Modulation Of IK Research Articles

Involvement of the TREK-1 channel in human alveolar cell membrane potential and its regulation by inhibitors of the chloride current.

K+ channels of the alveolar epithelium control the driving force acting on the ionic and solvent flow through the cell membranecontributing to the maintenance of cell volume and the constitution of epithelial lining fluid. In the present work, we analyze the effect of the Cl- channelinhibitors: (4-[(2-butyl-6,7-dichloro-2-cyclopentyl-2,3-dihydro-1-oxo-inden-5-yl)oxy] butanoic acid (DCPIB) and 9-anthracenecarboxylic acid (9-AC) on the total current in a type II pneumocytes (A549 cell line) model by patch clamp, immunocytochemical, and gene knockdown techniques. We noted that DCPIB and 9-AC promote the activation ofK conductance. In fact, they significantly increase the intensity of the current and shift its reversal potential to values more negative than the control. By silencing outward rectifier channel in its anoctamin 6 portion, we excluded a direct involvement of Cl- ions in modulation of IK and, by means of functional tests with its specific inhibitor spadin, we identifiedthe TREK-1 channel as the presumable target of both drugs. Asthe activity of TREK-1 has a key role for the correct functioning of the alveolar epithelium, the identification of DCPIB and 9-AC molecules as its activatorssuggests their possible use to build new pharmacological tools for the modulation of this channel.

Effects of tertiapin-Q and ZD7288 on changes in sinoatrial pacemaker rhythm during vagal stimulation.

Heart rate slowing produced by cardiac parasympathetic (vagal) stimulation is thought to be the result of modulation of the acetylcholine-activated K(+) current (IK,ACh) and the pacemaker current (If) in sinoatrial (SAN) pacemaker cells. However, the contribution of these and other ion currents to vagal slowing is controversial. Here, we examined the contributions of IK,ACh and If to vagal slowing in 15 isolated, vagal-innervated preparations of guinea-pig atria, using 300 nM tertiapin-Q (TQ) and 2 μM ZD7288 to obtain full and substantial block of these currents, respectively. Blocking IK,ACh alone reduced atrial rate responses to 10-s trains of regular vagal stimulation (supramaximal stimulation, 2-ms duration, 1-10 Hz) by ~50% (P<0.01; N=11); blocking If alone had no effect (N=7). Blocking both IK,ACh and If produced ~90% reduction (P<0.01; N=4). Atrial cycle length response to a single burst of vagal stimuli (3 stimuli at 50 Hz), delivered at the optimum phase of the cycle was strongly suppressed by blocking IK,ACh (reduced by 98%; P<0.01; N=9), and modestly reduced by blocking If alone (by ~43%; P=0.20; N=6). The response was abolished by combined block of IK,ACh and If (P=0.04; N=4). Our data show that modulation of IK,ACh and If is sufficient to account for all the vagal slowing observed in this preparation. The vagally-induced negative shift in activation potential for If will be opposed by hyperpolarisation of SAN through activation of IK,ACh. Thus removal of IK,ACh by TQ may have exaggerated the overall contribution of If to vagal slowing.

Molecular Mechanisms, and Selective Pharmacological Rescue, of Rem-Inhibited Ca V 1.2 Channels in Heart

In heart, Ca(2+) entering myocytes via Ca(V)1.2 channels controls essential functions, including excitation-contraction coupling, action potential duration, and gene expression. RGK GTPases (Rad/Rem/Rem2/Gem/Kir sub-family of Ras-like GTPases) potently inhibit Ca(V)1.2 channels, an effect that may figure prominently in cardiac Ca(2+) homeostasis under physiological and disease conditions. To define the mechanisms and molecular determinants underlying Rem GTPase inhibition of Ca(V)1.2 channels in heart and to determine whether such inhibited channels can be pharmacologically rescued. Overexpressing Rem in adult guinea pig heart cells dramatically depresses L-type calcium current (I(Ca,L)) ( approximately 90% inhibition) and moderately reduces maximum gating charge (Q(max)) (33%), without appreciably diminishing the physical number of channels in the membrane. Rem-inhibited Ca(V)1.2 channels were supramodulated by BAY K 8644 (10-fold increase) compared to control channels (3-fold increase). However, Rem prevented protein kinase A-mediated upregulation of I(Ca,L), an effect achieved without disrupting the sympathetic signaling cascade because protein kinase A modulation of I(KS) (slow component of the delayed rectifier potassium current) remained intact. In accord with its functional impact on I(Ca,L), Rem selectively prevented protein kinase A- but not BAY K 8644-induced prolongation of the cardiac action potential duration. A GTP-binding-deficient Rem[T94N] mutant was functionally inert with respect to I(Ca,L) inhibition. A chimeric construct, Rem(265)-H, featuring a swap of the Rem C-terminal tail for the analogous domain from H-Ras, inhibited I(Ca,L) and Q(max) to the same extent as wild-type Rem, despite lacking the capacity to autonomously localize to the sarcolemma. Rem predominantly inhibits I(Ca,L) in heart by arresting surface Ca(V)1.2 channels in a low open probability gating mode, rather than by interfering with channel trafficking. Moreover, Rem-inhibited Ca(V)1.2 channels can be selectively rescued by BAY K 8644 but not protein kinase A-dependent phosphorylation. Contrary to findings in reconstituted systems, Rem-induced ablation of cardiac I(Ca,L) requires GTP-binding, but not membrane-targeting of the nucleotide binding domain. These findings provide a different perspective on the molecular mechanisms and structural determinants underlying RGK GTPase inhibition of Ca(V)1.2 channels in heart, and suggest new (patho)physiological dimensions of this crosstalk.

Abstract 5347: Alpha-Adrenergic-Regulation of I K1 and Acetylcholine-gated I K,ACh is Impaired in Patients with Atrial Fibrillation

In chronic atrial fibrillation (cAF) the major effector of vagal excitation I K,ACh develops arrhythmogenic ACh-independent constitutive activity with limited additional activation via muscarinic receptors. Since the sympathetic nervous system prevents excessive vagal nerve activation we tested whether modulation of I K,ACh by adrenoceptors (ARs) is affected in cAF. I K,ACh was measured with whole-cell voltage-clamp in isolated right atrial myocytes from 29 sinus rhythm (SR) and 17 cAF patients. Compared to SR basal current was higher in cAF whereas carbachol (CCh, 2 μM)-activated I K,ACh was smaller (Figure ). Activation of beta-ARs with isoproterenol (ISO, 1 μM) increased CCh-activated I K,ACh by ~25% and ~20% in SR and cAF, respectively, whereas activation of adenylyl cyclase with forskolin (FSK, 1 μM) was without effect suggesting channel activation by G-beta/gamma-binding rather than PKA. Stimulation of alpha-1-ARs with phenylephrine (PE, 100 μM) reduced CCh-activated I K,ACh in SR by ~80%, but was ineffective in cAF. Neomycin (NEO, 500 μM), a blocker of phospholipase-C (PLC), prevented the PE effect suggesting that PE blunts I K,ACh activation via PLC-induced depletion of membrane PIP2 content required for I K,ACh stimulation. PE, but not ISO or FSK, reduced basal current in SR by ~50%, suggesting inhibition of I K1 , but was ineffective on basal current in cAF which consists of I K1 and constitutively active I K,ACh . Inhibition of CCh-activated I K,ACh and suppression of I K1 by alpha-1-ARs are impaired in cAF. These changes may shift the balance to stronger beta-AR-mediated I K,ACh activation promoting the maintenance of AF.

Model-based analysis of the β-adrenergic modulation of IKS in the guinea-pig ventricle

model-based analysis of the β-adrenergic modulation of IKS in the guinea-pig ventricle

Abstract 946: Angiotensin II Type 1 Receptor Partially Mediates Stretch-Induced Potentiation of the Slow Component of Delayed Rectifier Potassium Current in Guinea Pig Atrium

Introduction: Mechano-sensitive signal transduction in atrial myocytes is closely related to the development of atrial fibrillation (AF). A repolarizing conductance in the heart stimulated by stretch or swelling of myocytes is the slow component of the delayed rectifier K + current ( I Ks ). Modulation of I Ks appears to be linked to pathogenesis of AF because in hereditary cases, gain-of-function mutations in I Ks channel genes have been detected. Moreover, membrane stretch activates AT 1 receptor even without angiotensin II. Hypothesis: We assessed the hypothesis that activation of AT 1 receptor mediates swelling-induced increase of I Ks in atrium. Methods: Whole-cell patch-clamp method was used to record I Ks and action potentials in guinea pig atrial myocytes. Results: Exposure of atrial myocytes to 70% hyposmotic solution (210 mOsmol/L, HS) enhanced I Ks by 84.1± 8.4% ( n = 12), abbreviated atrial action potential at 90% repolarization (APD 90 ) by 16.8± 1.3%, and depolarized resting potential by 4.9±0.7 mV ( n = 9). Selective blockade of AT 1 receptor with 1 or 5 μmol/L candesartan and 5 μmol/L olmesartan significantly attenuated the HS-induced I Ks increase to 48.0±4.1% ( n = 10), 47.2±2.7% ( n = 9), and 59.4±5.5% ( n = 9), respectively. Pretreatment with 5 μmol/L olmesartan also significantly reduced the HS-evoked shortening of APD 90 to 12.4± 1.4% ( n = 10). Tyrosine kinase inhibitors tyrphostins A23 and A25 (20 μmol/L) reduced the HS-induced I Ks enhancement to 42.0± 9.5 ( n = 13) and 52.7±4.7% ( n = 12), respectively, whereas their inactive analogue A1 had little effect. Block of tyrosine phosphatases by 500 μmol/L orthovanadate further promoted the potentiation of I Ks by HS to 124.6± 10.6% ( n = 8) and markedly decreased the recovery rate of I Ks after withdrawal of HS. Pharmacological suppression of G proteins, phospholipase C, and protein kinase C did not appreciably affect the modulation of I Ks . Conclusion: These results indicate involvement of AT 1 receptor and tyrosine kinases in the hyposmotic potentiation of atrial I Ks . It is likely that in the clinical settings, AT 1 receptor antagonists can attenuate the stretch-induced I Ks increase and action potential shortening and thereby exert an acute antiarrhythmic action on stretch-related atrial arrhythmias such as AF.

Modifying the Subunit Composition of TASK Channels Alters the Modulation of a Leak Conductance in Cerebellar Granule Neurons

Two-pore domain potassium (K2P) channel expression is believed to underlie the developmental emergence of a potassium leak conductance [IK(SO)] in cerebellar granule neurons (CGNs), suggesting that K2P function is an important determinant of the input conductance and resting membrane potential. To investigate the role that different K2P channels may play in the regulation of CGN excitability, we generated a mouse lacking TASK-1, a K2P channel known to have high expression levels in CGNs. In situ hybridization and real-time PCR studies in wild-type and TASK-1 knock-outs (KOs) demonstrated that the expression of other K2P channels was unaltered in CGNs. TASK-1 knock-out mice were healthy and bred normally but exhibited compromised motor performance consistent with altered cerebellar function. Whole-cell recordings from adult cerebellar slice preparations revealed that the resting excitability of mature CGNs was no different in TASK-1 KO and littermate controls. However, the modulation of IK(SO) by extracellular Zn2+, ruthenium red, and H+ was altered. The IK(SO) recorded from TASK-1 knock-out CGNs was no longer sensitive to alkalization and was blocked by Zn2+ and ruthenium red. These results suggest that a TASK-1-containing channel population has been replaced by a homodimeric TASK-3 population in the TASK-1 knock-out. These data directly demonstrate that TASK-1 channels contribute to the properties of IK(SO) in adult CGNs. However, TASK channel subunit composition does not alter the resting excitability of CGNs but does influence sensitivity to endogenous modulators such as Zn2+ and H+.

Human beta(3)-adrenoreceptors couple to KvLQT1/MinK potassium channels in Xenopus oocytes via protein kinase C phosphorylation of the KvLQT1 protein.

Modulation of the slow component of the delayed rectifier potassium current (IKs) in heart critically affects cardiac arrhythmogenesis. Its current amplitude is regulated by the sympathetic nervous system. However, the signal transduction from the beta-adrenergic system to the KvLQT1/MinK (KCNQ1/KCNE1) potassium channel, which is the molecular correlate of the IKs current in human cardiomyocytes, is not sufficiently understood. In the human heart, three subtypes of beta-adrenergic receptors (beta(1-3)-ARs) have been identified. Only beta(1)- and beta(3)-ARs have been shown so far to be involved in the regulation of IKs. Special interest has been paid to the regulation of IKs by the beta(3)-AR because of its potential importance in congestive heart failure. In heart failure beta(1)-ARs are known to be down regulated while the density of beta(3)-ARs is increased. Unfortunately, studies on the modulation of IKs by beta(3)-AR revealed conflicting results. We investigated the functional role of protein kinase C (PKC) in the signal transduction cascade between beta3-adrenergic receptors and IKs by expressing heterologously its molecular components, the KvLQT1/MinK potassium channel, together with human beta(3)-AR in Xenopus oocytes. Membrane currents were measured with the double electrode voltage-clamp technique. Using activators and inhibitors of PKC we demonstrated that PKC is involved in this regulatory process. Experiments in which the putative C-terminal PKC-phosphorylation sites in the KvLQT1 protein were destroyed by site directed mutagenesis reduced the isoproterenol-induced current to 27+/-3,5% compared to control. These results indicate that the amplitude of KvLQT1/MinK current is mainly increased by PKC activation. Our results suggest that the regulation of the KvLQT1/MinK potassium channel via beta(3)-AR is substantially mediated by PKC phosphorylation of the KvLQT1 protein at its four C-terminal PKC phosphorylation sites.

Molecular interactions between two long-QT syndrome gene products, HERG and KCNE2, rationalized by in vitro and in silico analysis.

The cardiac delayed rectifier potassium current mediates repolarization of the action potential and underlies the QT interval of the ECG. Mutations in either of the two molecular components of the rapid delayed rectifier (I(K,r)), HERG and KCNE2, have been linked to heritable or acquired long-QT syndrome. Mechanisms whereby mutations of KCNE2 produce fatal cardiac arrhythmias characteristic of long-QT syndrome remain unclear. In this study, we characterize functional interactions between HERG and KCNE2 with a view to defining underlying mechanisms for action potential prolongation and long-QT syndrome. Whereas coexpression of hKCNE2 with HERG alters both kinetics and density of ionic current, incorporation of these effects into a quantitative model of the action potential predicts that only changes in current density significantly affect repolarization. Thus, the primary functional consequence of hKCNE2 on action potential morphology is through modulation of I(K,r) density, as predicted by the model. Mutations associated with long-QT syndrome that result only in modest changes of gating kinetics may be epiphenomena or may modulate action potential repolarization via interaction with alternative pore-forming potassium channel alpha subunits.

Dopamine depletion with 6-OHDA enhances dopamine D1-receptor modulation of potassium currents in retinal bipolar cells.

Ascorbate modulates IK(V) of ON-type mixed rod/cone bipolar cells (Mb) in the goldfish retinal slice through a dopamine D1/G-protein/PKA-coupled mechanism. We investigated the effects of dopamine depletion with intraocular injections of 6-OHDA on IK(V) and its modulation by ascorbate over 1-7 weeks following 6-OHDA treatment. Dopamine depletion was verified by tyrosine hydroxylase immunocytochemistry. Slices were perfused in a saline containing 200 microM sodium ascorbate. One-second puffs of ascorbate-free saline (zero [AA]o), delivered through a 2-3 microm diameter pipette, were directed at the bipolar cells. IK(V) was recorded by conventional whole-cell patch-clamp methods. In normal retinas, puffs of zero [AA]o caused a rapid (<100 ms) suppression of IK(V) of about 50% that lasted for several minutes. This effect was blocked by 1 microM SCH23390 and was unaffected by 2 mM Co2+ or 5 microM spiperone. 6-OHDA treatment resulted in major effects. First, IK(V) was reduced by approximately 50% for weeks 1-6, recovering to a 20% reduction by week 7. Second, puffs of zero [AA]o enhanced IK(V) rather than suppressed it. The enhancement was blocked by SCH23390 and the PKA inhibitor, Wiptide, but was insensitive to spiperone. Third, all parts of the Mb bipolar cell (except for the axon) were sensitive to puffs of zero [AA]o in both normal and 6-OHDA-treated retinas. Fourth, bath application of 20 microM dopamine restored the amplitude of IK(V) but did not reverse the effects of puffed zero [AA]o. IK(V) was fit by two exponentials; all of the effects on IK(V) were on the amplitude of the components and not on the time constants. Chronic dopamine depletion caused reversible changes in the properties of K+ channels underlying IK(V), as well as a long-term change in the intracellular coupling mechanisms between D1-receptor activation and the modulation of IK(V).

Delayed rectifier K+ current of dog bronchial myocytes: effect of pollen sensitization and PKC activation.

The properties of delayed rectifier K+ current [IK(dr)] of canine airway smooth muscle cells isolated from small bronchi and its modulation by protein kinase C (PKC) were studied by whole cell patch clamp. IK(dr) activated positive to -40 mV, with half-maximal activation at -16 +/- 1.2 mV (n = 15) and average current density of 31 +/- 2.6 pA/pF (n = 15) at +30 mV. The capacitive surface area, current density, and voltage dependence of activation of IK(dr) of myocytes of ragweed pollen-sensitized dogs were not different from age-matched control dogs. However, the sensitization reduced the availability of IK(dr) between -40 and -20 mV due to a hyperpolarizing shift in the voltage dependence of steady-state inactivation (-29.9 +/- 1.2 in sensitized versus -26.0 +/- 0.7 mV in control dogs, n = 9 and 11, respectively; P < 0.05). PKC activation with diacylglycerol analog or phorbol ester depressed IK(dr) amplitude, whereas an inactive diacylglycerol analog had no effect. The hyperpolarizing shift in voltage dependence of inactivation and/or modulation of IK(dr) by PKC may be two mechanisms that contribute to the enhanced reactivity of bronchial tissues from ragweed pollen-sensitized dogs.

Modulation of K+ and Ca2+ currents in cultured neurons by an angiotensin II type 1a receptor peptide.

Angiotensin II (ANG II) inhibits delayed rectifier K+ current (IK) and stimulates total Ca2+ current (ICa) in neurons cocultured from newborn rat hypothalamus and brain stem, effects mediated via ANG II type 1 (AT1) receptors. Here, we identify potential G protein activator regions of the AT1 receptor responsible for initiating the intracellular changes that lead to alterations in these currents. Intracellular application into cultured neurons of a peptide corresponding to the third cytoplasmic loop of the AT1 receptor (AT1a/i3) mimicked the actions of ANG II on IK and ICa, whereas application of a peptide corresponding to the second cytoplasmic loop (AT1a/i2) did not alter these currents. This modulation of IK and ICa by AT1a/i3 involves intracellular messengers (G alpha q, protein kinase C, and intracellular Ca2+) that are identical to those involved in the modulation of IK and ICa following ANG II activation of AT1 receptors. These data provide functional evidence for a role of the third cytoplasmic loop of the AT1 receptor in G protein coupling and subsequent modulation of ion channel effectors.

Presynaptic facilitation revisited: state and time dependence

The mechanisms underlying short-term presynaptic facilitation, the enhancement of transmitter release from sensory neurons in Aplysia, induced by serotonin (5-HT), can be divided into two categories: (1) changes in ionic conductances leading to spike broadening and enhancement of Ca2+ influx; and (2) actions on the machinery for transmitter release that are independent of spike broadening and the resulting increases in Ca2+ influx. Spike broadening and the associated enhancement of excitability are induced by the modulation of K+ conductances in the sensory neuron. The cellular mechanisms that contribute to the enhancement of release that is independent of spike broadening are not known and may involve vesicle mobilization or other steps in exocytotic release. These two facilitatory actions of 5-HT are mediated by at least two second-messenger-activated protein kinase systems, protein kinase A (PKA) and protein kinase C (PKC). These two second-messenger cascades overlap in their contributions to synaptic facilitation. However, their relative contributions to enhancement of transmitter release are not simply synergistic but are state- and time-dependent. The state dependence is a reflection of the synapse's previous history of activity. When the synapse is rested (and not depressed), a brief pulse of 5-HT (lasting from 10 sec to 5 min) produces its actions primarily through PKA via both spike broadening-dependent and -independent mechanisms. The broadening primarily involves the modulation of a voltage-dependent K+ current, IKV, with a small contribution by a voltage-independent K+ current, IKS. By contrast, the enhancement of excitability is mediated primarily by the modulation of IKS. As the synapse becomes depressed with repeated activity, the contribution of PKC becomes progressively more important. As is the case with PKA, PKC produces its action both by broadening the spike via modulation of IKV and by a spike broadening-independent mechanism. In addition to being state-dependent, the mechanisms of facilitation are time-dependent. There are differences in the response to 5-HT when it is given briefly to produce short-term facilitation or when the exposure is prolonged. When exposure is brief (< or = 5 min), PKA dominates. When exposure is prolonged (10-20 min), PKC becomes dominant as it is with depressed synapses. Thus, synaptic plasticity appears to be expressed in several overlapping time domains, and the transition between very short-term facilitation and various intermediate duration phases seems to involve interactive processes between the kinases.

Activators of protein kinase C mimic serotonin-induced modulation of a voltage-dependent potassium current in pleural sensory neurons of Aplysia

1. In the pleural mechanoafferent sensory neurons of Aplysia, serotonin (5-HT)-induced spike broadening consists of at least two components: a cAMP and protein kinase A (PKA)-dependent, rapidly developing component and a protein kinase C (PKC)-dependent, slowly developing component. Voltage-clamp experiments were conducted to identify currents that are modulated by PKC and thus may contribute to the slowly developing component of 5-HT-induced spike broadening. 2. We compared the effects of phorbol esters, activators of PKC, on membrane currents with those of 5-HT. Bath application of 5-HT had complex modulatory effects on currents elicited by voltage-clamp pulses to potentials > 0 mV. The kinetics of both activation and inactivation of the membrane currents were slowed by 5-HT. This led to a decrease in an outward current at the beginning of the voltage-clamp pulse and an increase at the end of the pulse. Previous work has shown that these effects represent, in part, the modulation of a large, voltage-dependent K+ current (IK,V) by 5-HT. 3. Active phorbol esters mimicked some of the actions of 5-HT on membrane currents in that they slowed activation and inactivation kinetics of current responses to voltage-clamp pulses more positive than 0 mV. This led to a decrease in an outward current at the beginning of the pulse and an increase at the end of the pulse. Because inactive phorbols did not mimic the actions of 5-HT, the effects of active phorbol esters appeared to be PKC specific. In addition, preexposure of the sensory neurons to active phorbol esters appeared to occlude the modulatory actions of 5-HT on IK,V. Thus it is likely that modulation of IK,V by 5-HT is mediated, at lease in part, by PKC. 4. To further characterize which currents were modulated by PKC, low concentrations of tetraethylammonium (TEA, 2 mM) were used to block Ca(2+)-activated K+ current (IK,Ca). Low TEA partially blocked the phorbol ester-induced increase of the outward current at the end of voltage-clamp pulses. These results agreed with previous reports that activation of PKC enhanced a fast component of IK,Ca in these sensory neurons. Such an enhancement would lead to an increase in outward current that should be blocked by low TEA. Low TEA, however, did not affect phorbol ester-induced decrease of the outward current at the beginning of pulse, where the predominant current is IK,V, which is less sensitive to TEA.(ABSTRACT TRUNCATED AT 400 WORDS)

Differential effects of cAMP and serotonin on membrane current, action-potential duration, and excitability in somata of pleural sensory neurons of Aplysia

1. In somata of sensory neurons in the pleural ganglia of Aplysia californica, serotonin (5-HT) modulates at least three K+ currents: the S K+ current (IK,S), a slow component of the Ca2(+)-activated K+ current (IK,Ca), and the delayed or voltage-dependent K+ current (IK,V). The modulation of IK,S and the slow component of IK,Ca by 5-HT has been shown previously to be mediated via adenosine 3',5'-cyclic monophosphate (cAMP). To determine whether the modulation of IK,V by 5-HT also is mediated via cAMP, we used two-electrode voltage-clamp techniques to compare the modulation of membrane current by cAMP and 5-HT. 2. Current responses were elicited by brief (200 ms) voltage-clamp pulses before and after the bath application of analogues of cAMP. At all voltage-clamp potentials examined (-40-30 mV), analogues of cAMP reduced the amplitude of the current response. The properties of the cAMP-sensitive component of membrane current were revealed by computer subtraction of current responses elicited in the presence of the analogue of cAMP from current responses elicited before application of the analogue. The characteristics of the resulting cAMP difference current (IcAMP) suggested that cAMP modulated a component of membrane current that was relatively voltage independent, did not inactivate, and was active over a wide range of membrane potentials. In addition, the current-voltage (I-V) relationship of the cAMP difference current had a positive slope. These properties of the cAMP difference current were consistent with those of IK,S but did not indicate that IK,V was modulated by cAMP. 3. The cAMP-independent modulation of membrane current by 5-HT was examined by eliciting current responses first in the presence of an analogue of cAMP and again after the addition of 5-HT to the bath, which still contained the analogue. The presence of the analogue of cAMP occluded further modulation of IK,S by 5-HT. However, the analogue of cAMP did not occlude the modulation of IK,V by 5-HT. This cAMP-independent effect of 5-HT on membrane current was revealed by computer subtraction of current responses elicited in the presence of 5-HT from current responses elicited before the application of 5-HT (the analogue of cAMP was present throughout). The resulting cAMP-independent 5-HT difference current (I5-HT) was highly voltage dependent, had complex kinetics, and its I-V relationship had a negative slope at membrane potentials above 0 mV.(ABSTRACT TRUNCATED AT 400 WORDS)

Beta-adrenergic modulation of cardiac ion channels. Differential temperature sensitivity of potassium and calcium currents.

beta-Adrenergic stimulation of ventricular heart cells results in the enhancement of two important ion currents that regulate the plateau phase of the action potential: the delayed rectifier potassium channel current (IK) and L-type calcium channel current (ICa). The temperature dependence of beta-adrenergic modulation of these two currents was examined in patch-clamped guinea pig ventricular myocytes at various steps in the beta-receptor/cyclic AMP-dependent protein kinase pathway. External applications of isoproterenol and forskolin were used to activate the beta-receptor and the enzyme adenylate cyclase, respectively. Internal dialysis of cyclic 3',5'-adenosine monophosphate (cAMP) or the catalytic subunit of cAMP-dependent protein kinase (CS), as well as the external addition of 8-chlorphenylthio cAMP (CPT-cAMP) was applied to increase intracellular levels of cAMP and CS. Isoproterenol-mediated increases in IK, but not ICa, were found to be very temperature dependent over the range of 20-37 degrees C. At room temperature (20-22 degrees C) isoproterenol produced a large (threefold) enhancement of ICa but had no effect on IK. In contrast, at warmer temperatures (30-37 degrees C) both currents increased in the presence of this agonist and the kinetics of IK were slowed at -30 mV. A similar temperature sensitivity also existed after exposure to forskolin, CPT-cAMP, cAMP, and CS, suggesting that this temperature sensitivity of IK may arise at the channel protein level. Modulation of IK during each of these interventions was accompanied by a slowing in IK kinetics. Thus, regulation of cardiac potassium channels but not calcium channels involves a temperature-dependent step that occurs after activation of the catalytic subunit of cAMP-dependent protein kinase.