Diadenosine tetraphosphate-gating of recombinant pancreatic ATP-sensitive K(+) channels

Diadenosine tetraphosphate (Ap4A) has been recently discovered in the pancreatic cells where targets ATP-sensitive K⁺ (K_ATP) channels, depolarizes the cell membrane and induces insulin secretion. However, whether Ap4A inhibit pancreatic K_ATP channels by targeting protein channel complex itself was unknown. Therefore, we coexpressed pancreatic KATP channel subunits, Kir6.2 and SUR1, in COS-7 cells and examined the effect of Ap4A on the single channel behavior using the inside-out configuration of the patch-clamp technique. Ap4A inhibited channel opening in a concentration-dependent manner. Analysis of single channels demonstrated that Ap4A did not change intraburst kinetic behavior of K_ATP channels, but rather decreased burst duration and increased between-burst duration. It is concluded that Ap4A antagonizes K_ATP channel opening by targeting channel subunits themselves and by keeping channels longer in closed interburst states.     

Phosphoinositides decrease ATP sensitivity of the cardiac ATP-sensitive K(+) channel. A molecular probe for the mechanism of ATP-sensitive inhibition.

Anionic phospholipids modulate the activity of inwardly rectifying potassium channels (Fan, Z., and J.C. Makielski. 1997. J. Biol. Chem. 272:5388-5395). The effect of phosphoinositides on adenosine triphosphate (ATP) inhibition of ATP-sensitive potassium channel (K(ATP)) currents was investigated using the inside-out patch clamp technique in cardiac myocytes and in COS-1 cells in which the cardiac isoform of the sulfonylurea receptor, SUR2, was coexpressed with the inwardly rectifying channel Kir6.2. Phosphoinositides (1 mg/ml) increased the open probability of K(ATP) in low [ATP] (1 microM) within 30 s. Phosphoinositides desensitized ATP inhibition with a longer onset period (>3 min), activating channels inhibited by ATP (1 mM). Phosphoinositides treatment for 10 min shifted the half-inhibitory [ATP] (K(i)) from 35 microM to 16 mM. At the single-channel level, increased [ATP] caused a shorter mean open time and a longer mean closed time. Phosphoinositides prolonged the mean open time, shortened the mean closed time, and weakened the [ATP] dependence of these parameters resulting in a higher open probability at any given [ATP]. The apparent rate constants for ATP binding were estimated to be 0.8 and 0.02 mM(-1) ms(-1) before and after 5-min treatment with phosphoinositides, which corresponds to a K(i) of 35 microM and 5.8 mM, respectively. Phosphoinositides failed to desensitize adenosine inhibition of K(ATP). In the presence of SUR2, phosphoinositides attenuated MgATP antagonism of ATP inhibition. Kir6.2DeltaC35, a truncated Kir6.2 that functions without SUR2, also exhibited phosphoinositide desensitization of ATP inhibition. These data suggest that (a) phosphoinositides strongly compete with ATP at a binding site residing on Kir6.2; (b) electrostatic interaction is a characteristic property of this competition; and (c) in conjunction with SUR2, phosphoinositides render additional, complex effects on ATP inhibition. We propose a model of the ATP binding site involving positively charged residues on the COOH-terminus of Kir6.2, with which phosphoinositides interact to desensitize ATP inhibition.     

Identification of two types of ATP-sensitive K+ channels in rat ventricular myocytes

The ATP-sensitive K(+) (K(ATP)) channels are known to provide a functional linkage between the electrical activity of the cell membrane and metabolism. Two types of inwardly rectifying K(+) channel subunits (i.e., Kir6.1 and Kir6.2) with which sulfonylurea receptors are associated were reported to constitute the K(ATP) channels. In this study, we provide evidence to show two types of K(ATP) channels with different biophysical properties functionally expressed in isolated rat ventricular myocytes. Using patch-clamp technique, we found that single-channel conductance for the different two types of K(ATP) channels in these cells was 57 and 21 pS. The kinetic properties, including mean open time and bursting kinetics, did not differ between these two types of K(ATP) channels. Diazoxide only activated the small-conductance K(ATP) channel, while pinacidil and dinitrophenol stimulated both channels. Both of these K(ATP) channels were sensitive to block by glibenclamide. Additionally, western blotting, immunochemistry, and RT-PCR revealed two types of Kir6.X channels, i.e., Kir6.1 and Kir6.2, in rat ventricular myocytes. Single-cell Ca(2+) imaging also revealed that similar to dinitrophenol, diazoxide reduced the concentration of intracellular Ca(2+). The present results suggest that these two types of K(ATP) channels may functionally be related to the activity of heart cells.     

Diclofenac-induced peripheral antinociception is associated with ATP-sensitive K+ channels activation

In order to investigate to the contribution of K+ channels on the peripheral antinociception induced by diclofenac, we evaluated the effect of several K+ channel blockers, using the rat paw pressure test, in which sensitivity is increased by intraplantar injection (2 microg) of prostaglandin E2. Diclofenac administered locally into the right hindpaw (25, 50, 100 and 200 microg) elicited a dose-dependent antinociceptive effect which was demonstrated to be local, since only higher doses produced an effect when injected in the contralateral paw. This blockade of PGE2 mechanical hyperalgesia induced by diclofenac (100 microg/paw) was antagonized in a dose-dependent manner by intraplantar administration of the sulphonylureas glibenclamide (40, 80 and 160 microg) and tolbutamide (80, 160 and 320 microg), specific blockers of ATP-sensitive K+ channels, and it was observed even when the hyperalgesic agent used was carrageenin, while the antinociceptive action of indomethacin (200 microg/paw), a typical cyclo-oxygenase inhibitor, over carrageenin-induced hyperalgesia was not affected by this treatment. Charybdotoxin (2 microg/paw), a blocker of large conductance Ca2+-activated K+ channels and dequalinium (50 microg/paw), a selective blocker of small conductance Ca2+-activated K+ channels, did not modify the effect of diclofenac. This effect was also unaffected by intraplantar administration of non-specific voltage-dependent K+ channel blockers tetraethylammonium (1700 microg) and 4-aminopyridine (100 microg) or cesium (500 microg), a non-specific K+ channel blocker. The peripheral antinociceptive effect induced by diclofenac was antagonized by NG-Nitro L-arginine (NOarg, 50 microg/paw), a NO synthase inhibitor and methylene blue (MB, 500 microg/paw), a guanylate cyclase inhibitor, and this antagonism was reversed by diazoxide (300 microg/paw), an ATP-sensitive K+ channel opener. We also suggest that an endogenous opioid system may not be involved since naloxone (50 microg/paw) did not affect diclofenac-induced antinociception in the PGE2-induced hyperalgesia model. This study provides evidence that the peripheral antinociceptive effect of diclofenac may result from activation of ATP-sensitive K+ channels, possible involving stimulation of L-arginine/NO/cGMP pathway, while Ca2+-activated K+ channels, voltage-dependent K+ channels as well as endogenous opioids appear not to be involved in the process.     

The C. elegans mitochondrial K+(ATP) channel: a potential target for preconditioning

Ischemic preconditioning (IPC) is an evolutionarily conserved endogenous mechanism whereby short periods of non-lethal exposure to hypoxia alleviate damage caused by subsequent ischemia reperfusion (IR). Pharmacologic targeting has suggested that the mitochondrial ATP-sensitive potassium channel (mK_ATP) is central to IPC signaling, despite its lack of molecular identity. Here, we report that isolated Caenorhabditis elegans mitochondria have a K_ATP channel with the same physiologic and pharmacologic characteristics as the vertebrate channel. Since C. elegans also exhibit IPC, our observations provide a framework to study the role of mK_ATP in IR injury in a genetic model organism.     

Na(+) interaction with the pore of Shaker B K(+) channels: zero and low K(+) conditions.

The Shaker B K(+) conductance (G(K)) collapses (in a reversible manner) if the membrane is depolarized and then repolarized in, 0 K(+), Na(+)-containing solutions (Gómez-Lagunas, F. 1997. J. Physiol. 499:3-15; Gómez-Lagunas, F. 1999. Biophys. J. 77:2988-2998). In this work, the role of Na(+) ions in the collapse of G(K) in 0-K(+) solutions, and in the behavior of the channels in low K(+) was studied. The main findings are as follows. First, in 0-K(+) solutions, the presence of Na(+) ions is an important factor that speeds the collapse of G(K). Second, external Na(+) fosters the drop of G(K) by binding to a site with a K(d) = 3.3 mM. External K(+) competes, in a mutually exclusive manner, with Na(o)(+) for binding to this site, with an estimated K(d) = 80 microM. Third, NMG and choline are relatively inert regarding the stability of G(K); fourth, with [K(o)(+)] = 0, the energy required to relieve Na(i)(+) block of Shaker (French, R.J., and J.B. Wells. 1977. J. Gen. Physiol. 70:707-724; Starkus, J.G., L. Kuschel, M. Rayner, and S. Heinemann. 2000. J. Gen. Physiol. 110:539-550) decreases with the molar fraction of Na(i)(+) (X(Na,i)), in an extent not accounted for by the change in Delta(mu)(Na). Finally, when X(Na,i) = 1, G(K) collapses by the binding of Na(i)(+) to two sites, with apparent K(d)s of 2 and 14.3 mM.     

Redox regulation of the mitochondrial KATP channel in cardioprotection

The mitochondrial ATP-sensitive potassium channel (mK_ATP) is important in the protective mechanism of ischemic preconditioning (IPC). The channel is reportedly sensitive to reactive oxygen and nitrogen species, and the aim of this study was to compare such species in parallel, to build a more comprehensive picture of mK_ATP regulation. mK_ATP activity was measured by both osmotic swelling and Tl⁺ flux assays, in isolated rat heart mitochondria. An isolated adult rat cardiomyocyte model of ischemia-reperfusion (IR) injury was also used to determine the role of mK_ATP in cardioprotection by nitroxyl. Key findings were as follows: (i) mK_ATP was activated by O₂⁻ and H₂O₂ but not other peroxides. (ii) mK_ATP was inhibited by NADPH. (iii) mK_ATP was activated by S-nitrosothiols, nitroxyl, and nitrolinoleate. The latter two species also inhibited mitochondrial complex II. (iv) Nitroxyl protected cardiomyocytes against IR injury in an mK_ATP-dependent manner. Overall, these results suggest that the mK_ATP channel is activated by specific reactive oxygen and nitrogen species, and inhibited by NADPH. The redox modulation of mK_ATP may be an underlying mechanism for its regulation in the context of IPC. This article is part of a Special Issue entitled: Mitochondria and Cardioprotection.     

Modulation of a plant mitochondrial K+ATP channel and its involvement in cytochrome c release

Pea stem mitochondria, resuspended in a KCl medium (de-energized mitochondria), underwent a swelling, as a consequence of K⁺ entry, that was inhibited by ATP. This inhibition was partially restored by GTP and diazoxide (K⁺ _ATP channel openers). In addition, glyburide and 5-hydroxydecanate (K⁺ _ATP channel blockers) induced an inhibition of the GTP-stimulated swelling. Mitochondrial swelling was inhibited by H₂O₂, but stimulated by NO. The same type of responses was also obtained in succinate-energized mitochondria. When the succinate-dependent transmembrane electrical potential () had reached a steady state, the addition of KCl induced a dissipation that was inhibited by H₂O₂ and stimulated by NO. The latter stimulation was prevented by carboxy-PTIO, a NO scavenger. Phenylarsine oxide (a thiol oxidant) and NEM (a thiol blocker) stimulated the KCl-induced dissipation of , while DTE prevented this effect in both cases. In addition, DTE transiently inhibited the NO-induced dissipation of , but then it caused a more rapid collapse. These results, therefore, show that the plant mitochondrial K⁺ _ATP channel resembles that present in mammalian mitochondria and that it appears to be modulated by dithiol–disulfide interconversion, NO and H₂O₂. The aperture of this channel was linked to the partial rupture of the outer membrane. The latter effect led to a release of cytochrome c, thus suggesting that this release may be involved in the manifestation of programmed cell death.     

Metabolic control of the K+ channel of human red cells

Summary The effects of cAMP, ATP and GTP on the Ca²⁺-dependent K⁺ channel of fresh (1–2 days) or cold-stored (28–36 days) human red cells were studied using atomic absorption flame photometry of Ca²⁺-EGTA loaded ghosts which had been resealed to monovalent cations in dextran solutions. When high-K⁺ ghosts were incubated in an isotonic Na⁺ medium, the rate constant of Ca²⁺-dependent K⁺ efflux was reduced by a half on increasing the theophylline concentration to 40mm. This effect was observed in ghosts from both fresh and stored cells, but only if they were previously loaded with ATP. The inhibition was more marked when Mg²⁺ was added together with ATP, and it was abolished by raising free Ca²⁺ to the micromolar level. Like theophylline, isobutyl methylxanthine (10mm) also affected K⁺ efflux. cAMP (0.2–0.5mm), added both internally and externally (as free salt, dibutyryl or bromide derivatives), had no significant effect on K⁺ loss when the ghost free-Ca²⁺ level was below 1 m, but it was slightly inhibitory at higher concentrations. The combined presence of cAMP (0.2mm) plus either theophylline (10mm), or isobutyl methylxanthine (0.5mm), was more effective than cAMP alone. This inhibition showed a strict requirement for ATP plus Mg²⁺ and it, was not overcome by raising internal Ca²⁺. Ghosts from stored cells seemed more sensitive than those from fresh cells, to the combined action of cAMP and methylxanthines. Loading ATP into ghosts from fresh or stored cells markedly decreased K⁺ loss. Although this effect was observed in the absence of added Mg²⁺ (0.5mm EDTA present), it was potentiated upon adding 2mm Mg²⁺. The K⁺ efflux from ATP-loaded ghosts was not altered by dithio-bis-nitrobenzoic acid (10mm) or acridine orange (100 m), while it was increased two-to fourfold by incubating with MgF₂ (10mm), or MgF₂ (10mm)+theophylline (40mm), respectively. By contrast, a marked efflux reduction was obtained by incorporating 0.5mm GTP into ATP-containing ghosts. The degree of phosphorylation obtained by incubating membranes with (-³²P)ATP under various conditions affecting K⁺ channel activity, was in direct correspondence to their effect on K⁺ efflux. The results suggest that the K⁺ channel of red cells is under complex metabolic control, via cAMP-mediated and nonmediated mechanisms, some which require ATP and presumably, involve phosphorylation of the channel proteins.     

Action of imipramine on activated ATP-sensitive K(+) channels in interstitial cells of Cajal from murine small intestine

Tricyclic antidepressants have been widely used for the treatment of depression and as a therapeutic agent for the altered gastrointestinal (GI) motility of irritable bowel syndrome (IBS). The aim of this study was to clarify whether antidepressants directly modulate pacemaker currents in cultured interstitial cells of Cajal (ICC). We used the whole-cell patch-clamp techniques at 30 degrees C in cultured ICC from the mouse small intestine. Treatment of pinacidil, an ATP-sensitive K(+) channel opener, in the ICC using the current clamping mode, produced hyperpolarization of the membrane potential and decreased the amplitude of the pacemaker potentials. With the voltage clamp mode, we observed a decrease in the frequency and amplitude of pacemaker currents and increases in the resting outward currents. These effects of pinacidil on pacemaker potentials and currents were completely suppressed by glibenclamide, an ATP-sensitive K(+) channel blocker. Also, with the current clamp mode, imipramine blocked the affect of pinacidil on the pacemaker potentials. Observations of the voltage clamp mode with imipramine, desipramine and amitryptyline suppressed the action of pinacidil in the ICC. Next, we examined whether protein kinase C (PKC) and the G protein are involved in the action of imipramine on pinacidil induced pacemaker current inhibition. We used chelerythrine, a potent PKC inhibitor and GDPbetaS, a nonhydrolyzable guanosine 5-diphosphate (GDP) analogue that permanently inactivates GTP-binding proteins. We found that pretreatment with chelerythrine and intracellular application of GDPbetaS had no influence on the blocking action of imipramine on inhibited pacemaker currents by pinacidil. We conclude that imipramine inhibited the activated ATP-sensitive K(+) channels in ICC. This action does not appear to be mediated through the G protein and protein kinase C. Furthermore, this study may suggest another possible mechanism for tricyclic antidepressants related modulation of GI motility.     

Effects of ADP upon the ATP-sensitive K+ channel in rat ventricular myocytes

Summary The effects of ADP upon the gating of ATP-sensitive K⁺ channels from rat ventricular myocytes have been investigated by patch-clamp single-channel current recording experiments. ADP was applied to the internal surface of excised insideout membrane patches and depending upon the experimental protocol and the concentration it was found that ADP could either inhibit or stimulate openings of ATP-sensitive K⁺ channels. In the absence of inactivation, ATP-sensitive K⁺ channels were inhibited by ADP in a dose-dependent manner. Partially inactivated channels, on the other hand, were stimulated by low (10 to 250 M) and inhibited by high (>250 M) concentrations of ADP. ATP-sensitive K⁺ channels which were being inhibited by ATP (<1 mM) could be opened by the simultaneous application of ADP (50 M to 1 mM). ADP had no effect upon channels inhibited by mM concentrations of ATP. The situation was further complicated when it was found that inhibition evoked by ADP was strongly attenuated by the presence of Mg²⁺ ions whilst channel stimulation, whether of partially inactivated channels or channels inhibited by ATP, required the presence of Mg²⁺ ions. The analog of ADP, ADPS, always evoked inhibition of ATP-sensitive K⁺ channels which was not affected by the presence or absence of Mg²⁺ ions.     

Gating of the ATP-sensitive K channel by a pore-lining phenylalanine residue

ATP-sensitive K⁺ (K_ATP) channels are gated by intracellular ATP, proton and phospholipids. The pore-forming Kir6.2 subunit has all essential machineries for channel gating by these ligands. It is known that channel gating involves the inner helix bundle of crossing in which a phenylalanine residue (Phe168) is found in the TM2 at the narrowest region of the ion-conduction pathway in the Kir6.2. Here we present evidence that Phe168-Kir6.2 functions as an ATP- and proton-activated gate via steric hindrance and hydrophobic interactions. Site-specific mutations of Phe168 to a small amino acid resulted in losses of the ATP- and proton-dependent gating, whereas the channel gating was well maintained after mutation to a bulky tryptophan, supporting the steric hindrance effect. The steric hindrance effect, though necessary, was insufficient for the gating, as mutating Phe168 to a bulky hydrophilic residue severely compromised the channel gating. Single-channel kinetics of the F168W mutant resembled the wild-type channel. Small residues increased P_open, and displayed long-lasting closures and long-lasting openings. Kinetic modeling showed that these resulted from stabilization of the channel to open and long-lived closed states, suggesting that a bulky and hydrophobic residue may lower the energy barrier for the switch between channel openings and closures. Thus, it is likely that the Phe168 acts as not only a steric hindrance gate but also potentially a facilitator of gating transitions in the Kir6.2 channel.     

Iptakalim protects PC12 cell against H2O2-induced oxidative injury via opening mitochondrial ATP-sensitive potassium channel

The final common pathway in the demise of dopaminergic neurons in Parkinson's disease may involve oxidative stress and excitotoxicity. In this study, we examined the neuroprotective effects of a novel ATP-sensitive potassium channel (K(ATP)) opener, iptakalim (IPT), against H(2)O(2)-induced cytotoxicity in rat dopaminergic PC12 cells. Pretreatment with IPT could attenuate increased extracellular glutamate levels and inhibit calcium influxing induced by H(2)O(2). Moreover, IPT regulated the expressions of bcl-2 and bax which were responsible for inhibiting apoptosis in PC12 cells. These protective effects of IPT were abolished by selective mitoK(ATP) channel blocker 5-hydroxydecanoate. Therefore, IPT can protect PC12 cells against H(2)O(2)-induced oxidative injury via activating mitoK(ATP) channel.     

Partial contribution of the ATP-sensitive K+ current to the effects of mild metabolic depression in rabbit myocardium

The object of the study was to compare the capability of glibenclamide to block the effects of K⁺-ATP channel activators on action potential duration and steady state whole cell current to its efficiency in counteracting the effects of hypoxia or metabolic poisons in the presence of glycolytic substrate. The modulation of action potential duration by 30 M glibenclamide was tested in perfused hearts subjected to hypoxia or to the K⁺-ATP channel opener pinacidil. Similar protocols were used to study the modifications of the steady state whole cell current in isolated ventricular myocytes. It was found that glibenclamide did not prevent early action potential shortening induced by hypoxia but produced a partial recovery after 15 min of exposure. At the steady state the action potential duration had lengthened by 53±6% at plateau level and 42±3% at 95% repolarization. In contrast, action potential shortening induced by 100 M pinacidil was fully reversed by glibenclamide within 2 min. Freshly dispersed ventricular myocytes were characterized in control conditions as for the properties of the steady state current. This current, measured at the end of 450 ms long pulses showed typical inward rectification that was abolished by 50 M Ba²⁺. Cyanide (2 mM), carbonyl-cyanide m-chlorophenylhydrazone (CCCP, 200 nM) and BRL 38227 (30 M) produced characteristic increases in time independent outward currents. Glibenclamide abolished the outward current induced by BRL 38227 and the concomitant action potential shortening. Addition of cyanide in the presence of glibenclamide and BRL 38227 produced a new increase in outward current accompanied by action potential shortening. In the absence of K⁺-ATP channel activators, glibenclamide partly inhibited the CCCP induced current. Our data suggested that the delayed onset of glibenclamide action in hypoxic hearts is not due to diffusion barriers. They rather support the view that mechanisms other than K⁺-ATP channel activation could determine the early action potential shortening in whole hearts. The partial recovery observed under glibenclamide may be due, in part, to channel desensitization but also reflect the contribution of more than one current system to the action potential shortening because the glibenclamide insensitive fraction of the CCCP induced current is partly blocked by low concentrations of Ba²⁺. Differences with other data in the literature are attributed to the degree to metabolic blockade, to species differences, and to the inherent heterogeneities of the whole heart model where non-muscle cells may modulate the response to hypoxia.     

Increased ATP-sensitive K+ channel expression during acute glucose deprivation

ATP-sensitive potassium (KATP) channels play a central role in glucose-stimulated insulin secretion (GSIS) by pancreatic beta-cells. Activity of these channels is determined by their open probability (Po) and the number of channels present in a cell. Glucose is known to reduce Po, but whether it also affects the channel density is unknown. Using INS-1 model beta-cell line, we show that the expression of K(ATP) channel subunits, Kir6.2 and SUR1, is high at low glucose, but declines sharply when the ambient glucose concentration exceeds 5mM. In response to glucose deprivation, channel synthesis increases rapidly by up-regulating translation of existing mRNAs. The effects of glucose deprivation could be mimicked by pharmacological activation of 5'-AMP-activated protein kinase with 5-aminoimidazole-4-carboxamide ribonucleotide and metformin. Pancreatic beta-cells which have lost their ability for GSIS do not show such changes implicating a possible (patho-)physiological link between glucose-regulated KATP channel expression and the capacity for normal GSIS.     

Modulation of mitochondrial K permeability and reactive oxygen species production by the p13 protein of human T-cell leukemia virus type 1

Human T-cell leukemia virus type-1 (HTLV-1) expresses an 87-amino acid protein named p13 that is targeted to the inner mitochondrial membrane. Previous studies showed that a synthetic peptide spanning an alpha helical domain of p13 alters mitochondrial membrane permeability to cations, resulting in swelling. The present study examined the effects of full-length p13 on isolated, energized mitochondria. Results demonstrated that p13 triggers an inward K⁺ current that leads to mitochondrial swelling and confers a crescent-like morphology distinct from that caused by opening of the permeability transition pore. p13 also induces depolarization, with a matching increase in respiratory chain activity, and augments production of reactive oxygen species (ROS). These effects require an intact alpha helical domain and strictly depend on the presence of K⁺ in the assay medium. The effects of p13 on ROS are mimicked by the K⁺ ionophore valinomycin, while the protonophore FCCP decreases ROS, indicating that depolarization induced by K⁺ vs. H⁺ currents has different effects on mitochondrial ROS production, possibly because of their opposite effects on matrix pH (alkalinization and acidification, respectively). The downstream consequences of p13-induced mitochondrial K⁺ permeability are likely to have an important influence on the redox state and turnover of HTLV-1-infected cells.     

K(+) channel activity and redox status are differentially required for JNK activation by UV and reactive oxygen species

Upon exposure to ultraviolet (UV) radiation, osmotic changes or the presence of reactive oxygen species (ROS) c-Jun N-terminal kinases (JNKs) are rapidly activated. Extensive studies have elucidated molecular components that mediate the activation of JNKs. However, it remains unclear whether activation of JNKs by various stress signals involves different pathways. Here we show that K(+) channel activity is involved in mediating apoptosis induced by UV but not by H(2)O(2) in myelocytic leukemic ML-1 cells. Specifically, JNKs were rapidly phosphorylated upon treatment of ML-1 cells with UV and H(2)O(2). UV-induced, but not H(2)O(2)-induced, JNK-1 phosphorylation was inhibited by pretreatment with 4-aminopyridine (4-AP), a K(+) channel blocker. 4-AP also blocked UV-induced increase in JNK activity as well as p38 phosphorylation. Immunofluorescent microscopy revealed that phosphorylated JNKs were concentrated at centrosomes in ML-1 cells and that these proteins underwent rapid subcellular translocation upon UV treatment. Consistently, the subcellular translocation of JNKs induced by UV was largely blocked by 4-AP. Furthermore, UV-induced JNK activation was blocked by NEM, a sulfhydryl alkylating agent also affecting K(+) current. Both UV- and H(2)O(2)-induced JNK activities were inhibited by glutathione, suggesting that the redox status does play an important role in the activation of JNKs. Taken together, our findings suggest that JNK activation by UV and H(2)O(2) is mediated by distinct yet overlapping pathways and that K(+) channel activity and redox status are differentially required for UV- and H(2)O(2)-induced activation of JNKs.     

Distinct modes of blockade in cardiac ATP-sensitive K+ channels suggest multiple targets for inhibitory drug molecules

Elementary K⁺ currents were recorded at 19°C in inside-out patches from cultured neonatal rat cardiocytes to elucidate the block phenomenology in cardiac ATP-sensitive K⁺ channels when inhibitory drug molecules, such as the sulfonylurea glibenclamide, the phenylalkylamine verapamil or sulfonamide derivatives (HE 93 and sotalol), are interacting in an attempt to stress the hypothesis of multiple channel-associated drug targets.Similar to their adult relatives, neonatal cardiac K_(ATP) channels are characterized by very individual open state kinetics, even in cytoplasmically well-controlled, cell-free conditions; at –7 mV, _open(1) ranged from 0.7 to 4.9 msec in more than 200 patches and _open(2) from 10 to 64 msec—an argument for a heterogeneous channel population. Nevertheless, a common response to drugs was observed. Glibenclamide and the other inhibitory molecules caused long-lasting interruptions of channel activity, after cytoplasmic application, as if drug occupancy trapped cardiac K_(ATP) channels in a very stable, nonconducting configuration. The resultant NP ₀ depression was strongest with glibenclamide (apparent IC₅₀ 13 nmol/liter) and much weaker with verapamil (apparent IC₅₀ 9 mol/liter), HE 93 (apparent IC₅₀ 29 mol/liter) and sotalol (apparent IC₅₀ 43 mol/ liter) and may have resulted from the occupancy of a single site with drug-specific affinity or of two sites, the high affinity glibenclamide target and a distinct nonglibenclamide, low affinity target.Changes in open state kinetics, particularly in the transition between the O₁ state and the O₂ state, are other manifestations of drug occupancy of the channel. Any inhibitory drug molecule reduced the likelihood of attaining the O₂ state, consistent with a critical reduction of the forward rate constant governing the O₁-O₁ transition. But only HE 93 (10 mol/liter) associated (with an apparent association rate constant of 2.3 × 10⁶ mol^–1 sec^–1) to shorten significantly _open(2) to 60.6 ± 6% of the predrug value, not the expected result when the entrance in and the exit from the O₂ state would be drug-unspecifically nfluenced. Sotalol found yet another and definitely distinctly located binding site to interfere with K⁺ permeation; both enantiomers associated with a rate close to 5×10⁵ mol^–1 sec^–1 with the open pore thereby flicker-blocking cardiac K_(ATP) channels. Clearly, these channels accommodate more than one drug-binding domain.     

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.     

Some effects of dibutylchloromethyltin chloride and other reagents on mitochondrial K+ flux

Respiration-dependent K⁺ fluxes across the limiting membranes of isolated rat liver mitochondria, measured by means of⁴²K, are stimulated by the oxidative phosphorylation inhibitor dibutylchloromethyltin chloride (DBCT). A lack of effect of Cl^– concentration indicates that the stimulation of K⁺ flux by DBCT is not attributable to Cl^–/OH^– exchange activity. The mercurial mersalyl was previously shown to stimulate respiration-dependent K⁺ influx. The combined presence of mersalyl plus DBCT results in a greater stimulation of K⁺ influx than is caused by either DBCT or mersalyl alone. The oxidative phosphorylation inhibitor oligomycin, which alone has no effect on respiration-dependent K⁺ influx, enhances the stimulatory effect of mersalyl on K⁺ influx. The data are consistent with, although not proof of, a direct interaction of the K⁺ transport mechanism with the mitochondrial energy transduction apparatus.Abbreviations used: DCCD,N,N-dicyclohexylcarbodiimide; DBCT, dibutylchloromethyltin chloride.