential to more positive values decreased both the delay and the half-times (t _1/2) to the steady value. Increasing the pipette Ca²⁺ also decreased the delay and decreasedt _1/2. For instance, when pipette Ca²⁺ was increased from 5 to 500nm, the delay andt _1/2 decreased from values greater than 50 and 150 msec to values less than 10 and 50 msec. We conclude that the delayed currents are K⁺ currents through Ca²⁺-activated K⁺ channels.At the resting membrane potential of –60 mV, Ca²⁺-activated K⁺ channels contribute between 13 to 25% of the total conductance of the cell. The contribution of these channels to cell conductance nearly doubles with membrane depolarization of 20–30 mV. Such depolarizations have been observed when cerebrospinal fluid (CSF) secretion is stimulated by cAMP and with intracellular Ca²⁺. Thus the Ca²⁺-activated K⁺ channels may play a specific role in maintaining intracellular K⁺ concentrations during CSF secretion.     

Imaging of mitochondrial Ca2+ dynamics in astrocytes using cell-specific mitochondria-targeted GCaMP5G/6s: Mitochondrial Ca2+ uptake and cytosolic Ca2+ availability via the endoplasmic reticulum store

Mitochondrial Ca²⁺ plays a critical physiological role in cellular energy metabolism and signaling, and its overload contributes to various pathological conditions including neuronal apoptotic death in neurological diseases. Live cell mitochondrial Ca²⁺ imaging is an important approach to understand mitochondrial Ca²⁺ dynamics. Recently developed GCaMP genetically-encoded Ca²⁺ indicators provide unique opportunity for high sensitivity/resolution and cell type-specific mitochondrial Ca²⁺ imaging. In the current study, we implemented cell-specific mitochondrial targeting of GCaMP5G/6s (mito-GCaMP5G/6s) and used two-photon microscopy to image astrocytic and neuronal mitochondrial Ca²⁺ dynamics in culture, revealing Ca²⁺ uptake mechanism by these organelles in response to cell stimulation. Using these mitochondrial Ca²⁺ indicators, our results show that mitochondrial Ca²⁺ uptake in individual mitochondria in cultured astrocytes and neurons can be seen after stimulations by ATP and glutamate, respectively. We further studied the dependence of mitochondrial Ca²⁺ dynamics on cytosolic Ca²⁺ changes following ATP stimulation in cultured astrocytes by simultaneously imaging mitochondrial and cytosolic Ca²⁺ increase using mito-GCaMP5G and a synthetic organic Ca²⁺ indicator, x-Rhod-1, respectively. Combined with molecular intervention in Ca²⁺ signaling pathway, our results demonstrated that the mitochondrial Ca²⁺ uptake is tightly coupled with inositol 1,4,5-trisphosphate receptor-mediated Ca²⁺ release from the endoplasmic reticulum and the activation of G protein-coupled receptors. The current study provides a novel approach to image mitochondrial Ca²⁺ dynamics as well as Ca²⁺ interplay between the endoplasmic reticulum and mitochondria, which is relevant for neuronal and astrocytic functions in health and disease.     

Mitochondrial ryanodine receptors and other mitochondrial Ca permeable channels

Ca²⁺ channels that underlie mitochondrial Ca²⁺ transport first reported decades ago have now just recently been precisely characterized electrophysiologically. Numerous data indicate that mitochondrial Ca²⁺ uptake via these channels regulates multiple intracellular processes by shaping cytosolic and mitochondrial Ca²⁺ transients, as well as altering the cellular metabolic and redox state. On the other hand, mitochondrial Ca²⁺ overload also initiates a cascade of events that leads to cell death. Thus, characterization of mitochondrial Ca²⁺ channels is central to a comprehensive understanding of cell signaling. Here, we discuss recent progresses in the biophysical and electrophysiological characterization of several distinct mitochondrial Ca²⁺ channels.     

Intermediate conductance Ca2+-activated potassium channel (KCa3.1) in the inner mitochondrial membrane of human colon cancer cells

Patch–clamping mitoplasts isolated from human colon carcinoma 116 cells has allowed the identification and characterization of the intermediate conductance Ca²⁺-activated K⁺-selective channel K_Ca3.1, previously studied only in the plasma membrane of various cell types. Its identity has been established by its biophysical and pharmacological properties. Its localisation in the inner membrane of mitochondria is indicated by Western blots of subcellular fractions, by recording of its activity in mitochondria made fluorescent by a mitochondria-targeted fluorescent protein and by the co-presence of channels considered to be markers of the inner membrane. Moderate increases of mitochondrial matrix [Ca²⁺] will cause mtK_Ca3.1 opening, thus linking inner membrane K⁺ permeability and transmembrane potential to Ca²⁺ signalling.     

Time and charge/pH-dependent activation of K+ channel-mediated K+ influx and K+/H+ exchange in guinea pig heart isolated mitochondria; role in bioenergetic stability

Mitochondria play an important role not only in producing energy for the cell but also for regulating mitochondrial and cell function depending on the cell's needs and environment. Uptake of cations, anions, and substrates requires a stable, polarized transmembrane charge potential (ΔΨ_m). Chemiosmosis requires ion exchangers to remove Na⁺, K⁺, Ca²⁺, PO₄^3?, and other charged species that enter mitochondria. Knowledge of the kinetics of mitochondrial (m) cation channels and exchangers is important in understanding their roles in regulating mitochondrial chemiosmosis and bioenergetics. The influx/efflux of K⁺, the most abundant mitochondrial cation, alters mitochondrial volume and shape by bringing in anions and H₂O by osmosis. The effects of K⁺ uptake through ligand-specific mK⁺ channels stimulated/inhibited by agonists/antagonists on mitochondrial volume (swelling/contraction) are well known. However, a more important role for K⁺ influx is likely its effects on H⁺ cycling and bioenergetics facilitated by mitochondrial (m) K⁺/H⁺ exchange (mKHE), though the kinetics and consequences of K⁺ efflux by KHE are not well described. We hypothesized that a major role of K⁺ influx/efflux is stimulation of respiration via the influx of H⁺ by KHE. We proposed to modulate KHE activity by energizing guinea pig heart isolated mitochondria and by altering the mK⁺ cycle to capture changes in mitochondrial volume, pH_m, ΔΨ_m, and respiration that would reflect a role for H⁺ influx via KHE to regulate bioenergetics. To test this, mitochondria were suspended in a 150 mM K⁺ buffer at pH 6.9, or in a 140 mM Cs⁺ buffer at pH 7.6 or 6.9 with added 10 mM K⁺, minimal Ca²⁺ and free of Na⁺. O₂ content was measured by a Clark electrode, and pH_m, ΔΨ_m, and volume, were measured by fluorescence spectrophotometry and light-scattering. Adding pyruvic acid (PA) alone caused increases in volume and respiration and a rapid decrease in the transmembrane pH gradient (ΔpH_m = pH_in–pH_ext) at pH_ext 6.9> > 7.6, so that ΔΨ_m was charged and maintained. BK_Ca agonist NS1619 and antagonist paxilline modified these effects, and KHE inhibitor quinine and K⁺ ionophore valinomycin depolarized ΔΨ_m. We postulate that K⁺ efflux-induced H⁺ influx via KHE causes an inward H⁺ leak that stimulates respiration, but at buffer pH 6.9 also utilizes the energy of ΔpH_m, the smaller component of the overall proton motive force, ΔμH⁺. Thus ΔpH_m establishes and maintains the ΔΨ_m required for utilization of substrates, entry of all cations, and for oxidative phosphorylation. Thus, K⁺ influx/efflux appears to play a pivotal role in regulating energetics while maintaining mitochondrial ionic balance and volume homeostasis.     

Ca2+ and K+ channels of normal human adrenal zona fasciculata cells: Properties and modulation by ACTH and AngII

In whole cell patch clamp recordings, we found that normal human adrenal zona fasciculata (AZF) cells express voltage-gated, rapidly inactivating Ca²⁺ and K⁺ currents and a noninactivating, leak-type K⁺ current. Characterization of these currents with respect to voltage-dependent gating and kinetic properties, pharmacology, and modulation by the peptide hormones adrenocorticotropic hormone (ACTH) and AngII, in conjunction with Northern blot analysis, identified these channels as Ca_v3.2 (encoded by CACNA1H), Kv1.4 (KCNA4), and TREK-1 (KCNK2). In particular, the low voltage–activated, rapidly inactivating and slowly deactivating Ca²⁺ current (Ca_v3.2) was potently blocked by Ni²⁺ with an IC₅₀ of 3 µM. The voltage-gated, rapidly inactivating K⁺ current (Kv1.4) was robustly expressed in nearly every cell, with a current density of 95.0 ± 7.2 pA/pF (n = 64). The noninactivating, outwardly rectifying K⁺ current (TREK-1) grew to a stable maximum over a period of minutes when recording at a holding potential of −80 mV. This noninactivating K⁺ current was markedly activated by cinnamyl 1-3,4-dihydroxy-α-cyanocinnamate (CDC) and arachidonic acid (AA) and inhibited almost completely by forskolin, properties which are specific to TREK-1 among the K2P family of K⁺ channels. The activation of TREK-1 by AA and inhibition by forskolin were closely linked to membrane hyperpolarization and depolarization, respectively. ACTH and AngII selectively inhibited the noninactivating K⁺ current in human AZF cells at concentrations that stimulated cortisol secretion. Accordingly, mibefradil and CDC at concentrations that, respectively, blocked Ca_v3.2 and activated TREK-1, each inhibited both ACTH- and AngII-stimulated cortisol secretion. These results characterize the major Ca²⁺ and K⁺ channels expressed by normal human AZF cells and identify TREK-1 as the primary leak-type channel involved in establishing the membrane potential. These findings also suggest a model for cortisol secretion in human AZF cells wherein ACTH and AngII receptor activation is coupled to membrane depolarization and the activation of Ca_v3.2 channels through inhibition of hTREK-1.     

Role of Voltage-Gated K+ (KV) Channels in Vascular Function

Voltage-dependent K⁺ (K_V) channels represent the most diverse group of K⁺ channels ubiquitously expressed in vascular smooth muscles. The K_V channels, together with other types of K⁺ conductances, such as Ca²⁺-activated (BK_Ca), ATP-sensitive (K_ATP), and inward rectifier, play an important role in the control of the cell membrane potential and regulation of the vascular contractility. Comparison of the expression of different K_V channel isoforms obtained from RT-PCR studies showed that virtually all K_V genes could be detected in vascular smooth muscle cells (VSMC). Based on the analysis of both mRNA and protein expressions, it is likely that K_V1.1, K_V1.2, K_V1.3, K_V1.5, K_V1.6, K_V2.1, and K_V3.1b channel isoforms are mainly responsible for the delayed rectifier current characterized electrophysiologically in most VSMC types studied to date. It has been recently demonstrated by our research group and by others that functional expression of multiple K_V channel α-subunits is not homogeneous and varies in different vascular beds of small and large arteries. Growing evidence suggests that in some small arteries, e.g., cerebral arteries and arterioles, the K_V channels are activated at more negative membrane voltages than BK_Ca, thus making a greater contribution to the control of vascular tone. Our data also suggest that in some blood vessels, such as the rat aorta and mouse small mesenteric arteries, the K_V channel current (identified mainly as passed through K_V2.1 channels), but not BK_Ca, is the predominant conductance activated even under conditions where intracellular Ca₂₊ concentration is increased up to 200 nM. In addition, our data indicate that the K_V2.1 channel current could also contribute to the regulation of the induced rhythmic activity in the rat aorta in vitro acting as a negative feedback mechanism for membrane depolarization. We and other experimenters also demonstrated that functional expression of K_V channels is a dynamic process, which is altered under normal physiological conditions (e.g., during the development of the vessels), and in various pathological states (e.g., pulmonary hypertension developing during chronic hypoxia). Recent findings also suggest that activation of K_V channels can also play a role in vascular apoptosis (causing loss of intracellular K⁺ and subsequent cell shrinking, one of the essential prerequisites of cellular apoptosis). To summarize, the K^V channels are essential for normal vascular function, and their expression and properties are altered under abnormal conditions. Therefore, understanding of the molecular identity of native K_V channels and their functional significance and elucidation of the mechanisms, which govern and control the expression of the K_V channels in the vasculature, represent an important and challenging task and could also lead to the development of useful therapeutic strategies for the treatment of cardiovascular diseases.     

Cardiotoxicity of calmidazolium chloride is attributed to calcium aggravation, oxidative and nitrosative stress, and apoptosis

The intracellular calcium concentration ([Ca]_i) regulates cell viability and contractility in myocardial cells. Elevation of the [Ca]_i level occurs by entry of calcium ions (Ca²⁺) through voltage-dependent Ca²⁺ channels in the plasma membrane and release of Ca²⁺ from the sarcoplasmic reticulum. Calmidazolium chloride (CMZ), a subgroup II calmodulin antagonist, blocks L-type calcium channels as well as voltage-dependent Na⁺ and K⁺ channel currents. This study elaborates on the events that contribute to the cytotoxic effects of CMZ on the heart. We hypothesized that apoptotic cell death occurs in the cardiac cells through calcium accumulation, production of reactive oxygen species, and the cytochrome c-mediated PARP activation pathway. CMZ significantly increased the production of superoxide (O₂^•–) and nitric oxide (NO) as detected by FACS and confocal microscopy. CMZ induced mitochondrial damage by increasing the levels of intracellular calcium, lowering the mitochondrial membrane potential, and thereby inducing cytochrome c release. Apoptotic cell death was observed in H9c2 cells exposed to 25 μM CMZ for 24 h. This is the first report that elaborates on the mechanism of CMZ-induced cardiotoxicity. CMZ causes apoptosis by decreasing mitochondrial activity and contractility indices and increasing oxidative and nitrosative stress, ultimately leading to cell death via an intrinsic apoptotic pathway.     

Inhibitors of the mitochondrial calcium uniporter for the treatment of disease

The mitochondrial calcium uniporter (MCU) is a protein located in the inner mitochondrial membrane that is responsible for mitochondrial Ca²⁺ uptake. Under certain pathological conditions, dysregulation of Ca²⁺ uptake through the MCU results in cellular dysfunction and apoptotic cell death. Given the role of the MCU in human disease, researchers have developed compounds capable of inhibiting mitochondrial calcium uptake as tools for understanding the role of this protein in cell death. In this article, we describe recent findings on the role of the MCU in mediating pathological conditions and the search for small-molecule inhibitors of this protein for potential therapeutic applications.     

Ion Channels in Cell Proliferation and Apoptotic Cell Death

Cell proliferation and apoptosis are paralleled by altered regulation of ion channels that play an active part in the signaling of those fundamental cellular mechanisms. Cell proliferation must - at some time point - increase cell volume and apoptosis is typically paralleled by cell shrinkage. Cell volume changes require the participation of ion transport across the cell membrane, including appropriate activity of Cl⁻ and K⁺ channels. Besides regulating cytosolic Cl⁻ activity, osmolyte flux and, thus, cell volume, most Cl⁻ channels allow HCO₃⁻ exit and cytosolic acidification, which inhibits cell proliferation and favors apoptosis. K⁺ exit through K⁺ channels may decrease intracellular K⁺ concentration, which in turn favors apoptotic cell death. K⁺ channel activity further maintains the cell membrane potential, a critical determinant of Ca²⁺ entry through Ca²⁺ channels. Cytosolic Ca²⁺ may trigger mechanisms required for cell proliferation and stimulate enzymes executing apoptosis. The switch between cell proliferation and apoptosis apparently depends on the magnitude and temporal organization of Ca²⁺ entry and on the functional state of the cell. Due to complex interaction with other signaling pathways, a given ion channel may play a dual role in both cell proliferation and apoptosis. Thus, specific ion channel blockers may abrogate both fundamental cellular mechanisms, depending on cell type, regulatory environment and condition of the cell. Clearly, considerable further experimental effort is required to fully understand the complex interplay between ion channels, cell proliferation and apoptosis.     

Synaptic NMDA Receptor-Dependent Ca2+ Entry Drives Membrane Potential and Ca2+ Oscillations in Spinal Ventral Horn Neurons

During vertebrate locomotion, spinal neurons act as oscillators when initiated by glutamate release from descending systems. Activation of NMDA receptors initiates Ca²⁺-mediated intrinsic membrane potential oscillations in central pattern generator (CPG) neurons. NMDA receptor-dependent intrinsic oscillations require Ca²⁺-dependent K⁺ (K_Ca2) channels for burst termination. However, the location of Ca²⁺ entry mediating K_Ca2 channel activation, and type of Ca²⁺ channel – which includes NMDA receptors and voltage-gated Ca²⁺ channels (VGCCs) – remains elusive. NMDA receptor-dependent Ca²⁺ entry necessitates presynaptic release of glutamate, implying a location at active synapses within dendrites, whereas VGCC-dependent Ca²⁺ entry is not similarly constrained. Where Ca²⁺ enters relative to K_Ca2 channels is crucial to information processing of synaptic inputs necessary to coordinate locomotion. We demonstrate that Ca²⁺ permeating NMDA receptors is the dominant source of Ca²⁺ during NMDA-dependent oscillations in lamprey spinal neurons. This Ca²⁺ entry is synaptically located, NMDA receptor-dependent, and sufficient to activate K_Ca2 channels at excitatory interneuron synapses onto other CPG neurons. Selective blockade of VGCCs reduces whole-cell Ca²⁺ entry but leaves membrane potential and Ca²⁺ oscillations unaffected. Furthermore, repetitive oscillations are prevented by fast, but not slow, Ca²⁺ chelation. Taken together, these results demonstrate that K_Ca2 channels are closely located to NMDA receptor-dependent Ca²⁺ entry. The close spatial relationship between NMDA receptors and K_Ca2 channels provides an intrinsic mechanism whereby synaptic excitation both excites and subsequently inhibits ventral horn neurons of the spinal motor system. This places the components necessary for oscillation generation, and hence locomotion, at glutamatergic synapses.     

Ca2+ activation and pH dependence of a maxi K+ channel from rabbit distal colon epithelium

To determine if their properties are consistent with a role in regulation of transepithelial transport, Ca²⁺-activated K⁺ channels from the basolateral plasma membrane of the surface cells in the distal colon have been characterized by single channel analysis after fusion of vesicles with planar lipid bilayers. A Ca²⁺-activated K⁺ channel with a single channel conductance of 275 pS was predominant. The sensitivity to Ca²⁺ was strongly dependent on the membrane potential and on the pH. At a neutral pH, the K _0.5 for Ca²⁺ was raised from 20nm at a potential of 0 mV to 300nm at –40 mV. A decrease in pH at the cytoplasmic face of the K⁺ channel reduced the Ca²⁺ sensitivity dramatically. A loss of the high sensitivity to Ca²⁺ was also observed after incubation with MgCl₂, possibly a result of dephosphorylation of the channels by endogenous phosphatases. Modification of the channel protein may thus explain the variation in Ca²⁺ sensitivity between studies on K⁺ channels from the same tissue. High affinity inhibition (K _0.5=10nm) by charybdotoxin of the Ca²⁺-activated K⁺ channel from the extracellular face could be lifted by an outward flux of K⁺ through the channel. However, at the ion gradients and potentials found in the intact epithelium, charybdotoxin should be a useful tool for examination of the role of maxi K⁺ channels. The high sensitivity for Ca²⁺ and the properties of the activator site are in agreement with an important regulatory role for the high conductance K⁺ channel in the epithelial cells.Dr. E. Moczydlowsky, Yale University School of Medicine, New Haven, CT, and Dr. Per Stampe, Brandeis University, Waltham, MA, are thanked for introduction to the bilayer technique. Tove Soland is thanked for excellent technical assistance. This work was supported by the Novo Nordisk Foundation, the Carlsberg Foundation, the Danish Medical Research Council, and the Austrian Research Council.     

Switch of voltage-gated K+ channel expression in the plasma membrane of chondrogenic cells affects cytosolic Ca2+-oscillations and cartilage formation

Background

Understanding the key elements of signaling of chondroprogenitor cells at the earliest steps of differentiation may substantially improve our opportunities for the application of mesenchymal stem cells in cartilage tissue engineering, which is a promising approach of regenerative therapy of joint diseases. Ion channels, membrane potential and Ca²⁺-signaling are important regulators of cell proliferation and differentiation. Our aim was to identify such plasma membrane ion channels involved in signaling during chondrogenesis, which may serve as specific molecular targets for influencing chondrogenic differentiation and ultimately cartilage formation.

Methodology/Principal Findings

Using patch-clamp, RT-PCR and Western-blot experiments, we found that chondrogenic cells in primary micromass cell cultures obtained from embryonic chicken limb buds expressed voltage-gated Na_V1.4, K_V1.1, K_V1.3 and K_V4.1 channels, although K_V1.3 was not detectable in the plasma membrane. Tetrodotoxin (TTX), the inhibitor of Na_V1.4 channels, had no effect on cartilage formation. In contrast, presence of 20 mM of the K⁺ channel blocker tetraethyl-ammonium (TEA) during the time-window of the final commitment of chondrogenic cells reduced K_V currents (to 27±3% of control), cell proliferation (thymidine incorporation: to 39±4.4% of control), expression of cartilage-specific genes and consequently, cartilage formation (metachromasia: to 18.0±6.4% of control) and also depolarized the membrane potential (by 9.3±2.1 mV). High-frequency Ca²⁺-oscillations were also suppressed by 10 mM TEA (confocal microscopy: frequency to 8.5±2.6% of the control). Peak expression of TEA-sensitive K_V1.1 in the plasma membrane overlapped with this period. Application of TEA to differentiated chondrocytes, mainly expressing the TEA-insensitive K_V4.1 did not affect cartilage formation.

Conclusions/Significance

These data demonstrate that the differentiation and proliferation of chondrogenic cells depend on rapid Ca²⁺-oscillations, which are modulated by K_V-driven membrane potential changes. K_V1.1 function seems especially critical during the final commitment period. We show the critical role of voltage-gated cation channels in the differentiation of non-excitable cells with potential therapeutic use.     

Interactions of K+ ATP channel blockers with Na+/K+-ATPase

Two K⁺ _ATP channel blockers, 5-hydroxydecanoate (5-HD) and glyburide, are often used to study cross-talk between Na⁺/K⁺-ATPase and these channels. The aim of this work was to characterize the effects of these blockers on purified Na⁺/K⁺-ATPase as an aid to appropriate use of these drugs in studies on this cross-talk. In contrast to known dual effects (activating and inhibitory) of other fatty acids on Na⁺/K⁺-ATPase, 5-HD only inhibited the enzyme at concentrations exceeding those that block mitochondrial K⁺ _ATP channels. 5-HD did not affect the ouabain sensitivity of Na⁺/K⁺-ATPase. Glyburide had both activating and inhibitory effects on Na⁺/K⁺-ATPase at concentrations used to block plasma membrane K⁺ _ATP channels. The findings justify the use of 5-HD as specific mitochondrial channel blocker in studies on the relation of this channel to Na⁺/K⁺-ATPase, but question the use of glyburide as a specific blocker of plasma membrane K⁺ _ATP channels, when the relation of this channel to Na⁺/K⁺-ATPase is being studied.     

Exercise training changes the gating properties of large-conductance Ca2+-activated K+ channels in rat thoracic aorta smooth muscle cells

Large-conductance Ca²⁺-activated K⁺ (BK_Ca) channels play a critical role in regulating the cellular excitability in response to change in blood flow. It has been demonstrated that vascular BK_Ca channel currents in both humans and rats are increased after exercise training. This up-regulation of the BK_Ca channel activity in arterial myocytes may represent a cellular compensatory mechanism of limiting vascular reactivity to exercise training. However, the underlying mechanisms are not fully understood. In the present study, we examined the single channel activities and kinetics of the BK_Ca channels in rat thoracic aorta smooth muscle cells. We showed that exercise training significantly increased the open probability (Po), decreased the mean closed time and increased the mean open time, and the sensitivity to Ca²⁺ and voltage without altering the unitary conductance and the K⁺ selectivity. Our results suggest a novel mechanism by which exercise training increases the K⁺ currents by changing the BK_Ca channel activities and kinetics.     

Permeation of Ca2+ through K+ channels in the plasma membrane of Vicia faba guard cells

Summary The whole-cell patch-clamp method has been used to measure Ca²⁺ influx through otherwise K⁺-selective channels in the plasma membrane surrounding protoplasts from guard cells of Vicia faba. These channels are activated by membrane hyperpolarization. The resulting K⁺ influx contributes to the increase in guard cell turgor which causes stomatal opening during the regulation of leaf-air gas exchange. We find that after opening the K⁺ channels by hyperpolarization, depolarization of the membrane results in tail current at voltages where there is no electrochemical force to drive K⁺ inward through the channels. Tail current remains when the reversal potential for permeant ions other than Ca²⁺ is more negative than or equal to the K⁺ equilibrium potential (–47 mV), indicating that the current is due to Ca²⁺ influx through the K⁺ channels prior to their closure. Decreasing internal [Ca²⁺] (Ca _i ) from 200 to 2 nm or increasing the external [Ca²⁺] (Ca _o ) from 1 to 10 mm increases the amplitude of tail current and shifts the observed reversal potential to more positive values. Such increases in the electrochemical force driving Ca²⁺ influx also decrease the amplitude of time-activated current, indicating that Ca²⁺ permeation is slower than K⁺ permeation, and so causes a partial block. Increasing Ca _o also (i) causes a positive shift in the voltage dependence of current, presumably by decreasing the membrane surface potential, and (ii) results in a U-shaped current-voltage relationship with peak inward current ca. –160 mV, indicating that the Ca^2– block is voltage dependent and suggesting that the cation binding site is within the electric field of the membrane. K⁺ channels in Zea mays guard cells also appear to have a Ca _i -, and Ca _o -dependent ability to mediate Ca²⁺ influx. We suggest that the inwardly rectiying K⁺ channels are part of a regulatory mechanism for Ca _i . Changes in Ca _o and (associated) changes in Ca _i regulate a variety of intracellular processes and ion fluxes, including the K⁺ and anion fluxes associated with stomatal aperture change.This work was supported by grants to S.M.A. from NSF (DCB-8904041) and from the McKnight Foundation. K.F.-G. is a Charles Gilbert Heydon Travelling Fellow. The authors thank Dr. R. MacKinnon (Harvard Medical School) and two anonymous reviewers for helpful comments.