Phosphorylation modulates potassium conductance and gating current of perfused giant axons of squid

cAMP regulation of protein phosphatases PP1 and PP2A in brain

Normal functioning of the brain is dependent upon a complex web of communication between numerous cell types. Within neuronal networks, the faithful transmission of information between neurons relies on an equally complex organization of inter- and intra-cellular signaling systems that act to modulate protein activity. In particular, post-translational modifications (PTMs) are responsible for regulating protein activity in response to neurochemical signaling. The key second messenger, cyclic adenosine 3',5'-monophosphate (cAMP), regulates one of the most ubiquitous and influential PTMs, phosphorylation. While cAMP is canonically viewed as regulating the addition of phosphate groups through its activation of cAMP-dependent protein kinases, it plays an equally critical role in regulating removal of phosphate through indirect control of protein phosphatase activity. This dichotomy of regulation by cAMP places it as one of the key regulators of protein activity in response to neuronal signal transduction throughout the brain. In this review we focus on the role of cAMP in regulation of the serine/threonine phosphatases protein phosphatase 1 (PP1) and protein phosphatase 2A (PP2A) and the relevance of control of PP1 and PP2A to regulation of brain function and behavior.

The PLC/PKC/Ras/MEK/Kv channel pathway is involved in uncarboxylated osteocalcin-regulated insulin secretion in rats

Uncarboxylated osteocalcin, a bone matrix protein, has been proposed to regulate glucose metabolism by increasing insulin secretion, improving insulin sensitivity and stimulating β cell proliferation. Our previous study also indicated that uncarboxylated osteocalcin stimulates insulin secretion by inhibiting voltage-gated potassium (K_V) channels. The goal of this study is to further investigate the underlying mechanisms for the regulation of Kv channels and insulin secretion by uncarboxylated osteocalcin. Insulin secretion and Kv channel currents were examined by radioimmunoassay and patch-clamp technique, respectively. Calcium imaging system was applied to measure intracellular Ca²⁺ concentration ([Ca²⁺]_i). The protein levels were detected by western blot. The results showed that uncarboxylated osteocalcin potentiated insulin secretion, inhibited Kv channels and increased [Ca²⁺]_i compared to control. These effects were suppressed by phospholipase-C (PLC)/protein kinase C (PKC)/Ras/MAPK-ERK kinase (MEK) signaling pathway, indicating that this signaling pathway plays an important role in uncarboxylated osteocalcin-regulated insulinotropic effect. In addition, the results also showed that adenylyl cyclase (AC) did not influence the effect of uncarboxylated osteocalcin on insulin secretion and Kv channels, suggesting that AC is not involved in uncarboxylated osteocalcin-stimulated insulin secretion. These findings provide new insight into the mechanism of uncarboxylated osteocalcin-regulated insulin secretion.

Intrinsic plasticity induced by group II metabotropic glutamate receptors via enhancement of high-threshold KV currents in sound localizing neurons

Intrinsic plasticity has emerged as an important mechanism regulating neuronal excitability and output under physiological and pathological conditions. Here, we report a novel form of intrinsic plasticity. Using perforated patch clamp recordings, we examined the modulatory effects of group II metabotropic glutamate receptors (mGluR II) on voltage-gated potassium (KV) currents and the firing properties of neurons in the chicken nucleus laminaris (NL), the first central auditory station where interaural time cues are analyzed for sound localization. We found that activation of mGluR II by synthetic agonists resulted in a selective increase of the high-threshold KV currents. More importantly, synaptically released glutamate (with reuptake blocked) also enhanced the high-threshold KV currents. The enhancement was frequency-coding region dependent, being more pronounced in low-frequency neurons compared to middle- and high-frequency neurons. The intracellular mechanism involved the Gβγ signaling pathway associated with phospholipase C and protein kinase C. The modulation strengthened membrane outward rectification, sharpened action potentials, and improved the ability of NL neurons to follow high-frequency inputs. These data suggest that mGluR II provides a feedforward modulatory mechanism that may regulate temporal processing under the condition of heightened synaptic inputs.

ATP regulation of a large conductance voltage-gated cation channel in rough endoplasmic reticulum of rat hepatocytes

ATP-sensitive K+ channels play an important role in regulating membrane potential during metabolic stress. In this work we report the effect of ATP and ADP-Mg on a K+ channel present in the membrane of rough endoplasmic reticulum (RER) from rat hepatocytes incorporated into lipid bilayers. Channel activity was found to decrease in presence of ATP 100 microM on the cytoplasmic side and was totally inhibited at ATP concentrations greater than 0.25mM. The effect appeared voltage dependent, suggesting that the ATP binding site was becoming available upon channel opening. Channel activity was suppressed by the nonhydrolyzable ATP analog (ATPgammaS), ruling out a phosphorylation-based mechanism. Notably addition of 2.5mM ADP-Mg to the cytosolic side increased the channel open probability at negative potentials. We conclude that the large conductance voltage-gated cation channel in RER of rat hepatocytes is an ATP and ADP sensitive channel likely to be involved in cellular processes such as Ca(2+) signaling or control of membrane potential across the endoplasmic reticulum membrane.

G protein activation inhibits gating charge movement in rat sympathetic neurons

G protein-coupled receptors (GPCRs) control neuronal functions via ion channel modulation. For voltage-gated ion channels, gating charge movement precedes and underlies channel opening. Therefore, we sought to investigate the effects of G protein activation on gating charge movement. Nonlinear capacitive currents were recorded using the whole cell patch-clamp technique in cultured rat sympathetic neurons. Our results show that gating charge movement depends on voltage with average Boltzmann parameters: maximum charge per unit of linear capacitance (Q(max)) = 6.1 +/- 0.6 nC/microF, midpoint (V(h)) = -29.2 +/- 0.5 mV, and measure of steepness (k) = 8.4 +/- 0.4 mV. Intracellular dialysis with GTPgammaS produces a nonreversible approximately 34% decrease in Q(max), a approximately 10 mV shift in V(h), and a approximately 63% increase in k with respect to the control. Norepinephrine induces a approximately 7 mV shift in V(h) and approximately 40% increase in k. Overexpression of G protein beta(1)gamma(4) subunits produces a approximately 13% decrease in Q(max), a approximately 9 mV shift in V(h), and a approximately 28% increase in k. We correlate charge movement modulation with the modulated behavior of voltage-gated channels. Concurrently, G protein activation by transmitters and GTPgammaS also inhibit both Na(+) and N-type Ca(2+) channels. These results reveal an inhibition of gating charge movement by G protein activation that parallels the inhibition of both Na(+) and N-type Ca(2+) currents. We propose that gating charge movement decrement may precede or accompany some forms of GPCR-mediated channel current inhibition or downregulation. This may be a common step in the GPCR-mediated inhibition of distinct populations of voltage-gated ion channels.

Modulation of Kv3.1b potassium channel phosphorylation in auditory neurons by conventional and novel protein kinase C isozymes

In fast-spiking neurons such as those in the medial nucleus of the trapezoid body (MNTB) in the auditory brainstem, Kv3.1 potassium channels are required for high frequency firing. The Kv3.1b splice variant of this channel predominates in the mature nervous system and is a substrate for phosphorylation by protein kinase C (PKC) at Ser-503. In resting neurons, basal phosphorylation at this site decreases Kv3.1 current, reducing neuronal ability to follow high frequency stimulation. We used a phospho-specific antibody to determine which PKC isozymes control serine 503 phosphorylation in Kv3.1b-tranfected cells and in auditory neurons in brainstem slices. By using isozyme-specific inhibitors, we found that the novel PKC-delta isozyme, together with the novel PKC-epsilon and conventional PKCs, contributed to the basal phosphorylation of Kv3.1b in MNTB neurons. In contrast, only PKC-epsilon and conventional PKCs mediate increases in phosphorylation produced by pharmacological activation of PKC in MNTB neurons or by metabotropic glutamate receptor activation in Kv3.1/mGluR1-cotransfected cells. We also measured the time course of dephosphorylation and recovery of basal phosphorylation of Kv3.1b following brief high frequency electrical stimulation of the trapezoid body, and we determined that the recovery process is mediated by both novel PKC-delta and PKC-epsilon isozymes and by conventional PKCs. The association between Kv3.1b and PKC isozymes was confirmed by reciprocal coimmunoprecipitation of Kv3.1b with multiple PKC isozymes. Our results suggest that the Kv3.1b channel is regulated by both conventional and novel PKC isozymes and that novel PKC-delta contributes specifically to the maintenance of basal phosphorylation in auditory neurons.

Acoustic environment determines phosphorylation state of the Kv3.1 potassium channel in auditory neurons

Sound localization by auditory brainstem nuclei relies on the detection of microsecond interaural differences in action potentials that encode sound volume and timing. Neurons in these nuclei express high amounts of the Kv3.1 potassium channel, which allows them to fire at high frequencies with short-duration action potentials. Using computational modeling, we show that high amounts of Kv3.1 current decrease the timing accuracy of action potentials but enable neurons to follow high-frequency stimuli. The Kv3.1b channel is regulated by protein kinase C (PKC), which decreases current amplitude. Here we show that in a quiet environment, Kv3.1b is basally phosphorylated in rat brainstem neurons but is rapidly dephosphorylated in response to high-frequency auditory or synaptic stimulation. Dephosphorylation of the channel produced an increase in Kv3.1 current, facilitating high-frequency spiking. Our results indicate that the intrinsic electrical properties of auditory neurons are rapidly modified to adjust to the ambient acoustic environment.

A model of the rat phrenic motor neuron

We have developed a model for the rat phrenic motor neuron (PMN) that robustly replicates many experimentally observed behaviors of PMNs in response to pharmacological, ionic, and electrical perturbations using a single set of parameters. Our model suggests that the after-depolarization (ADP) response seen in action potentials is a result of the slow deactivation of the fast sodium channel in the range of the ADP coupled with the activation of the L-type calcium channel (I(CaL)). This current and its interactions with the small and large conductance calcium-activated potassium currents (I(KCaSK) and I(KCaBK), respectively) is also important in the generation of spike frequency adaptation in the repetitive firing mode of activity. Other aspects of the model conform very well to experimental observations in both the action potential and repetitive firing mode of activity, including the role of I(KCaSK) in the medium after-hyperpolarization (AHP) and the role of I(KCaBK) in the fast AHP. We have made a number of predictions using the model, including the characterization of two putative sodium currents (fast and persistent), as well as functional roles for the N- and T-type calcium currents.

Outward Currents in Rat Entorhinal Cortex Stellate Cells Studied with Conventional and Perforated Patch Recordings

We have studied outward currents of neurons acutely isolated from superficial layers of the entorhinal cortex with whole-cell patch-clamp recordings. If cells were held more negative than -50 mV, depolarizing voltage commands activated a transient A-type current together with a sustained outward current. Both currents were sensitive to 4-aminopyridine, while only the sustained current was blocked by tetraethylammonium. The sustained outward current showed a considerable rundown in amplitude over prolonged recording periods. At the same time its half-maximal inactivation shifted from -74 to -114 mV. Nystatin perforated patch recordings were used to minimize these perfusion effects. Under such conditions the amplitude and the steady-state inactivation properties of the sustained outward current remained stable for more than 1 h. Pharmacological investigations revealed that only a small part of the sustained outward current could be attributed to a calcium-activated potassium current. Therefore most of the rundown has to be due to changes in the delayed rectifier outward current. These results may suggest that the delayed rectifier current is under considerable metabolic control.

Kv3 channels: voltage-gated K+ channels designed for high-frequency repetitive firing

Analysis of the Kv3 subfamily of K(+) channel subunits has lead to the discovery of a new class of neuronal voltage-gated K(+) channels characterized by positively shifted voltage dependencies and very fast deactivation rates. These properties are adaptations that allow these channels to produce currents that can specifically enable fast repolarization of action potentials without compromising spike initiation or height. The short spike duration and the rapid deactivation of the Kv3 currents after spike repolarization maximize the quick recovery of resting conditions after an action potential. Several neurons in the mammalian CNS have incorporated into their repertoire of voltage-dependent conductances a relatively large number of Kv3 channels to enable repetitive firing at high frequencies - an ability that crucially depends on the special properties of Kv3 channels and their impact on excitability.

Nerve conduction and ATP concentrations in sciatic-tibial and medial plantar nerves of hens given phenyl saligenin phosphate

To assess the relationship of nerve conduction and adenosine triphosphate (ATP) status in organophosphorus-induced delayed neuropathy (OPIDN), we evaluated both in adult hen peripheral nerves following exposure to a single 2.5 mg/kg dose of phenyl saligenin phosphate (PSP). ATP concentrations were determined at days 2, 4, 7, and 14 post-dosing, from five segments (n = 5 per group) representing the entire length of the sciatic-tibial and medial plantar nerve. Initial effects of PSP dosing were seen in the most distal segment at day 2, when a transient ATP concentration increase (388 +/- 79 pmol/ml/mg versus control value of 215 +/- 23, P < 0.05) was noted. Subsequently, ATP concentration in this distal segment returned to normal. In the most proximal nerve segment, ATP concentrations were decreased on day 7, and further decreased on day 14 post-dosing (P < 0.05). Changes in ATP concentration and nerve conduction velocity begin at post-dosing day 2, and were found prior to development of clinical neuropathy and axonopathic lesions. These results suggest that alterations in sciatic-tibial and medial plantar nerve conduction associated with sciatic-tibial and medial plantar nerve ATP concentration are early events in the development of OPIDN.

Coregulation of voltage-dependent kinetics of Na(+) and K(+) currents in electric organ

The electric organ cells of Sternopygus generate action potentials whose durations vary over a fourfold range. This variation in action potential duration is the basis for individual variation in a communication signal. Thus, action potential duration must be precisely regulated in these cells. We had observed previously that the inactivation kinetics of the electrocyte Na(+) current show systematic individual variation. In this study, using a two-electrode voltage clamp, we found that the voltage-dependent activation and deactivation kinetics of the delayed rectifying K(+) current in these cells covary in a graded and predictable manner across fish. Furthermore, when Na(+) and K(+) currents were recorded in the same cell, their voltage-dependent kinetics were highly correlated. This finding illustrates an unprecedented degree of coregulation of voltage-dependent properties in two molecularly distinct ionic channels. Such a coregulation of ionic channels is uniquely observable in a cell specialized to generate individual differences in electrical activity and in which the results of biophysical control mechanisms are evident in behaving animals. We propose that the precise coregulation of the voltage-dependent kinetics of multiple ionic currents may be a general mechanism for regulation of membrane excitability.

Coregulation of voltage-dependent kinetics of Na(+) and K(+) currents in electric organ

The electric organ cells of Sternopygus generate action potentials whose durations vary over a fourfold range. This variation in action potential duration is the basis for individual variation in a communication signal. Thus, action potential duration must be precisely regulated in these cells. We had observed previously that the inactivation kinetics of the electrocyte Na(+) current show systematic individual variation. In this study, using a two-electrode voltage clamp, we found that the voltage-dependent activation and deactivation kinetics of the delayed rectifying K(+) current in these cells covary in a graded and predictable manner across fish. Furthermore, when Na(+) and K(+) currents were recorded in the same cell, their voltage-dependent kinetics were highly correlated. This finding illustrates an unprecedented degree of coregulation of voltage-dependent properties in two molecularly distinct ionic channels. Such a coregulation of ionic channels is uniquely observable in a cell specialized to generate individual differences in electrical activity and in which the results of biophysical control mechanisms are evident in behaving animals. We propose that the precise coregulation of the voltage-dependent kinetics of multiple ionic currents may be a general mechanism for regulation of membrane excitability.

Protein kinase C inhibits Kv1.1 potassium channel function

The regulation by protein kinase C (PKC) of recombinant voltage-gated potassium (K) channels in frog oocytes was studied. Phorbol 12-myristate 13-acetate (PMA; 500 nM), an activator of PKC, caused persistent and large (up to 90%) inhibition of mouse, rat, and fly Shaker K currents. K current inhibition by PMA was blocked by inhibitors of PKC, and inhibition was not observed in control experiments with PMA analogs that do not activate PKC. However, site-directed substitution of potential PKC phosphorylation sites in the Kv1.1 protein did not prevent current inhibition by PMA. Kv1.1 current inhibition was also not accompanied by changes in macroscopic activation kinetics or in the conductance-voltage relationship. In Western blots, Kv1.1 membrane protein was not significantly reduced by PKC activation. The injection of oocytes with botulinum toxin C3 exoenzyme blocked the PMA inhibition of Kv1. 1 currents. These data are consistent with the hypothesis that PKC-mediated inhibition of Kv1.1 channel function occurs by a novel mechanism that requires a C3 exoenzyme substrate but does not alter channel activation gating or promote internalization of the channel protein.

Phosphorylation of the Kv2.1 K+ channel alters voltage-dependent activation

The voltage-gated delayed-rectifier-type K+ channel Kv2.1 is expressed in high-density clusters on the soma and proximal dendrites of mammalian central neurons; thus, dynamic regulation of Kv2.1 would be predicted to have an impact on dendritic excitability. Rat brain Kv2.1 polypeptides are phosphorylated extensively, leading to a dramatically increased molecular mass on sodium dodecyl sulfate gels. Phosphoamino acid analysis of Kv2.1 expressed in transfected cells and labeled in vivo with 32P shows that phosphorylation was restricted to serine residues and that a truncation mutant, DeltaC318, which lacks the last 318 amino acids in the cytoplasmic carboxyl terminus, was phosphorylated to a much lesser degree than was wild-type Kv2.1. Whole-cell patch-clamp studies showed that the voltage-dependence of activation of DeltaC318 was shifted to more negative membrane potentials than Kv2.1 without differences in macroscopic kinetics; however, the differences in the voltage-dependence of activation between Kv2.1 and DeltaC318 were eliminated by in vivo intracellular application of alkaline phosphatase, suggesting that these differences were due to differential phosphorylation. Similar analyses of other truncation and point mutants indicated that the phosphorylation sites responsible for the observed differences in voltage-dependent activation lie between amino acids 667 and 853 near the distal end of the Kv2.1 carboxyl terminus. Together, these parallel biochemical and electrophysiological results provide direct evidence that the voltage-dependent activation of the delayed-rectifier K+ channel Kv2. 1 can be modulated by direct phosphorylation of the channel protein; such modulation of Kv2.1 could dynamically regulate dendritic excitability.

Fast inactivation of delayed rectifier K conductance in squid giant axon and its cell bodies

Inactivation of delayed rectifier K conductance (gk) was studied in squid giant axons and in the somata of giant fiber lobe (GFL) neurons. Axon measurements were made with an axial wire voltage clamp by pulsing to VK (approximately -10 mV in 50-70 mM external K) for a variable time and then assaying available gK with a strong, brief test pulse. GFL cells were studied with whole-cell patch clamp using the same prepulse procedure as well as with long depolarizations. Under our experimental conditions (12-18 degrees C, 4 mM internal MgATP) a large fraction of gK inactivates within 250 ms at -10 mV in both cell bodies and axons, although inactivation tends to be more complete in cell bodies. Inactivation in both preparations shows two kinetic components. The faster component is more temperature-sensitive and becomes very prominent above 12 degrees C. Contribution of the fast component to inactivation shows a similar voltage dependence to that of gK, suggesting a strong coupling of this inactivation path to the open state. Omission of internal MgATP or application of internal protease reduces the amount of fast inactivation. High external K decreases the amount of rapidly inactivating IK but does not greatly alter inactivation kinetics. Neither external nor internal tetraethylammonium has a marked effect on inactivation kinetics. Squid delayed rectifier K channels in GFL cell bodies and giant axons thus share complex fast inactivation properties that do not closely resemble those associated with either C-type or N-type inactivation of cloned Kvl channels studied in heterologous expression systems.

Cytoplasmic ATP-dependent regulation of ion transporters and channels: mechanisms and messengers

Many ion transporters and channels appear to be regulated by ATP-dependent mechanisms when studied in planar bilayers, excised membrane patches, or with whole-cell patch clamp. Protein kinases are obvious candidates to mediate ATP effects, but other mechanisms are also implicated. They include lipid kinases with the generation of phosphatidylinositol phosphates as second messengers, allosteric effects of ATP binding, changes of actin cytoskeleton, and ATP-dependent phospholipases. Phosphatidylinositol-4,5-bisphosphate (PIP2) is a possible membrane-delimited messenger that activates cardiac sodium-calcium exchange, KATP potassium channels, and other inward rectifier potassium channels. Regulation of PIP2 by phospholipase C, lipid phosphatases, and lipid kinases would thus tie surface membrane transport to phosphatidylinositol signaling. Sodium-hydrogen exchange is activated by ATP through a phosphorylation-independent mechanism, whereas ion cotransporters are activated by several protein kinase mechanisms. Ion transport in epithelium may be particularly sensitive to changes of cytoskeleton that are regulated by ATP-dependent cell signaling mechanisms.

Layer-specific properties of the transient K current (IA) in piriform cortex

Piriform cortex in the rat is highly susceptible to induction of epileptiform activity. Experiments in vivo and in vitro indicate that this activity originates in endopiriform nucleus (EN). In slices, EN neurons are more excitable than layer II (LII) pyramidal cells, with more positive resting potentials and lower spike thresholds. We investigated potassium currents in EN and LII to evaluate their contribution to these differences in excitability. Whole-cell currents were recorded from identified cells in brain slices. A rapidly inactivating outward current (IA) had distinct properties in LII (IA,LII) versus EN (IA,EN). The peak amplitude of IA,EN was 45% smaller than IA,LII, and the kinetics of activation and inactivation was significantly slower for IA,EN. The midpoint of steady-state inactivation was hyperpolarized by 10 mV for IA,EN versus IA,LII, whereas activation was similar in the two cell groups. Other voltage-dependent potassium currents were indistinguishable between EN and LII. Simulations using a compartmental model of LII cells argue that different cellular distributions of IA channels in EN versus LII cells cannot account for these differences. Thus, at least some of the differences are intrinsic to the channels themselves. Current-clamp simulations suggest that the differences between IA,LII and IA,EN can account for the observed difference in resting potentials between the two cell groups. Simulations show that this difference in resting potential leads to longer first spike latencies in response to depolarizing stimuli. Thus, these differences in the properties of IA could make EN more susceptible to induction and expression of epileptiform activity.

Layer-specific properties of the transient K current (IA) in piriform cortex

Piriform cortex in the rat is highly susceptible to induction of epileptiform activity. Experiments in vivo and in vitro indicate that this activity originates in endopiriform nucleus (EN). In slices, EN neurons are more excitable than layer II (LII) pyramidal cells, with more positive resting potentials and lower spike thresholds. We investigated potassium currents in EN and LII to evaluate their contribution to these differences in excitability. Whole-cell currents were recorded from identified cells in brain slices. A rapidly inactivating outward current (IA) had distinct properties in LII (IA,LII) versus EN (IA,EN). The peak amplitude of IA,EN was 45% smaller than IA,LII, and the kinetics of activation and inactivation was significantly slower for IA,EN. The midpoint of steady-state inactivation was hyperpolarized by 10 mV for IA,EN versus IA,LII, whereas activation was similar in the two cell groups. Other voltage-dependent potassium currents were indistinguishable between EN and LII. Simulations using a compartmental model of LII cells argue that different cellular distributions of IA channels in EN versus LII cells cannot account for these differences. Thus, at least some of the differences are intrinsic to the channels themselves. Current-clamp simulations suggest that the differences between IA,LII and IA,EN can account for the observed difference in resting potentials between the two cell groups. Simulations show that this difference in resting potential leads to longer first spike latencies in response to depolarizing stimuli. Thus, these differences in the properties of IA could make EN more susceptible to induction and expression of epileptiform activity.

Elimination of rapid potassium channel inactivation by phosphorylation of the inactivation gate

The effect of protein kinase C (PKC) on rapid N-type inactivation of K+ channels has not been reported previously. We found that PKC specifically eliminates rapid inactivation of a cloned human A-type K+ channel (hKv3.4), converting this channel from a rapidly inactivating A type to a noninactivating delayed rectifier type. Biochemical analysis showed that the N-terminal domain of hKv3.4 is phosphorylated in vitro by PKC, and mutagenesis experiments revealed that two serines within the inactivation gate at the N-terminus are sites of direct PKC action. Moreover, mutating one of these serines to aspartic acid mimics the action of PKC. Serine phosphorylation may thus prevent rapid inactivation by shielding basic residues known to be critical to the function of the inactivation gate. The regulatory mechanism reported here may have substantial effects on signal coding in the nervous system.

Regulation of Shaker K+ channel inactivation gating by the cAMP-dependent protein kinase

In response to depolarization of the membrane potential, Shaker K+ channels undergo a series of voltage-dependent conformational changes, from resting to open conformations followed by a rapid transition into a long-lived closed conformation, the N-type inactivated state. Application of phosphatases to the cytoplasmic side of Shaker channels in excised inside-out patches slows N-type inactivation gating. Subsequent application of the purified catalytic subunit of the cAMP-dependent protein kinase (PKA) and ATP reverses the effect, accelerating N-type inactivation back to its initial rapid rate. Macroscopic and single-channel experiments indicate that N-type inactivation is selectively modulated. There was little or no effect on the voltage dependence and kinetics of activation. Comparison of site-directed mutant channels shows that a C-terminal consensus site for PKA phosphorylation is responsible for the modulation. Since a cell's integrative characteristics can be determined by the rate of inactivation of its voltage-dependent channels, modulation of these rates by phosphorylation is likely to have functional consequences.

Some effects of short-chain phospholipids and n-alkanes on a transient potassium current (IA) in identified Helix neurons

Many effects of short-chain phospholipids and n-alkanes on the squid axon sodium current (INa) are consistent with mechanisms involving changes in membrane thickness. Here, we suggest that the actions of short-chain phospholipids on an A-type potassium current (IA) in two-microelectrode voltage clamped Helix D1 and F77 neurons are incompatible with such simple mechanisms. Diheptanoyl phosphatidylcholine (diC7PC, 0.2 and 0.3 mM) caused substantial (58 and 79%), and in some cases partially reversible, increases in IA amplitude. These were correlated with hyperpolarizing shifts of up to -7 mV in the voltage dependence of current activation. The voltage dependence of steady-state inactivation was also moved in the hyperpolarizing direction. These effects are the opposite of those described for squid INa. 0.5 Saturated n-pentane and saturated n-hexane caused significant (-3 and -6 mV) hyperpolarizing shifts in the voltage dependence of IA inactivation, qualitatively consistent with their effects on squid INa, while the voltage dependence of activation was moved slightly to the left or unchanged. Hydrocarbons had variable effects on peak current amplitude, although saturated n-pentane produced a clear suppression. DiC7PC caused a 25% increase in the time constant of macroscopic IA inactivation (tau b) but 0.5 saturated n-pentane and saturated n-hexane reduced tau b by 40%. The effects of these agents on current-clamped cells were broadly consistent with their opposing actions on tau b--phospholipids tended to reduce excitability and n-alkanes tended to increase it. Possible mechanisms of IA perturbation are discussed.

Intracellular ATP modifies the voltage dependence of the fast transient outward K+ current in Lymnaea stagnalis neurones

1. The action of intracellular ATP on the fast transient outward K+ current (A-current) was studied in dialysed voltage-clamped Lymnaea stagnalis neurones. 2. When introduced intracellularly in millimolar concentrations ATP caused a shift of the steady-state inactivation curve along the voltage axis in the direction of positive potentials and decreased A-current at all test voltages. 3. Intracellular treatment with an inhibitor of ATP synthesis, sodium arsenate, led to the opposite changes. The action of arsenate was not reversed upon its removal. After wash-out of arsenate ATP restored the initial voltage dependence. 4. Addition of Mg2+ to the solution weakened the action of ATP in proportion to the Mg2+: ATP concentration ratio. On the other hand, in neurones pretreated with arsenate, Mg2+ did not affect the ATP action. 5. When a mixture of glycolytic substrates was applied after arsenate wash-out the activation and inactivation curves shifted towards positive voltages. A substrate of oxidative phosphorylation was ineffective in the same conditions. 6. Non-hydrolysable analogues of ATP, adenosine-5'-O-gamma-thiotriphosphate and adenylyl imidodiphosphate, did not mimic the ATP action. This means that the ATP effect is mediated by some enzymatic process(es). 7. Elevation of total cytosolic Ca2+ concentration as well as intracellular application of agents increasing intracellular free Ca2+ reduced A-current amplitude but failed to alter its voltage dependence. Therefore, ATP action cannot be related to activation of Ca2+ transport. 8. Treatment of the neurones with alkaline phosphatase evoked a shift of the inactivation voltage dependence towards hyperpolarizing potentials and increased the A-current amplitudes at all test voltages. 9. The data indicate that a change in intracellular ATP concentration modulates the A-current voltage dependence. The effect of ATP is probably the result of phosphorylation of a channel protein or some associated proteins, but lowering of free Mg2+ concentration cannot be excluded. The possible physiological significance of the phenomenon is discussed.

Cloning and expression of an inwardly rectifying ATP-regulated potassium channel

A complementary DNA encoding an ATP-regulated potassium channel has been isolated by expression cloning from rat kidney. The predicted 45K protein, which features two potential membrane-spanning helices and a proposed ATP-binding domain, represents a major departure from the basic structural design characteristic of voltage-gated and second messenger-gated ion channels. But the presence of an H5 region, which is likely to form the ion conduction pathway, indicates that the protein may share a common origin with voltage-gated potassium channel proteins.

Inactivation of the Ba2+ current in dissociated Helix neurons: voltage dependence and the role of phosphorylation

The rate of inactivation of the voltage-dependent Ba2+ current in dissociated neurons from the snail Helix aspersa was found to be modulated by phosphorylation. Conditions were chosen such that the most likely mechanism of inactivation of the Ba2+ current was a voltage-dependent/calcium-independent inactivation process. If adenosine-triphosphate (ATP) was not included in the patch electrode filling solution, or if alkaline phosphatase was added, the Ba2+ current rapidly ran down and the rate of inactivation greatly increased with time. Dialysis with either ATP gamma S or the phosphatase inhibitor okadaic acid (OA) either enhanced the amplitude or greatly reduced the rate of run-down of the Ba2+ current (depending upon the presence of ATP), as well as reducing the rate of inactivation. However, dialysis with either the catalytic subunit of the cyclic-adenosine-mono-phosphate-dependent protein kinase (cAMP-PK), a synthetic peptide inhibitor of this enzyme, or staurosporine (a potent inhibitor of protein kinase C), did not have any significant effect on the amplitude or kinetics of the Ba2+ current. Surprisingly, dialysis with a peptide inhibitor (CKIP) of the Ca2+/calmodulin-dependent protein kinase II (Ca(2+)-CaM-PK) significantly reduced the rate of inactivation of this current. These results suggest that phosphorylation may exert its effect by modulating the gating properties of the Ca2+ channels.

Patch-clamp analysis of voltage-gated currents in intermediate lobe cells from rat pituitary thin slices

Ionic currents of hypophyseal intermediate lobe cells were studied using a thin-slice preparation of the rat pituitary in conjunction with conventional and perforated whole-cell patch-clamp recording techniques. A majority (89%) of the cells studied generated Na+, Ca2+ and K+ currents upon depolarizing voltage steps and responded to bath application of gamma-aminobutyric acid (GABA; 20-50 microM) with inward currents (in symmetrical chloride, holding potential -80 mV). A small percentage of cells (11%) did not display inward membrane currents upon depolarization and was unresponsive to GABA. In the first type of cells, Ca2+ and K+ currents were further studied in isolation. Ca2+ tail currents showed a biphasic time course upon repolarization, with time constants and amplitudes of 2.07 +/- 0.29 ms, 123 +/- 22 pA (for the slowly deactivating component) and 0.14 +/- 0.06 ms, 437 +/- 33 pA (for the fast-deactivating component; means +/- SD of n = 4 cells). Slowly and fast-deactivating conductances were half-maximally activated at around -10 mV and +10 mV respectively. Depolarizing voltage steps elicited two types of K+ current, which were separated using a prepulse protocol. A fast-activating, transient component showed half-maximal steady-state inactivation between -65 mV and -45 mV depending on the divalent cation composition of the external solution. Its decay was fitted by single-exponential functions with time constants of 36 +/- 11 ms and 3.9 +/- 0.9 ms at -20 mV and +40 mV respectively (mean +/- SD; n = 4 cells). Whereas the peak current amplitudes of the transient K+ current component remained stable, the amplitude of the second, delayed component increased progressively throughout the course of whole-cell experiments. In cells recorded with the perforated whole-cell technique, bath application of dopamine (10 nM-1 microM) induced large hyperpolarizations from a spontaneous membrane potential of -40 mV, but did not consistently affect the amplitude of the voltage-gated K+ conductances. These data are compared to previous studies using other preparations of the intermediate lobe, and differences are discussed, thus helping to extend our knowledge of electrical excitability of hypophyseal cells.

Role of calcium and protein kinase C in development of the delayed rectifier potassium current in Xenopus spinal neurons

The delayed rectifier current of embryonic Xenopus spinal neurons plays the central role in developmental conversion of calcium-dependent action potentials to sodium-dependent spikes. During its maturation, this potassium current undergoes a pronounced increase in rate of activation. The mechanism underlying the change in kinetics was analyzed with whole-cell voltage clamp of neurons cultured under various conditions. Calcium is necessary at an early stage of development, to permit influx that triggers subsequent release of calcium from intracellular stores. Its action is prevented by depletion of protein kinase C and mimicked by stimulation of the kinase. Calcium influx through voltage-dependent channels at early stages of development regulates the differentiation of potassium current kinetics and modulation of the ionic dependence of action potentials.

Phosphorylation shifts the time-dependence of cardiac Ca++ channel gating currents

A general mechanism for the physiological regulation of the activity of voltage-dependent Na+, Ca++, K+, and Cl channels by neurotransmitters in a variety of excitable cell types may involve a final common pathway of a cyclic AMP-dependent phosphorylation of the channel protein. The functional correlates of channel phosphorylation are known to involve a change in the probability of opening, and a negative or positive shift in the voltage dependence for activation of the conductance. The voltage dependence for activation appears to be governed by the properties of the charge movement of the voltage-sensing moiety of the channel. This study of the gating charge movement of cardiac Ca++ channels has revealed that isoproterenol or cAMP (via a presumed phosphorylation of the channel) speeds the kinetics of the Ca++ channel gating charge movement. These results suggest that the changes in the kinetics and voltage dependence of the cardiac calcium currents produced by beta-adrenergic stimulation are initiated, in part, by parallel changes in the gating charge movement.

Phosphorylation of K+ channels in the squid giant axon. A mechanistic analysis

Protein phosphorylation is an important mechanism in the modulation of voltage-dependent ionic channels. In squid giant axons, the potassium delayed rectifier channel is modulated by an ATP-mediated phosphorylation mechanism, producing important changes in amplitude and kinetics of the outward current. The characteristics and biophysical basis for the phosphorylation effects have been extensively studied in this preparation using macroscopic, single-channel and gating current experiments. Phosphorylation produces a shift in the voltage dependence of all voltage-dependent parameters including open probability, slow inactivation, first latency, and gating charge transferred. The locus of the effect seems to be located in a fast 20 pS channel, with characteristics of delayed rectifier, but at least another channel is phosphorylated under our experimental conditions. These results are interpreted quantitatively with a mechanistic model that explains all the data. In this model the shift in voltage dependence is produced by electrostatic interactions between the transferred phosphate and the voltage sensor of the channel.

Modulation of acetylcholine-activated K+ channel function in rat atrial cells by phosphorylation

1. In voltage-clamped whole cells dialysed with GTP, extracellular application of ACh elicits an inwardly rectifying K+ current which subsequently decreases to a steady-state level well below the maximally induced current (desensitization). The mechanism of desensitization of the acetylcholine (ACh)-activated K+ channel current was studied in rat neonatal atrial cells at the single-channel level using the patch-clamp technique. 2. In cell-attached patches with ACh in the pipette, a similar pattern of K+ channel current desensitization was present. Single-channel analyses revealed that the initial rapid decrease in channel activity was associated with progressive shortening of the mean open time (tau o) and prolongation of the mean closed time (tau c) of the K+ channel. 3. In excised, inside-out patches with ACh in the pipette, GTP activated K+ channels with a tau o of approximately 1.0 ms. Addition of ATP to the cytosolic surface resulted in progressive increases in tau o (from 1 to 5 ms) and channel activity. These changes are similar but opposite in direction to those observed during the early phase of ACh-induced channel desensitization in cell-attached patches. 4. The effect of ATP on the channel kinetics was abolished in Mg(2+)-free solution AMP-PNP (adenylyl-imidodiphosphate, a non-hydrolysable analogue of ATP), ADP, CTP (cytidine triphosphate), ITP (inosine triphosphate) or UTP (uridine triphosphate) did not alter the channel kinetics, suggesting that the ATP effect on channel gating probably occurs via phosphorylation by a membrane-bound kinase. H-8 (an isoquinolinesulphonamide derivative which inhibits protein kinases A and C) failed to prevent the action of ATP on the channel. 5. The increases in tau o and channel activity produced by ATP could be completely reversed by an elevation of cytosolic [Ca2+] to 3 x 10(-5) M or above. 6. The effect of Ca2+ on the ATP-induced changes in channel kinetics was blocked by sodium vanadate, a general phosphatase inhibitor. Okadaic acid, an inhibitor of protein phosphatase 1 and 2A, did not block the Ca2+ effect. Calmodulin antagonists, N-(6-aminohexyl)-5-chloro-1-naphthalenesulphonamide (W-7), trifluoroperazine, and calmidazolium, partially blocked the effect of Ca2+. 7. Alkaline phosphatase (20 units/ml) reversed the ATP-induced increases in tau o and channel activity. These results suggest that the ACh-activated K+ channel can be modulated by phosphorylation and dephosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)

Ion channels in transit: voltage-gated Na and K channels in axoplasmic organelles of the squid Loligo pealei

Ion channels that give rise to the excitable properties of the neuronal plasma membrane are synthesized, transported, and degraded in cytoplasmic organelles. To determine whether plasma membrane ion channels from these organelles could be physiologically activated, we extruded axoplasm from squid giant axons, dissociated organelles from the cytoskeletal matrix, and fused the free organelles with planar lipid bilayers. Three classes of ion channels normally associated with the plasma membrane were identified based on conductance, selectivity, and gating properties determined from steady-state single-channel recordings: (i) voltage-dependent Na channels, (ii) voltage-dependent delayed rectifier K channels, and (iii) large, voltage-independent K channels. The identity of the delayed rectifier channels was confirmed by reconstructing the time course of activation from single-channel responses to depolarizing voltage steps applied across the bilayer. These observations suggest that several classes of plasma membrane ion channels are transported in cytoplasmic organelles in physiologically active forms.

Gating currents of inactivating and non-inactivating potassium channels expressed in Xenopus oocytes

The Xenopus oocyte expression system in combination with patch-clamp techniques allows the measurement of ionic currents from a single class of genetically engineered ion channels. Ionic currents in the nanoampere range from oocytes injected with cRNA, corresponding to potassium channels, can be recorded in the inside-out patch configuration. These recordings have a high time resolution at low background noise. Substitution of impermeant ions for potassium and blocking of the channel conductance with tetraethylammonium allows the recording of potassium gating currents, Ig, which is hampered in natural excitable cells by the simultaneous presence of sodium channels and a variety of different potassium channels. The "on" transients, Ig(on), are fast and can have amplitudes of up to several tens of pA. Upon repolarization to -100 mV after small depolarizations, "off" gating currents, Ig(off)g, which reverse most of the "on" charge displacement, Q(on), within 1 ms, are readily observed. However, this fast recovery of the gating charge is drastically reduced upon increasing the amplitude of the depolarizing pulse. In contrast to sodium channels, this temporary charge immobilization is complete within a few milliseconds at positive membrane potentials. Furthermore, there seems to be no direct correlation between charge immobilization and inactivation because the same phenomenon occurs for channels that do not inactivate.

The quantal gating charge of sodium channel inactivation

Using a very low noise voltage clamp technique it has been possible to record from the squid giant axon a slow component of gating current (Ig) during the inactivation phase of the macroscopic sodium current (INa) which was hitherto buried in the baseline noise. In order to examine whether this slow Ig contains gating charge that originates from transitions between the open (O) and the inactivated (I) states, which would indicate a true voltage dependence of inactivation, or whether other transitions contribute charge to slow Ig, a new model independent analysis termed isochronic plot analysis has been developed. From a direct correlation of Ig and the time derivative of the sodium conductance dgNa/dt the condition when only O-I transitions occur is detected. Then the ratio of the two signals is constant and a straight line appears in an isochronic plot of Ig vs. dgNa/dt. Its slope does not depend on voltage or time and corresponds to the quantal gating charge of the O-I transition (qh) divided by the single channel ionic conductance (gamma). This condition was found at voltages above -10 mV up to +40 mV and a figure of 1.21 e- was obtained for qh at temperatures of 5 and 15 degrees C. At lower voltages additional charge from other transitions, e.g. closed to open, is displaced during macroscopic inactivation. This means that conventional Eyring rate analysis of the inactivation time constant tau h is only valid above -10 mV and here the figure for qh was confirmed also from this analysis. It is further shown that most of the present controversies surrounding the voltage dependence of inactivation can be clarified. The validity of the isochronic plot analysis has been confirmed using simulated gating and ionic currents.

Effects of protein kinase inhibitors on canine Purkinje fibre pacemaker depolarization and the pacemaker current i(f)

1. The effects of the protein kinase inhibitors H-7 and H-8 were investigated on diastolic depolarization of the action potential with microelectrodes and on the pacemaker current if with the two-microelectrode voltage clamp in canine cardiac Purkinje fibres. 2. Both 200 microM-H-7 and 100 microM-H-8 had no significant effect on the slope of diastolic depolarization but eliminated the actions of isoprenaline (1 microM). 3. We examined the actions of H-7 and H-8 on if in the presence and absence of isoprenaline. H-7 (200 microM) shifted the pacemaker current if in the negative direction on the voltage axis, whereas 100 microM-H-8 had no significant effect by itself. Both 200 microM-H-7 and 100 microM-H-8 can reverse or prevent the actions of isoprenaline (1-5 microM) on if. 4. We applied activators of the cyclic AMP cascade down-stream to the beta-receptor, to further evaluate where H-7 and H-8 might be exerting their effects. When exposing Purkinje fibres to an adenylyl cyclase activator (forskolin, 10-50 microM), a phosphodiesterase inhibitor (IBMX, 100 microM) and a permeable cyclic AMP analogue (8-chlorophenylthio-cyclic AMP, 200 microM-1 mM), the amplitude of if was increased. H-7 and H-8 at 100-200 microM eliminated each of these actions. 5. These results suggest that a phosphorylation process is involved in the modulation of the pacemaker current, if, in Purkinje fibres. The different actions of H-7 and H-8 on basal if suggest the hypothesis that other protein kinases, possibly protein kinase C, might also be involved in regulating basal phosphorylation of if in Purkinje fibres.

Regulation of transmitter release at the squid giant synapse by presynaptic delayed rectifier potassium current

1. The three-microelectrode voltage clamp technique and pharmacological agents were used to examine the properties and functions of potassium currents in squid giant presynaptic terminals. 2. Outward currents consisted of two components: a slow component which activated over hundreds of milliseconds and was blocked by extracellular application of tetraethylammonium (TEA) ions and a more rapidly activating component which was relatively insensitive to extracellular TEA. 3. The more rapid component was studied in isolation by treating presynaptic terminals with extracellular TEA, as well as tetrodotoxin (to block sodium channel currents) and manganese (to block calcium channel currents). The magnitude of this current component was 1-2 mA cm-2 at 0 mV. Rates of activation and deactivation were voltage dependent and little evidence of inactivation was seen for depolarizations less than several seconds in duration. 4. The reversal potential of the current was -70 to -80 mV in normal saline and became more positive with elevated extracellular potassium concentrations, suggesting that potassium is the primary permeant ion. Accumulation of extracellular potassium appeared to be marked during depolarizations that produced significant activation of the current. 5. Extracellular application of 3,4-diaminopyridine (DAP) blocked the current with an apparent dissociation constant of 7 microM at 0 mV. Intracellular applications of DAP and TEA also were effective in reducing this current. These treatments, but not extracellular TEA application, broadened presynaptic action potentials and increased the magnitude and time-to-peak of postsynaptic currents elicited by the broadened presynaptic action potentials. Postsynaptic currents were a sensitive and linear function of action potential duration; a 30% increase in action potential duration increased postsynaptic current amplitude by 190%. 6. Estimation of the magnitude and time course of the presynaptic calcium current, based on previous measurements of calcium channel gating, indicated that action potential broadening produces a large increase in calcium current magnitude. These calculations predict that a 30% increase in presynaptic action potential duration will increase the peak amplitude of the calcium current by approximately 170% and the total amount of calcium entry by approximately 230%. This implies a linear relationship between transmitter release and calcium entry during an action potential and can be explained by assuming that calcium co-operatively triggers release within intracellular domains that do not overlap.(ABSTRACT TRUNCATED AT 400 WORDS)