Mechanism of Ba(2+) block of a mouse inwardly rectifying K+ channel: differential contribution by two discrete residues.

1. The block of the IRK1/Kir2.1 inwardly rectifying K+ channel by a Ba(2+) ion is highly voltage dependent, where the ion binds approximately half-way within the membrane electrical field. The mechanism by which two distinct mutations, E125N and T141A, affect Ba(2+) block of Kir2.1 was investigated using heterologous expression in Xenopus oocytes. 2. Analysis of the blocking kinetics showed that E125 and T141 affect the entry and binding of Ba(2+) to the channel, respectively. Replacing the glutamate at position 125 with an asparagine greatly decreased the rate at which the Ba(2+) ions enter and leave the pore. In contrast, replacing the polar threonine at position 141 with an alanine affected the entry rate of the Ba(2+) ions while leaving the exit rate unchanged. 3. Acidification of the extracellular solution slowed the exit rate of the Ba(2+) from the wild-type channel, but had no such effect on the Kir2.1(E125N) mutant. 4. These results thus reveal two unique roles for the amino acids at positions 125 and 141 in aiding the interaction of Ba(2+) with the channel. Their possible roles in K+ permeation are discussed.

Redox-dependent gating of G protein-coupled inwardly rectifying K+ channels.

G protein-coupled inwardly rectifying K(+) channels (GIRK) play a major role in inhibitory signaling in excitable and endocrine tissues. The gating mechanism of these channels is mediated by a direct interaction of the Gbetagamma subunits of G protein, which are released upon inhibitory neurotransmitter receptor activation. This gating mechanism is further manifested by intracellular factors such as anionic phospholipids and Na(+) and Mg(2+) ions. In addition to the essential role of these components for channel function, phosphorylation events can also modulate channel activity. In this study we explored the involvement of redox modulation on GIRK channel function. Extracellular application of the reducing agent dithiothreitol (DTT), but not reduced glutathione, activated GIRK channels without affecting their permeation or rectification properties. The DTT-dependent activation was found to mimic receptor activation and to act directly on the channel in a membrane delimited fashion. A critical cysteine residue located in the N-terminal cytoplasmic domain was found to be essential for DTT-dependent activation in hetero- and homotetrameric contexts. Interestingly, when mutating this cysteine residue, DTT-dependent activation was abolished, but receptor-mediated channel activation was not affected. These results suggest that intracellular redox potential can play a major role in tuning GIRK channel activity in a receptor-independent manner. This sort of redox modulation can be part of an important cellular protective mechanism against ischemic or hypoxic insults.

In vitro phosphorylation of COOH termini of the epithelial Na(+) channel and its effects on channel activity in Xenopus oocytes.

Recent findings have suggested the involvement of protein phosphorylation in the regulation of the epithelial Na(+) channel (ENaC). This study reports the in vitro phosphorylation of the COOH termini of ENaC subunits expressed as glutathione S-transferase fusion proteins. Channel subunits were specifically phosphorylated by kinase-enriched cytosolic fractions derived from rat colon. The phosphorylation observed was not mediated by the serum- and glucocorticoid-regulated kinase sgk. For the gamma-subunit, phosphorylation occurred on a single, well-conserved threonine residue located in the immediate vicinity of the PY motif (T630). The analogous residue on beta(S620) was phosphorylated as well. The possible role of gammaT630 and betaS620 in channel function was studied in Xenopus laevis oocytes. Mutating these residues to alanine had no effect on the basal channel-mediated current. They do, however, inhibit the sgk-induced increase in channel activity but only in oocytes that were preincubated in low Na(+) and had a high basal Na(+) current. Thus mutating gammaT630 or betaS620 may limit the maximal channel activity achieved by a combination of sgk and low Na(+).

Coupling Gbetagamma-dependent activation to channel opening via pore elements in inwardly rectifying potassium channels.

G protein-coupled inwardly rectifying potassium channels, GIRK/Kir3.x, are gated by the Gbetagamma subunits of the G protein. The molecular mechanism of gating was investigated by employing a novel yeast-based random mutagenesis approach that selected for channel mutants that are active in the absence of Gbetagamma. Mutations in TM2 were found that mimicked the Gbetagamma-activated state. The activity of these channel mutants was independent of receptor stimulation and of the availability of heterologously expressed Gbetagamma subunits but depended on PtdIns(4,5)P(2). The results suggest that the TM2 region plays a key role in channel gating following Gbetagamma binding in a phospholipid-dependent manner. This mechanism of gating in inwardly rectifying K+ channels may be similar to the involvement of the homologous region in prokaryotic KcsA potassium channel and, thus, suggests evolutionary conservation of the gating structure.

Regulation of sgk by aldosterone and its effects on the epithelial Na(+) channel.

Aldosterone is the major corticosteroid regulating Na(+) absorption in tight epithelia and acts primarily by activating the epithelial Na(+) channel (ENaC) through unknown induced proteins. Recently, it has been reported that aldosterone induces the serum- and glucocorticoid-dependent kinase sgk and that coexpressing ENaC with this kinase in Xenopus laevis oocytes increases the amiloride-sensitive Na(+) current (Chen SY, Bhargava A, Mastroberardino L, Meijer OC, Wang J, Buse P, Firestone GL, Verrey F, and Pearce D. Proc Natl Acad Sci USA 96: 2514-2519, 1999). The present study was done to further characterize regulation of sgk by aldosterone in native mammalian epithelia and to examine its effect on ENaC. With both in vivo and in vitro protocols, an almost fivefold increase in the abundance of sgk mRNA has been demonstrated in rat kidney and colon but not in lung. Induction of sgk by aldosterone was detected in kidney cortex and medulla, whereas the papilla expressed a constitutively high level of the kinase. The increase in sgk mRNA was detected as early as 30 min after the hormonal application and was independent of de novo protein synthesis. The observed aldosterone dose-response relationships suggest that the response is mediated, at least in part, by occupancy of the mineralocorticoid receptor. Coexpressing sgk and ENaC in Xenopus oocytes evoked a fourfold increase in the amiloride-blockable Na(+) channel activity. A point mutation in the beta-subunit known to impair regulation of the channel by Nedd4 (Y618A) had no significant effect on the response to sgk.

Fast inactivation of a brain K+ channel composed of Kv1.1 and Kvbeta1.1 subunits modulated by G protein beta gamma subunits.

Modulation of A-type voltage-gated K+ channels can produce plastic changes in neuronal signaling. It was shown that the delayed-rectifier Kv1.1 channel can be converted to A-type upon association with Kvbeta1.1 subunits; the conversion is only partial and is modulated by phosphorylation and microfilaments. Here we show that, in Xenopus oocytes, expression of Gbeta1gamma2 subunits concomitantly with the channel (composed of Kv1.1 and Kvbeta1.1 subunits), but not after the channel's expression in the plasma membrane, increases the extent of conversion to A-type. Conversely, scavenging endogenous Gbetagamma by co-expression of the C-terminal fragment of the beta-adrenergic receptor kinase reduces the extent of conversion to A-type. The effect of Gbetagamma co-expression is occluded by treatment with dihydrocytochalasin B, a microfilament-disrupting agent shown previously by us to enhance the extent of conversion to A-type, and by overexpression of Kvbeta1.1. Gbeta1gamma2 subunits interact directly with GST fusion fragments of Kv1.1 and Kvbeta1.1. Co-expression of Gbeta1gamma2 causes co-immunoprecipitation with Kv1.1 of more Kvbeta1.1 subunits. Thus, we suggest that Gbeta1gamma2 directly affects the interaction between Kv1.1 and Kvbeta1.1 during channel assembly which, in turn, disrupts the ability of the channel to interact with microfilaments, resulting in an increased extent of A-type conversion.

Molecular basis for interactions of G protein betagamma subunits with effectors.

Both the alpha and betagamma subunits of heterotrimeric guanine nucleotide-binding proteins (G proteins) communicate signals from receptors to effectors. Gbetagamma subunits can regulate a diverse array of effectors, including ion channels and enzymes. Galpha subunits bound to guanine diphosphate (Galpha-GDP) inhibit signal transduction through Gbetagamma subunits, suggesting a common interface on Gbetagamma subunits for Galpha binding and effector interaction. The molecular basis for interaction of Gbetagamma with effectors was characterized by mutational analysis of Gbeta residues that make contact with Galpha-GDP. Analysis of the ability of these mutants to regulate the activity of calcium and potassium channels, adenylyl cyclase 2, phospholipase C-beta2, and beta-adrenergic receptor kinase revealed the Gbeta residues required for activation of each effector and provides evidence for partially overlapping domains on Gbeta for regulation of these effectors. This organization of interaction regions on Gbeta for different effectors and Galpha explains why subunit dissociation is crucial for signal transmission through Gbetagamma subunits.

Probing the G-protein regulation of GIRK1 and GIRK4, the two subunits of the KACh channel, using functional homomeric mutants.

In heart, G-protein-activated channels are complexes of two homologous proteins, GIRK1 and GIRK4. Expression of either protein alone results in barely active or non-active channels, making it difficult to assess the individual contribution of each subunit to the channel complex. The residue Phe137, located within the H5 region of GIRK1, is critical to the synergy between GIRK1 and GIRK4 (Chan, K. W., Sui, J. L., Vivaudou, M., and Logothetis, D. E. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 14193-14198). By modifying this residue or the matching residue of GIRK4, Ser143, we have been able to generate mutant proteins that produced large inwardly rectifying, G-protein-modulated currents when expressed alone in Xenopus oocytes. The enhanced activity of the heterologous expression of each of two active mutants, GIRK1(F137S) and GIRK4(S143T), was not caused by association with an endogenous oocyte channel subunit, and these mutants did not display apparent differences in the ability to localize to the cell surface compared with their wild-type counterparts. When these functional mutant channels were compared individually with wild-type heteromeric channels, they responded with only small differences to a number of maneuvers involving coexpression with muscarinic receptors, G-protein betagamma subunits, wild-type or mutated G-protein alpha subunits, and active protomers of pertussis toxin. These experiments, which confirmed the crucial, though not exclusive, role of Gbetagamma in regulating channel activity, demonstrated that GIRK1(F137S) and GIRK4(S143T), and by extrapolation their wild-type counterparts, interact in a qualitatively similar way with G-protein subunits. These findings suggest that functionally important sites of interaction with G-proteins are likely to be located within the homologous regions of GIRK1 and GIRK4 rather than within the divergent terminal regions. They also raise the question of the functional advantage of a heteromeric over homomeric design for G-protein-gated channels.

Contributions of a negatively charged residue in the hydrophobic domain of the IRK1 inwardly rectifying K+ channel to K(+)-selective permeation.

Inwardly rectifying K+ channels are highly selective for K+ ions and show strong interaction with ions in the pore. Both features are important for the physiological functions of these channels and pose intriguing mechanistic questions of ion permeation. The aspartate residue in the second putative transmembrane segment of the IRK1 inwardly rectifying K+ channel, previously implicated in inward rectification gating due to cytoplasmic Mg2+ and polyamine block, is found in this study to be crucial for the channel's ability to distinguish between K+ and Rb+ ions. Mutation of this residue also perturbs the interaction between the channel pore and the Sr2+ blocking ion. Our studies suggest that this aspartate residue contributes to a selectivity filter near the cytoplasmic end of the pore.

Identification of structural elements involved in G protein gating of the GIRK1 potassium channel.

Chimeras of GIRK1 and IRK1, a G protein-insensitive inward rectifier, are activated by coexpression of G beta gamma if they contain either the N-terminal or part of the C-terminal hydrophilic domain of GIRK1. The N-terminal domain of GIRK1 also facilitates the fast rates of activation and deactivation following m2 muscarinic receptor stimulation. The hydrophobic core of GIRK1 (M1-H5-M2) is important for determining the brief single-channel open times typical of GIRK1 but not important for determining G beta gamma sensitivity. Coexpression with CIR revealed that the gating properties associated with different GIRK1 domains could not have arisen from altered ability to form heteromultimers. These results implicate specific regions of GIRK1 in G protein activation and suggest that GIRK1 may be closely linked to the m2 muscarinic receptor-G protein complex.

GABA receptor-channel complex as a target site of mercury, copper, zinc, and lanthanides.

1. The GABAA receptor-chloride channel complex has been shown to be modulated by a variety of chemicals. Scores of chemicals with diverse and unrelated structures augment the GABA-induced chloride current, while some other chemicals suppress the current. Certain heavy metals and a variety of polyvalent cations increase or decrease the current in a potent and efficacious manner. 2. We have studied the mechanisms whereby mercury, copper, zinc, and lanthanides modulated the GABA system by whole-cell and single-channel patch clamp techniques as applied to the rat dorsal root ganglion neurons in primary culture. 3. Mercuric chloride augmented the GABA-induced current to 115% of control at 0.1 microM and to 270% of control at 100 microM. It also generated a slowly developing inward current carried by a variety of ions. In contrast, methylmercury suppressed the GABA-induced current. The potent stimulation of the GABA system by mercuric chloride is deemed important in mercury intoxication. 4. Copper and zinc suppressed the GABA-induced current with an EC50 of 16 and 19 microM, respectively. They bound to a common site on the external surface of the GABA receptor-channel complex. 5. Lanthanum augmented the GABA-induced current with an EC50 of 230 microM by increasing the affinity of the receptor for GABA. It bound to a site on or near the external surface of the GABA receptor-channel complex which is different from the sites for GABA, barbiturates, benzodiazepines, picrotoxin, and copper/zinc. 6. Six other lanthanides with larger atomic numbers also exerted the same stimulatory effect with their efficacies increasing with the atomic number. 7. Single-channel analyses have revealed that the augmentation of whole-cell current by terbium, a lanthanide, is due to three actions: an increase in the overall mean open time, a decrease in the overall mean closed time, and an increase in the overall mean burst time.

Opioid inhibition and desensitization of calcium channel currents in rat dorsal root ganglion neurons.

The mu-opioid [D-Ala2,N-Me-Phe4,Gly5-ol]-enkephalin (DAMGO) inhibited the high voltage-activated calcium channel currents of neonatal rat dorsal root ganglion neurons in a voltage-dependent manner. The low voltage-activated currents were not affected by DAMGO. The inhibitory effect was eliminated by pretreatment of the cell with pertussis toxin, indicating that the receptor was coupled with the pertussis toxin-sensitive G protein. Although the DAMGO inhibition occurred quickly, it was relieved gradually during the 5-min application of DAMGO. The recovery from desensitization after washout of DAMGO was very slow. Pretreatment of the cell with 1 microM DAMGO for 18 hr induced almost complete tolerance to the agonist. GTP-gamma-S also inhibited the high voltage-activated calcium channel currents mimicking DAMGO inhibition and the inhibition diminished during continuous application, suggesting that desensitization could occur without receptor stimulation by the agonist. Baclofen caused a similar inhibition and desensitization to those by DAMGO, and the inhibition by the subsequently applied DAMGO was attenuated. Thus, desensitization by these distinct receptor agonists is heterologous. Modulation of G proteins which are coupled with these agonists may be involved in the desensitization process.

Activation of the cloned muscarinic potassium channel by G protein beta gamma subunits.

Acetylcholine released during parasympathetic stimulation of the vagal nerve slows the heart rate through the activation of muscarinic receptors and subsequent opening of an inwardly rectifying potassium channel. The activation of these muscarinic potassium channels is mediated by a pertussis toxin-sensitive heterotrimeric GTP-binding protein (G protein). It has not been resolved whether exogenously applied G alpha or G beta gamma, or both, activate the channel. Using a heterologous expression system, we have tested the ability of different G protein subunits to activate the cloned muscarinic potassium channel, GIRK1. We report here that coexpression of GIRK1 with G beta gamma but not G alpha beta gamma in Xenopus oocytes results in channel activity that persists in the absence of cytoplasmic GTP. This activity is reduced by fusion proteins of the beta-adrenergic receptor kinase and of recombinant G alpha i-GDP, both of which are known to interact with G beta gamma. Moreover, application of recombinant G beta gamma, but not G alpha i-GTP-gamma S, activates GIRK1 channels. Thus G beta gamma appears to be sufficient for the activation of GIRK1 muscarinic potassium channels.

Single-channel analysis of tetrodotoxin-sensitive and tetrodotoxin-resistant sodium channels in rat dorsal root ganglion neurons.

Tetrodotoxin-sensitive and tetrodotoxin-resistant single sodium channel currents were recorded from rat dorsal root ganglion neurons. The two types of sodium channel currents could be distinguished by the effects of predepolarization, 10 nM tetrodotoxin, and the inactivation during depolarization. Single-channel conductances were calculated to be 6.3 and 3.4 pS in the tetrodotoxin-sensitive and tetrodotoxin-resistant channels, respectively.

Terbium modulation of single gamma-aminobutyric acid-activated chloride channels in rat dorsal root ganglion neurons.

We have previously reported that lanthanides markedly potentiate the GABA-induced chloride current by acting at a distinct site on the GABAA receptor-channel complex (Ma and Narahashi, 1993a,b). These studies have now been extended to the single-channel level and changes in gating kinetics of GABAA receptor currents caused by 100 microM terbium (Tb3+) are reported. The GABA-induced currents were recorded from outside-out membrane patches isolated from rat dorsal root ganglion neurons in primary culture at a holding potential of -60 mV. At least two conductance levels were recorded, a main conductance of about 26 pS (70-80% of events) and a subconductance of about 19 pS (20-30% of events). These two conductances and the ratio of main- and subconductance state currents with respect to the number of events were not changed by Tb3+. The frequency of channel openings was also unchanged in the presence of Tb3+. The frequency histograms of open, close, and burst durations of the main-conductance state were best fitted by a sum of three exponential functions. All of the time constants remained unchanged by application of Tb3+ while the relative proportions of the longest open and burst duration time constants were increased and the relative proportion of longest closed time constant was decreased. We suggest that Tb3+ binds to an allosteric site on the GABAA receptor-channel complex to increase the apparent mean open time of the channel by increasing the affinity of GABA for the GABA binding site, and/or by shifting the distribution toward the open states so that the frequency of occurrence of longer open states is stabilized.(ABSTRACT TRUNCATED AT 250 WORDS)

Primary structure and functional expression of a rat G-protein-coupled muscarinic potassium channel.

Parasympathetic nerve stimulation causes slowing of the heart rate by activation of muscarinic receptors and the subsequent opening of muscarinic K+ channels in the sinoatrial node and atrium. This inwardly rectifying K+ channel is coupled directly with G protein. Based on sequence homology with cloned inwardly rectifying K+ channels, ROMK1 (ref. 11) and IRK1 (ref. 12), we have isolated a complementary DNA for a G-protein-coupled inwardly rectifying K+ channel (GIRK1) from rat heart. The GIRK1 channel probably corresponds to the muscarinic K+ channel because (1) its functional properties resemble those of the atrial muscarinic K+ channel and (2) its messenger RNA is much more abundant in the atrium than in the ventricle. In addition, GIRK1 mRNA is expressed not only in the heart but also in the brain.

The effect of polyamines on voltage-activated calcium channels in mouse neuroblastoma cells.

1. Putrescine has been implicated in modulating cytoplasmic calcium concentration and is correlated with selective neuronal vulnerability in cerebral ischaemia. In order to determine whether putrescine modulates voltage-activated calcium channels, whole-cell and single channel patch clamp experiments were performed with N1E-115 mouse neuroblastoma cells. 2. L-type calcium channel currents showed a 34 +/- 21% increase (n = 6 cells) during external application of 1 mM putrescine. There was no change in the kinetics of the current and no shift in the current-voltage relationship along the voltage axis. 3. T-type calcium channel currents were not affected by 1 mM putrescine. 4. The effect of putrescine on single L-type calcium channels was studied using the cell-attached configuration of the patch clamp technique. Putrescine (5 mM) applied to the bathing solution, but not present in the pipette, caused an increase in open time of the single channel current without changing the conductance of the channel. In 345 depolarizing steps compiled from three cells, the number of channel openings longer than 3 ms increased from six to seventy-six, and the number of channel openings longer than 9 ms increased from zero to twenty-seven. This single channel study supports the hypothesis that putrescine acts on the L-type channel from the inside of the cell. 5. External application of 1 mM spermine and 1 mM spermidine had no effect on T- and L-type calcium channels. Thus, the effect of putrescine is probably not mediated by the higher polyamines. 6. In order to test whether the effect of putrescine is mediated by a second messenger, specific protein kinase C and cyclic AMP-dependent protein kinase inhibitors, staurosporine and KT5720, respectively, were applied prior to putrescine. When cells were preconditioned with 200 nM staurosporine, the increase of the L-type calcium current by 1 mM putrescine was inhibited. By contrast, 200 nM KT5720 did not inhibit the putrescine effect. Therefore, the increase of L-type channel currents by putrescine may be mediated by protein kinase C but not the cyclic AMP-dependent protein kinase. 7. The putrescine-induced enhancement of the L-type calcium channel activity may play an important role in calcium-induced neurotoxicity.

Two types of high voltage-activated calcium channels in SH-SY5Y human neuroblastoma cells.

Voltage-activated calcium channel currents were recorded from differentiated human neuroblastoma cells. SK-N-SH-SY5Y (SH-SY5Y) line, using patch-clamp techniques. Experimental solutions were designed to suppress sodium and potassium channel currents, and barium ions were used as the charge carrier. Two distinct types of calcium channel currents (N- and L-like) were identified based on their time-dependent inactivation, pharmacology and single-channel conductances. N- and L-like calcium channel currents were evoked by step depolarizing pulses to potentials more positive than -40 mV from a holding potential of -100 mV. The N-like component showed time-dependent inactivation during maintained depolarization with a time constant of tau f approximately 100 ms, whereas the L-like currents showed very slow inactivation with a time constant of tau s approximately 1,000 ms. Steady-state inactivation of currents evoked from a holding potential of -100 mV had two distinct components. One component involved the reduction of the transient current and had a half-maximal current at approximately -66 mV, whereas the other component involved the reduction of the steady-state current in the range of -35 to 0 mV with a half-maximal current at approximately -17 mV. Bay K 8644 (5 microM), had two distinct actions, one was the increase (50%) of the current associated with a depolarizing pulse to +10 mV. The second action was the increase in the peak amplitude of the tail current and the slowing of the deactivation kinetics. Omega-conotoxin at 1 microM irreversibly reduced the N-like current, sparing a component that was still sensitive to 5 microM Bay K 8644. The single-channel currents recorded with the cell-attached configuration of the patch clamp revealed two distinct conductances: a large approximately 28 pS and a small approximately 16 pS, corresponding to the L- and N-like channels, respectively. Bay K 8644 at 5 microM increased the mean open time of L-like single channel currents without changing single-channel conductance.

Chlordiazepoxide block of two types of calcium channels in neuroblastoma cells.

Chlordiazepoxide is a benzodiazepine that is widely used as a minor tranquilizer. It is also effective in the treatment of acute alcohol withdrawal. In this setting, chlordiazepoxide acts as a sedative and prevents the development of epileptiform activity. Although benzodiazepines are known to augment gamma-aminobutyric acid-activated chloride channels, an action which at least partially accounts for their anticonvulsant properties, there is some evidence to suggest that voltage-activated calcium channels may also be the target of these agents. We therefore studied the effect of chlordiazepoxide in blocking two distinct types of voltage-activated calcium channels in N1E-115 neuroblastoma cells. Chlordiazepoxide reversibly blocked calcium channels in both closed and open configurations. It was slightly more potent in blocking the transient (T-type or type I) than the long-lasting (L-type or type II) type of calcium channels with apparent Ki values of 311 and 398 microM, respectively. In the presence of chlordiazepoxide, the currents of both types of calcium channel currents decayed more quickly than control, an observation that suggests open channel block. Chlordiazepoxide-induced block of T-type calcium channels was use dependent, increasing with an increase in stimulus frequency. This was due primarily to the acceleration of current decay and slowing of recovery from inactivation by chlordiazepoxide. These calcium channel blocking actions could contribute some to the sedative and anticonvulsant properties of chlordiazepoxide in patients suffering from acute alcohol withdrawal and in electric shock-induced seizures in animal models.