Properties of the pacemaker current (If) in latent pacemaker cells isolated from cat right atrium

Membrane Resonance in Pyramidal and GABAergic Neurons of the Mouse Perirhinal Cortex

The perirhinal cortex (PRC) is a polymodal associative region of the temporal lobe that works as a gateway between cortical areas and hippocampus. In recent years, an increasing interest arose in the role played by the PRC in learning and memory processes, such as object recognition memory, in contrast with certain forms of hippocampus-dependent spatial and episodic memory. The integrative properties of the PRC should provide all necessary resources to select and enhance the information to be propagated to and from the hippocampus. Among these properties, we explore in this paper the ability of the PRC neurons to amplify the output voltage to current input at selected frequencies, known as membrane resonance. Within cerebral circuits the resonance of a neuron operates as a filter toward inputs signals at certain frequencies to coordinate network activity in the brain by affecting the rate of neuronal firing and the precision of spike timing. Furthermore, the ability of the PRC neurons to resonate could have a fundamental role in generating subthreshold oscillations and in the selection of cortical inputs directed to the hippocampus. Here, performing whole-cell patch-clamp recordings from perirhinal pyramidal neurons and GABAergic interneurons of GAD67-GFP⁺ mice, we found, for the first time, that the majority of PRC neurons are resonant at their resting potential, with a resonance frequency of 0.5–1.5 Hz at 23°C and of 1.5–2.8 Hz at 36°C. In the presence of ZD7288 (blocker of HCN channels) resonance was abolished in both pyramidal neurons and interneurons, suggesting that I_h current is critically involved in resonance generation. Otherwise, application of TTx (voltage-dependent Na⁺ channel blocker) attenuates the resonance in pyramidal neurons but not in interneurons, suggesting that only in pyramidal neurons the persistent sodium current has an amplifying effect. These experimental results have also been confirmed by a computational model. From a functional point of view, the resonance in the PRC would affect the reverberating activity between neocortex and hippocampus, especially during slow wave sleep, and could be involved in the redistribution and strengthening of memory representation in cortical regions.

The "funny" current (I(f)) inhibition by ivabradine at membrane potentials encompassing spontaneous depolarization in pacemaker cells

Recent clinical trials have shown that ivabradine (IVA), a drug that inhibits the funny current (I(f)) in isolated sinoatrial nodal cells (SANC), decreases heart rate and reduces morbidity and mortality in patients with cardiovascular diseases. While IVA inhibits I(f), this effect has been reported at essentially unphysiological voltages, i.e., those more negative than the spontaneous diastolic depolarization (DD) between action potentials (APs). We tested the relative potency of IVA to block I(f) over a wide range of membrane potentials, including those that encompass DD governing to the SANC spontaneous firing rate. A clinically relevant IVA concentration of 3 μM to single, isolated rabbit SANC slowed the spontaneous AP firing rate by 15%. During voltage clamp the maximal I(f) was 18 ± 3 pA/pF (at -120 mV) and the maximal I(f) reduction by IVA was 60 ± 8% observed at -92 ± 4 mV. At the maximal diastolic depolarization (~-60 mV) I(f) amplitude was only -2.9 ± 0.4 pA/pF, and was reduced by only 41 ± 6% by IVA. Thus, I(f) amplitude and its inhibition by IVA at physiologically relevant membrane potentials are substantially less than that at unphysiological (hyperpolarized) membrane potentials. This novel finding more accurately describes how IVA affects SANC function and is of direct relevance to numerical modeling of SANC automaticity.

Atrial natriuretic peptide regulates Ca channel in early developmental cardiomyocytes

Background

Cardiomyocytes derived from murine embryonic stem (ES) cells possess various membrane currents and signaling cascades link to that of embryonic hearts. The role of atrial natriuretic peptide (ANP) in regulation of membrane potentials and Ca²⁺ currents has not been investigated in developmental cardiomyocytes.

Methodology/Principal Findings

We investigated the role of ANP in regulating L-type Ca²⁺ channel current (I_CaL) in different developmental stages of cardiomyocytes derived from ES cells. ANP decreased the frequency of action potentials (APs) in early developmental stage (EDS) cardiomyocytes, embryonic bodies (EB) as well as whole embryo hearts. ANP exerted an inhibitory effect on basal I_CaL in about 70% EDS cardiomyocytes tested but only in about 30% late developmental stage (LDS) cells. However, after stimulation of I_CaL by isoproterenol (ISO) in LDS cells, ANP inhibited the response in about 70% cells. The depression of I_CaL induced by ANP was not affected by either Nω, Nitro-L-Arginine methyl ester (L-NAME), a nitric oxide synthetase (NOS) inhibitor, or KT5823, a cGMP-dependent protein kinase (PKG) selective inhibitor, in either EDS and LDS cells; whereas depression of I_CaL by ANP was entirely abolished by erythro-9-(2-Hydroxy-3-nonyl) adenine (EHNA), a selective inhibitor of type 2 phosphodiesterase(PDE2) in most cells tested.

Conclusion/Significances

Taken together, these results indicate that ANP induced depression of action potentials and I_CaL is due to activation of particulate guanylyl cyclase (GC), cGMP production and cGMP-activation of PDE2 mediated depression of adenosine 3′, 5′–cyclic monophophate (cAMP)–cAMP-dependent protein kinase (PKA) in early cardiomyogenesis.

Pacemaker activity of the human sinoatrial node: role of the hyperpolarization-activated current, I(f)

The mechanism of primary, spontaneous cardiac pacemaker activity of the sinoatrial node (SAN) has extensively been studied in several animal species, but is virtually unexplored in man. Understanding the mechanisms of human SAN pacemaker activity is important for developing new therapeutic approaches for controlling the heart rate in the sick sinus syndrome and in diseased myocardium. Here we review the functional role of the hyperpolarization-activated 'funny' current, I(f), in human SAN pacemaker activity. Despite the many animal studies performed over the years, the contribution of I(f) to pacemaker activity is still controversial and not fully established. However, recent clinical data on mutations in the I(f) encoding HCN4 gene, which is thought to be the most abundant isoform of the HCN gene family in SAN, suggest a functional role of I(f) in human pacemaker activity. These clinical findings are supported by recent experimental data from single isolated human SAN cells that provide direct evidence that I(f) contributes to human SAN pacemaker activity. Therefore, controlling heart rate in clinical practice via I(f) blockers offers a valuable approach to lowering heart rate and provides an attractive alternative to conventional treatment for a wide range of patients with confirmed stable angina, while upregulation or artificial expression of I(f) may relieve disease-causing bradycardias.

Acute effects of candesartan on rat renal haemodynamics and proximal tubular reabsorption

1. The effects of the specific angiotensin II receptor type I (AT1) antagonist candesartan on renal proximal tubular sodium transport were studied using lithium clearance. The effects of candesartan on mean arterial blood pressure (MABP), renal plasma flow (RPF), glomerular filtration rate (GFR) and sodium and potassium excretion were also investigated. 2. Male Wistar rats were anaesthetized with Inactin (thiobutabarbital sodium; Sigma, St Louis, MO, USA). Clearance markers (8% polyfructosan, 1% para-aminohippuric acid and 4 mmol/l lithium chloride) were given into a jugular vein at the rate of 1.6 mL/h per 100 g bodyweight. Candesartan was given as bolus injection (0.01, 0.1, 0.2, 0.5 and 1.0 mg/kg) followed by 60 min continuous infusion at a rate of 0.5, 5, 10, 25 and 50 microg/min per kg, respectively. 3. The non-depressor dose of candesartan (0.01 mg/kg) did not alter RPF or GFR, whereas diuresis, natriuresis and kaliuresis were observed. The higher doses of candesartan reduced MABP, RPF and GFR, although diuresis, natriuresis and kaliuresis were still observed. 4. Renal tubular sodium and water reabsorption were inhibited after intravenous administration of candesartan independently of an alteration in arterial pressure. Lithium clearance data indicate that the site of inhibition was in the proximal nephron segment.

Physiology and pharmacology of the cardiac pacemaker (“funny”) current

First described over a quarter of a century ago, the cardiac pacemaker "funny" (I(f)) current has been extensively characterized since, and its role in cardiac pacemaking has been thoroughly demonstrated. A similar current, termed I(h), was later described in different types of neurons, where it has a variety of functions and contributes to the control of cell excitability and plasticity. I(f) is an inward current activated by both voltage hyperpolarization and intracellular cAMP. In the heart, as well as generating spontaneous activity, f-channels mediate autonomic-dependent modulation of heart rate: beta-adrenergic stimulation accelerates, and vagal stimulation slows, cardiac rate by increasing and decreasing, respectively, the intracellular cAMP concentration and, consequently, the f-channel degree of activation. Four isoforms of hyperpolarization-activated, cyclic nucleotide-gated (HCN) channels have been cloned more recently and shown to be the molecular correlates of native f-channels in the heart and h-channels in the brain. Individual HCN isoforms have kinetic and modulatory properties which differ quantitatively. A comparison of their biophysical properties with those of native pacemaker channels provides insight into the molecular basis of the pacemaker current properties and, together with immunolabelling and other detection techniques, gives information on the pattern of HCN isoform distribution in different tissues. Because of their relevance to cardiac pacemaker activity, f-channels are a natural target of drugs aimed at the pharmacological control of heart rate. Several agents developed for their ability to selectively reduce heart rate act by a specific inhibition of f-channel function; these substances have a potential for the treatment of diseases such as angina and heart failure. In the near future, devices based on the delivery of f-channels in situ, or of a cellular source of f-channels (biological pacemakers), will likely be developed for use in therapies for diseases of heart rhythm with the aim of replacing electronic pacemakers.

Developmental changes in functional expression and beta-adrenergic regulation of I(f) in the heart of mouse embryo

The hyperpolarization-activated current (I(f)) plays an important role in determining the spontaneous rate of cardiac pacemaker cells. The automatic rhythmicity also exists in working cells of embryonic heart, therefore we studied developmental changes in functional expression and beta-adrenergic regulation of I(f) in embryonic mouse heart. The expression of I(f) is high in early developmental stage (EDS) (10.5 d after coitus) ventricular myocytes, low in intermediate developmental stage (IDS) (13.5 d) atrial or ventricular myocytes and even lower in late developmental stage (LDS) (16.5 d) atrial or ventricular myocytes, indicating that these cells of the EDS embryonic heart have some properties of pacemaker cells. Beta-adrenergic agonist isoproterenol (ISO) stimulates I(f) in LDS but not in EDS cardiomyocytes, indicating that the beta-adrenergic regulation of I(f) is not mature in EDS embryonic heart. But forskolin (a direct activator of adenylate cyclase) and 8-Br-cAMP (a membrane-permeable analogue of cAMP) increase the amplitude of I(f) in EDS cells, indicating that adenylate cyclase and cAMP function fairly well at early stage of development. Furthermore, the results demonstrate that I(f) is modulated by phosphorylation via cAMP dependent PKA both in EDS and LDS cells.

Functional expression of the hyperpolarization-activated, non-selective cation current I(f) in immortalized HL-1 cardiomyocytes

HL-1 cells are adult mouse atrial myocytes induced to proliferate indefinitely by SV40 large T antigen. These cells beat spontaneously when confluent and express several adult cardiac cell markers including the outward delayed rectifier K(+) channel. Here, we examined the presence of a hyperpolarization-activated I(f) current in HL-1 cells using the whole-cell patch-clamp technique on isolated cells enzymatically dissociated from the culture at confluence. Cell membrane capacitance (C(m)) ranged from 5 to 53 pF. I(f) was detected in about 30% of the cells and its occurrence was independent of the stage of the culture. I(f) maximal slope conductance was 89.7 +/- 0.4 pS pF(-1) (n = 10). I(f) current in HL-1 cells showed typical characteristics of native cardiac I(f) current: activation threshold between -50 and -60 mV, half-maximal activation potential of -83.1 +/- 0.7 mV (n = 50), reversal potential at -20.8 +/- 1.5 mV (n = 10), time-dependent activation by hyperpolarization and blockade by 4 mM Cs(+). In half of the cells tested, activation of adenylyl cyclase by the forskolin analogue L858051 (20 microM) induced both an approximately 6 mV positive shift of the half-activation potential and an approximately 37 % increase in the fully activated I(f) current. RT-PCR analysis of the hyperpolarization-activated, cyclic nucleotide-gated channels (HCN) expressed in HL-1 cells demonstrated major contributions of HCN1 and HCN2 channel isoforms to I(f) current. Cytosolic Ca(2+) oscillations in spontaneously beating HL-1 cells were measured in Fluo-3 AM-loaded cells using a fast-scanning confocal microscope. The oscillation frequency ranged from 1.3 to 5 Hz and the spontaneous activity was stopped in the presence of 4 mM Cs(+). Action potentials from HL-1 cells had a triangular shape, with an overshoot at +15 mV and a maximal diastolic potential of -69 mV, i.e. more negative than the threshold potential for I(f) activation. In conclusion, HL-1 cells display a hyperpolarization-activated I(f) current which might contribute to the spontaneous contractile activity of these cells.

Does Ca2+ release from the sarcoplasmic reticulum influence heart rate?

1. The present review summarizes the evidence that Ca2+ release from the sarcoplasmic reticulum (SR) is an important contributor to the systolic rise in [Ca2+]i (the Ca2+ transient) and influences the pacemaker firing rate. 2. We believe that the mechanism whereby [Ca2+]i influences firing rate is through the dependence of the Na+-Ca2+ exchanger on [Ca2+]i. 3. Extrusion of Ca2+ by the electrogenic Na+-Ca2+ exchanger produces an inward current that contributes to the pacemaker currents. Confocal images of Ca2+ indicate the distribution of [Ca2+]i and Ca2+ sparks add to the evidence that Ca2+ release from SR is involved in pacemaker activity. 4. The normal pathway for increased heart rate is sympathetic activation; we discuss the evidence that part of the chronotropic effect of beta-adrenoceptor stimulation is through the modulation of SR Ca2+ release. 5. These studies show that Ca2+ handling by the pacemaker cells makes an important contribution to the regulation of pacemaker activity.

Intracellular Ca2+ release sparks atrial pacemaker activity

Electrical excitation of the mammalian heart originates from specialized pacemaker cells in the right atrium. Pacemaker activity depends on multiple ion channels and transport mechanisms that reside primarily within the plasma membrane. However, recent evidence indicates that intracellular Ca2+ release from the sarcoplasmic reticulum also contributes importantly to atrial pacemaker function.

Intracellular Ca2+ release contributes to automaticity in cat atrial pacemaker cells

1. The cellular mechanisms governing cardiac atrial pacemaker activity are not clear. In the present study we used perforated patch voltage clamp and confocal fluorescence microscopy to study the contribution of intracellular Ca2+ release to automaticity of pacemaker cells isolated from cat right atrium. 2. In spontaneously beating pacemaker cells, an increase in subsarcolemmal intracellular Ca2+ concentration occurred concomitantly with the last third of diastolic depolarization due to local release of Ca2+ from the sarcoplasmic reticulum (SR), i.e. Ca2+ sparks. Nickel (Ni2+; 25-50 microM), a blocker of low voltage-activated T-type Ca2+ current ((ICa,T), decreased diastolic depolarization, prolonged pacemaker cycle length and suppressed diastolic Ca2+ release. 3. Voltage clamp analysis indicated that the diastolic Ca2+ release was voltage dependent and triggered at about -60 mV. Ni2+ suppressed low voltage-activated Ca2+ release. Moreover, low voltage-activated Ca2+ release was paralleled by a slow inward current presumably due to stimulation of Na+-Ca2+ exchange (INa-Ca). Low voltage-activated Ca2+ release was found in both sino-atrial node and latent atrial pacemaker cells but not in working atrial myocytes. 4. These findings suggest that low voltage-activated ICa,T triggers subsarcolemmal Ca2+ sparks, which in turn stimulate INa-Ca to depolarize the pacemaker potential to threshold. This novel mechanism indicates a pivotal role for ICa,T and subsarcolemmal intracellular Ca2+ release in normal atrial pacemaker activity and may contribute to the development of ectopic atrial arrhythmias.

Functional expression and regulation of the hyperpolarization activated non-selective cation current in embryonic stem cell-derived cardiomyocytes

1. The biophysical and pharmacological characteristics of the hyperpolarization activated non- selective cation current (If) were recorded using whole-cell voltage clamp in embryonic stem (ES) cell-derived cardiomyocytes at different stages of development. 2. The cation current was detected in a large percentage (65 %) of early stage (EDS, differentiated for 7 + 3-4 days) cells at a current density of 11.4 +/- 0.6 pA pF-1 (n = 47). In late stage (LDS, differentiated for 7 + 9-12 days) cells the percentage of cells expressing If decreased (45 %), but If densities (15.5 +/- 0.9 pA pF-1, n = 20) were increased. 3. The muscarinic agonist carbachol (CCh, 1 microM) depressed basal If in EDS cells by 45.7 +/- 6.5 %, n = 5) and was without effect in LDS cardiomyocytes (n = 4). The beta-adrenoceptor agonist isoprenaline (ISO, 1 microM) stimulated If in LDS cells by 33 +/- 5.2 % (n = 6) but not in EDS cells (n = 5). 4. Cell infusion with the catalytic subunit of the cAMP-dependent protein kinase (PKA, 7 microM) stimulated If in EDS cells by 37.0 +/- 2.9 %, (n = 4), but subsequent superfusion of 8-bromo-cAMP (200 microM) was without effect. Intracellular perfusion of LDS cardiomyocytes with the highly selective peptide inhibitor of PKA (PKI, 20 microM) completely inhibited the stimulation of the L-type Ca2+ current (ICa,L) as well as of If by ISO (1 microM). 5. Extracellular superfusion with phosphodiesterase (PDE) inhibitors - IBMX, a non-selective antagonist, Erythro-9-(2-hydoxy-3-nonyl)adenine (EHNA), a PDE2 antagonist and rolipram, a PDE4 antagonist - resulted in stimulation of ICa,L and If in EDS cells. By contrast, milrinone and cilostamide, two PDE3 antagonists, stimulated ICa,L, but not If. 6. The present work demonstrates that If is functionally expressed during early cardiomyogenesis. Similar to ICa,L, If is regulated during embryonic development by phosphorylation via PKA. In contrast to ICa,L, If is not regulated by PDE3 suggesting different localization of these ion channels with respect to PDE3.

The HCN gene family: molecular basis of the hyperpolarization-activated pacemaker channels

The molecular basis of the hyperpolarization-activated cation channels that underlie the anomalous rectifying current variously termed Ih, Iq, or I(f) is discussed. On the basis of the expression patterns and biophysical properties of the newly cloned HCN ion channels, an initial attempt at defining the identity and subunit composition of channels underlying native Ih is undertaken. By comparing the sequences of HCN channels to other members of the K channel superfamily, we discuss how channel opening may be coupled to membrane hyperpolarization and to direct binding of cyclic nucleotide. Finally, we consider some of the questions in cardiovascular physiology and neurobiology that can be addressed as a result of the demonstration that Ih is encoded by the HCN gene family.

Expression of different types of inward rectifier currents confers specificity of light and dark responses in type A and B photoreceptors of Hermissenda

Each eye of the mollusc Hermissenda consists of five photoreceptors, two type A and three type B cells. Type A cells are quiescent, whereas B cells are spontaneously active in the dark. Differences in the intrinsic membrane properties of type A and B photoreceptors were studied using voltage- and current-clamp techniques. The current density of a Ni2+-sensitive, low-voltage activated Ca2+ current was similar in the two cell types. However, type B cells express an inward rectifier current (Ih) that has different permeation and pharmacological properties from the inward rectifier current in type A cells. The current in the B cells was time-dependent and was blocked by Cs+. Na+ and K+ were the charge carriers for Ih. The inward rectifier current in A cells (IK1) was time-independent, was selectively permeable to K+, and was blocked by Ba2+. Ni2+ reduced the spontaneous spike activities of type A and B cells, whereas Cs+ produced membrane hyperpolarization and reduced the spike activities of dark-adapted B cells. The application of both Cs+ and Ni2+ completely blocked dark-adapted spontaneous activities of B cells. Moreover, Ba2+ increased the excitability of type A cells but not B cells. Hence, differential expression of the two distinct inward rectifiers found in type A and B cells contributes to differences in their intrinsic membrane properties. Because changes in the excitability of the two cell types are correlates of conditioning in Hermissenda, modulation of these underlying currents may play a major role during conditioning-induced plasticity.

Expression of different types of inward rectifier currents confers specificity of light and dark responses in type A and B photoreceptors of Hermissenda

Each eye of the mollusc Hermissenda consists of five photoreceptors, two type A and three type B cells. Type A cells are quiescent, whereas B cells are spontaneously active in the dark. Differences in the intrinsic membrane properties of type A and B photoreceptors were studied using voltage- and current-clamp techniques. The current density of a Ni2+-sensitive, low-voltage activated Ca2+ current was similar in the two cell types. However, type B cells express an inward rectifier current (Ih) that has different permeation and pharmacological properties from the inward rectifier current in type A cells. The current in the B cells was time-dependent and was blocked by Cs+. Na+ and K+ were the charge carriers for Ih. The inward rectifier current in A cells (IK1) was time-independent, was selectively permeable to K+, and was blocked by Ba2+. Ni2+ reduced the spontaneous spike activities of type A and B cells, whereas Cs+ produced membrane hyperpolarization and reduced the spike activities of dark-adapted B cells. The application of both Cs+ and Ni2+ completely blocked dark-adapted spontaneous activities of B cells. Moreover, Ba2+ increased the excitability of type A cells but not B cells. Hence, differential expression of the two distinct inward rectifiers found in type A and B cells contributes to differences in their intrinsic membrane properties. Because changes in the excitability of the two cell types are correlates of conditioning in Hermissenda, modulation of these underlying currents may play a major role during conditioning-induced plasticity.

Identification of a gene encoding a hyperpolarization-activated pacemaker channel of brain

The generation of pacemaker activity in heart and brain is mediated by hyperpolarization-activated cation channels that are directly regulated by cyclic nucleotides. We previously cloned a novel member of the voltage-gated K channel family from mouse brain (mBCNG-1) that contained a carboxy-terminal cyclic nucleotide-binding domain (Santoro et al., 1997) and hence proposed it to be a candidate gene for pacemaker channels. Heterologous expression of mBCNG-1 demonstrates that it does indeed code for a channel with properties indistinguishable from pacemaker channels in brain and similar to those in heart. Three additional mouse genes and two human genes closely related to mBCNG-1 display unique patterns of mRNA expression in different tissues, including brain and heart, demonstrating that these channels constitute a widely expressed gene family.

Hyperpolarization-activated inward current in ventricular myocytes from normal and failing human hearts

BACKGROUND

The hyperpolarization-activated inward current (I[f]) was found to be overexpressed in hypertrophied rat ventricular myocytes, indicating that I(f) might favor arrhythmias in hypertrophied or failing ventricular myocardium. In the present study, we evaluated whether I(f) is expressed in human ventricular myocardium, if it may be increased in human heart failure, and if its autonomic modulation may be altered.

METHODS AND RESULTS

The whole-cell patch-clamp technique was used to record I(f) in isolated ventricular myocytes from 34 failing (dilated [DCM] or ischemic [ICM] cardiomyopathy) and 13 donor hearts (NF). I(f) was observed in all myocytes showing typical current properties, ie, time and voltage dependence, block by [Cs+]o, permeability for K+ and Na+, and current increase with raising [K+]o. There was a trend toward larger current densities in myopathic (at -130 mV in [K+]o 25 mmol/L; DCM: -1.37 +/- 0.12 pA/pF, n = 50; ICM: -1.39 +/- 0.24 pA/pF, n = 30) than in nonfailing cells (-1.18 +/- 0.21 pA/pF, n = 24), although this difference did not reach statistical significance (P=.23). Boltzmann distributions yielded an activation threshold of -80 mV and half-maximal activation at -110.96 +/- 0.06 mV in myopathic and normal myocytes. Isoproterenol (10(-5) mol/L) shifted the current activation by 10 mV (31 myopathic, 5 NF). Carbachol and adenosine had no direct effect on I(f) (6 and 12 myopathic, 3 and 3 NF, respectively) but reversibly antagonized beta-adrenergic stimulation (5 and 7 myopathic, 2 and 2 NF, respectively). Autonomic modulation was similar in failing and nonfailing cells.

CONCLUSIONS

In end-stage heart failure, no significant change of I(f) could be found, although there was a trend toward increased I(f). Together with an elevated plasma norepinephrine concentration and a previously reported reduction in I(K1) in human heart failure, I(f) might favor diastolic depolarization in individual myopathic cells.

Characterization of a hyperpolarization-activated current in dedifferentiated adult rat ventricular cells in primary culture

1. The presence of a hyperpolarization-activated pacemaker (I(f)-like current was tested in dedifferentiated adult rat ventricular myocytes up to 12 days in primary culture with the whole-cell patch clamp technique. 2. An I(f)i-like current was found and characterized on freshly isolated and cultured ventricular cells. Both activation and density of the current varied in relation to the stage of dedifferentiation. The current was activated from -92.0 +/- 2.5 and -63 +/- 1.0 mV at the beginning (4-day-cultured cells) and end of the dedifferentiation process (12 days), respectively. Its density measured at 170 mV progressively increased from -2.34 +/- 0.36 to -6.12 +/- 0.64 pA pF-1 between the two farthest stages of cellular remodeling. In freshly isolated cells the current was activated at -108.0 +/- 1.5 mV and its current density measured at -170 mV was -1.97 +/- 0.56 pA pF-1. 3. The current was blocked by extracellular CsCl (3mM) in a voltage-dependent manner. Modification of reversal potentials obtained at various values of [K+]o ( 5.4 or 25 mM) and [Na+]o (140 or 30 mM) suggests that the current was carried by both K+ and Na+ ions. 4. It is concluded that the hyperpolarization-activated inward current, recorded in freshly isolated and in cultured ventricular cells has characteristics similar to those of I(f). In adult rat ventricular cells it is activated in a non-physiological potential range, but can be elicited in a more physiological range when the cells are remodelled through a dedifferentiated way. It is suggested that such a current could be implicated in ventricular arrhythmias developed in pathological events.

A cellular mechanism contributing to postvagal tachycardia studied in isolated pacemaker cells from cat right atrium

Vagal nerve-induced inhibition of the heartbeat is followed by a postvagal increase in heart rate above control levels, postvagal tachycardia. In the present study, we used a perforated-patch/whole-cell recording method to determine the role of L-type Ca2+ current (ICa,L) and the hyperpolarization-activated inward current (I(f)) in the positive chronotropic response elicited by withdrawal of acetylcholine (ACh). Experiments were performed on sinoatrial node (SAN) and latent atrial pacemaker (LAP) cells isolated from cat right atrium. Withdrawal of a 2-minute exposure to 1 mumol/L ACh elicited a rebound stimulation of ICa,L in both SAN (33 +/- 4%) and LAP (50 +/- 6%) cells above control. Similarly, withdrawal of ACh (1 mumol/L) elicited a rebound stimulation of I(f) in both SAN (21 +/- 4%) and LAP (20 +/- 6%) cells. During the rebound stimulation of ICa,L, peak amplitude was increased throughout the voltage range, and the voltage dependence of activation was shifted to more negative voltages. Action potential recordings from both SAN and LAP cells showed that following ACh-induced inhibition, withdrawal of ACh elicited a concomitant rebound increase in action potential amplitude ( + 21 +/- 2% and + 21 +/- 3%, respectively) and decrease in pacemaker cycle length (30 +/- 5% and 44 +/- 5%, respectively) compared with control. H-89 (2 mumol/L), an inhibitor of cAMP-dependent protein kinase A, abolished the rebound increase of ICa,L, I(f), action potential amplitude, and decrease in pacemaker cycle length elicited by withdrawal of ACh. In the presence of 2 mmol/L cesium, a blocker of I(f), the rebound decrease in pacemaker cycle length elicited by withdrawal of ACh was unchanged. We conclude that in SAN and LAP cells, withdrawal of ACh elicits a positive chronotropic response primarily through a cAMP-mediated rebound stimulation of ICa,L. These findings are the first demonstration of an intrinsic cellular mechanism that may contribute directly to the nonadrenergic component of postvagal tachycardia.

beta-Adrenergic stimulation induces acetylcholine to activate ATP-sensitive K+ current in cat atrial myocytes

Our previous work on atrial myocytes suggested that the effect of acetylcholine (ACh) to increase K+ conductance can be potentiated by prior loading of the sarcoplasmic reticulum (SR) with Ca2+. The present study, therefore, sought to determine whether prior exposure to isoproterenol (ISO) potentiates ACh-induced increases in K+ conductance and the underlying mechanisms. A nystatin-perforated patch whole-cell configuration was used to record from cat atrial myocytes. Voltage-clamp ramps (40 mV/s) were used to assess total membrane conductance. The experimental protocol consisted of two consecutive 30-second ACh exposures (ACh1 and ACh2) separated by a 6-minute recovery period in ACh-free solution. In general, experimental interventions, such as exposure to ISO, were imposed during the period between ACh1 and ACh2 to determine their effects on the response to ACh2 in relation to ACh1. Under control conditions, K+ conductances induced by ACh1 and ACh2 were not different from one another with or without activation of L-type Ca2+ current (ICa,L) during the recovery period. When 1 mumol/L ISO plus ICa,L activation was imposed during the recovery period, ACh2 induced a significantly larger increase in K+ conductance than ACh1. The ACh2-induced K+ current potentiated by ISO was time independent and selectively blocked by 10 mumol/L glibenclamide and therefore identified as ATP-sensitive K+ current (IK,ATP). The effect of ISO to induce ACh2-activated IK,ATP was mimicked by 1 mumol/L forskolin or 200 mumol/L 8-(4-chlorophenylthio)-cAMP, but not by 0.5 mumol/L BAY K 8644, and was selectively abolished by (1) 5 mumol/L thapsigargin or 1 mumol/L ryanodine, agents that prevent accumulation of SR Ca2+, (2) inhibition of L-type Ca2+ current (ICa,L) by 1 mumol/L nisoldipine or zero external Ca2+, (3) 50 mumol/L Rp-cAMPs, an inhibitor of cAMP-dependent protein kinase A, or (4) 2 mumol/L propranolol. Atropine (1 mumol/L) abolished all ACh-induced currents. Moreover, ACh2-activated IK,ATP was selectively blocked by 0.2 mumol/L pirenzepine, an M1 muscarinic receptor antagonist, or 0.1 mumol/L calphostin C, a selective inhibitor of protein kinase C. AFDX116 (100 mumol/L), an M2 muscarinic receptor antagonist, blocked the conventional ACh-activated K+ current and revealed ACh2-activated IK,ATP. These results indicate that prior exposure to ISO potentiates ACh-induced increases in K+ current via ACh-activated IK,ATP.(ABSTRACT TRUNCATED AT 400 WORDS)

Different types of ganglion cell in the cardiac plexus of guinea-pigs

1. Intracellular recordings were made from the parasympathetic ganglion cells that lie in the epicardium of the left atrium of guinea-pig heart near the interatrial septum. 2. Three distinct types of neurone were identified on the basis of their electrophysiological properties. In one group of neurones, S cells, somatic action potentials were followed by brief after-hyperpolarizations. In the other two sets of neurones, somatic action potentials were followed by prolonged after-hyperpolarizations. The neurones with prominent after-hyperpolarization were further subdivided: one group of neurones, P cells, showed inward rectification at membrane potentials near the resting membrane potential whilst neurones in the other group, SAH cells, did so only at more negative potentials. 3. In the group of neurones that displayed inward rectification at potentials near rest, rectification resulted from the activation of an inward current, which resembled the hyperpolarization-activated inward current present in cardiac muscle pacemaker cells. 4. The three different types of neurone received different patterns of synaptic input. Each SAH cell received a synaptic excitatory connection from the vagus which in most cells released sufficient transmitter to initiate an action potential in that cell; several SAH cells also received a separate connection, which could be activated by local stimulation. Although most S cells failed to receive a synaptic input from the vagus, all of those tested received an excitatory synaptic input which could be activated by local stimulation. Virtually all P cells failed to receive a synaptic input from the vagus; in addition, local stimulation failed to initiate synaptic potentials in P cells. 5. When the structure of cardiac ganglion cells was determined, by loading the cells with either biocytin or neurobiotin, it was found that most cells lacked extensive dendritic processes. S cells were invariably monopolar, most P cells were dipolar or pseudodipolar, whereas many SAH cells were multipolar. 6. In many neurones an on-going discharge of action potentials was detected in the absence of obvious stimulation. In S and SAH cells, the action potentials resulted from an on-going discharge of excitatory synaptic potentials. However, when a spontaneous discharge of action potentials was detected in P cells a discharge of excitatory synaptic potentials was not detected. 7. The results are discussed in relation to the idea that the three different types of cell may have different functions and that some of the cells may be organized in such a way as to permit the local handling of neuronal information within the heart.

Pacemaker current i(f) in adult canine cardiac ventricular myocytes

1. Single cells enzymatically isolated from canine ventricle and canine Purkinje fibres were studied with the whole-cell patch clamp technique, and the properties of the pacemaker current i(f) compared. 2. Steady-state i(f) activation occurred in canine ventricular myocytes at more negative potentials (-120 to -170 mV) than in canine Purkinje cells (-80 to -130 mV). 3. Reversal potentials were obtained in various extracellular Na+ (140, 79 or 37 mM) and K+ concentrations (25, 9 or 5.4 mM) to determine the ionic selectivity of i(f) in the ventricle. The results suggest that this current was carried by both sodium and potassium ions. 4. The plots of the time constants of i(f) activation against voltage were 'bell shaped' in both canine ventricular and Purkinje myocytes. The curve for the ventricular myocytes was shifted about 30 mV in the negative direction. In both ventricular and Purkinje myocytes, the fully activated I-V relationship exhibited outward rectification in 5.4 mM extracellular K+. 5. Calyculin A (0.5 microM) increased i(f) by shifting its activation to more positive potentials in ventricular myocytes. Protein kinase inhibition by H-7 (200 microM) or H-8 (100 microM) reversed the positive voltage shift of i(f) activation. This effect of calyculin A also occurred when the permeabilized patch was used for whole-cell recording. 6. These results indicate i(f) is present in ventricular myocytes. If shifted to more positive potentials i(f) could play a role in ischaemia-induced ventricular arrhythmias. The negative shift of i(f) in the ventricle might play a role in differentiating non-pacing regions of the heart from those regions that pace.

Sodium currents in toad cardiac pacemaker cells

Cells in the pacemaker region of toad (Bufo marinus) sinus venosus had spontaneous rhythmic action potentials. The rate of firing of action potentials, the rate of diastolic depolarization and the maximum rate of rise of action potentials were reduced by TTX (10 nM to 1 microM). Currents were recorded with the whole cell, tight seal technique from cells enzymatically dissociated from this region. Cells studied were identified as pacemaker cells by their characteristic morphology, spontaneous rhythmic action potential activity that could be blocked by cobalt but not by TTX and lack of inward rectification. When calcium, potassium and nonselective cation currents (If) activated by hyperpolarization were blocked, depolarization was seen to generate transient and persistent inward currents. Both were sodium currents: they were abolished by tetrodotoxin (10 to 100 nM), their reversal potential was close to the sodium equilibrium potential and their amplitude and reversal potential were influenced as expected for sodium currents when extracellular sodium ions were replaced with choline ions. The transient sodium current was activated at potentials more positive than -40 mV while the persistent sodium current was obvious at more negative potentials. It was concluded that, in toad pacemaker cells, TTX-sensitive sodium currents contributing both to the upstroke of action potentials and to diastolic depolarization may play an important role in setting heart rate.

Characterization of the hyperpolarization-activated current, I(f), in ventricular myocytes isolated from hypertensive rats

1. Left ventricular myocytes isolated from the heart of young (2-month-old) and old (18- to 20-month-old) spontaneously hypertensive rats (SHRs) were studied in the whole-cell configuration. Since multicellular preparations from old SHRs show a diastolic depolarization phase, we performed experiments to test whether it was associated with the presence of a hyperpolarization-activated If-like current. 2. In control Tyrode solution, a time-dependent increasing inward current activated by hyperpolarization was recorded in myocytes from old SHRs showing a diastolic depolarization phase. A barium-insensitive, caesium-sensitive, time-dependent inward current was recorded in a minority (4 of 33) of cells from young SHRs (membrane capacitance, 160 +/- 7 pF) but in 93% (25 of 27, P < 0.01) of myocytes from old SHRs (membrane capacitance, 355 +/- 19 pF, P < 0.01). 3. The current was fully activated at -120 mV and voltage of half-maximal activation was -88.1 +/- 1.5 mV; it was blocked by extracellular CsCl (4 mM) in a voltage-dependent manner. Reducing [K+]o from 25 to 5.4 mM caused a shift of the reversal potential from -17.3 +/- 3.8 to -25.7 +/- 2.7 mV and a 60% decrease of current conductance. 4. These findings suggest that an If-like current is present in rat ventricular myocytes from old SHRs, where it might favour the occurrence of spontaneous action potentials.

Delayed rectifier potassium current (IK) in latent atrial pacemaker cells isolated from cat right atrium

Whole-cell recording techniques were used to study the delayed rectifier K+ current (IK) in latent pacemaker cells isolated from cat right atrium. From a holding potential of -40 mV, depolarizing clamp steps elicited L-type Ca2+ current followed by an increasing outward current (IK). The time course of tail current amplitudes paralleled that of the time-dependent activation of outward current. Activation of IK exhibited a sigmoidal time course that was best fit by a power function where the activation variable was raised to the second power. The voltage-dependence of IK activation exhibited a sigmoidal relationship between -40 and +30 mV. The half-maximal activation voltage and slope factor were -21.9 +/- 1.3 and 13.8 +/- 0.9 mV respectively (n = 6). The fully activated I/V relationship of IK was linear between -100 and -30 mV and inwardly rectified at more positive voltages. Following IK activation, hyperpolarizations more negative than about -50 mV elicited tail currents that consisted of both IK deactivation and I(f) activation. A subtraction protocol was used to isolate IK tail currents. In 5.4 mM extracellular [K+], IK tail currents exhibited a reversal potential of -78.2 +/- 0.3 mV (n = 6). The reversal potential of IK was linearly related to log extracellular [K] and the slope was 51.5 mV per ten-fold change in extracellular [K]. At -70 mV, IK tail currents decayed as a single exponential function with a time constant of 159 +/- 16 ms (n = 6). These results indicate that latent atrial pacemakers exhibit IK activated by depolarization.(ABSTRACT TRUNCATED AT 250 WORDS)

Na(+)-Ca2+ exchange current in latent pacemaker cells isolated from cat right atrium

1. Single latent pacemaker cells were isolated from cat right atrium, and studied in a whole-cell configuration using a nystatin-perforated patch recording method. The nystatin method avoids alterations in intracellular Ca2+, cellular constituents and run-down of ionic currents. 2. Depolarizing voltage clamp pulses from -40 mV elicited L-type Ca2+ current (ICa) that exhibited an initial rapid phase of inactivation followed by a secondary slower inward current component that decayed over about 100 ms. The secondary inward component appeared as a slowly decaying inward tail current following short (10-40 ms) depolarizing clamp steps. 3. Slowly decaying inward currents were abolished by internally dialysing pacemaker cells with 2 mM EGTA using a ruptured patch recording method. Inward tail currents were also abolished by exposure to 1 microM ryanodine and significantly decreased by replacing 85% of external Na+ with lithium, without effect on peak ICa. These findings identify a Na(+)-Ca2+ exchange current (INa-Ca) that is mediated by sarcoplasmic reticulum (SR) Ca2+ release. 4. Properties of INa-Ca and ICa differed significantly: (i) ICa exhibited a bell-shaped voltage dependence that peaked at 0 mV and decreased at more positive voltages. INa-Ca was maximal at -10 mV and remained relatively constant at more positive voltages; (ii) a paired pulse protocol showed that the time course of INa-Ca recovery (5 s) was significantly longer than that of ICa (2 s); (iii) cadmium (50 microM) induced an inhibition of ICa that did not correlate in time with changes in INa-Ca. 5. The duration of depolarizing steps between 10 and 120 ms had no effect on the time course of INa-Ca tail currents. 6. Isoprenaline > or = 5 x 10(-8) M significantly increased peak ICa amplitude, peak INa-Ca amplitude, accelerated INa-Ca rate of decay and decreased the absolute time of INa-Ca decay. 7. Free-running pacemaker action potentials were clamped during diastole at either -40 or -70 mV (maximum diastolic potential) for variable periods of time. At times between 0.2 and 1 s, INa-Ca exhibited a voltage-dependent increase in amplitude over time, i.e. INa-Ca recovered more rapidly from -70 mV than from -40 mV. At times > 2 s, INa-Ca exhibited a voltage-dependent decline in amplitude over time, i.e. from -40 mV INa-Ca decreased by 10% of maximum whereas from -70 mV INa-Ca decreased by 60% of maximum.(ABSTRACT TRUNCATED AT 400 WORDS)

Effect of isoprenaline on I(f) current in latent pacemaker cells isolated from cat right atrium: ruptured vs. perforated patch whole-cell recording methods

Whole-cell recording techniques were used to study the time-dependent inward current activated on hyperpolarization (I(f)) and its response to isoprenaline in latent atrial pacemaker cells isolated from cat right atrium. To determine whether the response to isoprenaline depended on the type of recording method, we analysed I(f) using either a standard ruptured-patch, or a nystatin-perforated-patch, whole-cell recording method. All cells beat rhythmically at 35 degrees C and exhibited normal pacemaker action potentials and I(f) current, regardless of the recording method. With the ruptured-patch method, pacemaker action potentials ceased activity within a few minutes and I(f) amplitude decreased "ran down" to 74% of control within 10 min of rupturing the patch. Isoprenaline (1 microM) elicited variable changes in I(f) amplitude among different latent pacemaker cells resulting in no net change in mean current amplitude (n = 6). In addition, isoprenaline failed to change the voltage dependence of the I(f) activation curve. On the other hand, using a nystatin-perforated-patch method, pacemaker action potentials and I(f) exhibited no significant changes over the same 10 min period. Under these conditions, isoprenaline consistently increased I(f) in all cells studied (+90%) at -80 mV; n = 8), and increased the spontaneous rate of pacemaker action potentials by 58 +/- 7% (n = 5). Moreover, isoprenaline elicited a significant positive shift (+11 mV) in the half-maximal activation voltage of the I(f) activation curve (n = 3). We conclude that latent atrial pacemakers consistently exhibit I(f) current, and that isoprenaline consistently elicits an increase in I(f) amplitude.(ABSTRACT TRUNCATED AT 250 WORDS)