Electrophysiology of parasympathetic neurones isolated from the interatrial septum of bull-frog heart

Inactivation of Native K Channels

We have experimented with isolated cardiomyocytes of mollusks Helix. During the whole-cell patch-clamp recordings of K⁺ currents a considerable decrease in amplitude was observed upon repeated voltage steps at 0.96 Hz. For these experiments, ventricular cells were depolarized to identical + 20 mV from a holding potential of - 50 mV. The observed spontaneous inhibition of outward currents persisted in the presence of 4-aminopyridine, tetraethylammonium chloride or E-4031, the selective class III antiarrhythmic agent that blocks HERG channels. Similar tendency was retained when components of currents sensitive to either 4-AP or TEA were mathematically subtracted. Waveforms of currents sensitive to 1 and 10 micromolar concentration of E-4031 were distinct comprising prevailingly those activated during up to 200 ms pulses. The outward current activated by a voltage ramp at 60 mV x s^-1 rate revealed an inward rectification around + 20 mV. This feature closely resembles those of the mammalian cardiac delayed rectifier I_Kr.

Biophysical characterization of whole-cell currents in O2-sensitive neurons from the rat glossopharyngeal nerve

In this study we use nystatin perforated-patch and conventional whole-cell recording to characterize the biophysical properties of neuronal nitric oxide synthase (nNOS)-expressing paraganglion neurons from the rat glossopharyngeal nerve (GPN), that are thought to provide NO-mediated efferent inhibition of carotid body chemoreceptors. These GPN neurons occur in two populations, a proximal one near the bifurcation of the GPN and the carotid sinus nerve, and a more distal one located further along the GPN. Both populations were visualized in whole mounts by vital staining with the styryl pyridinium dye, 4-Di-2-ASP (D289). Following isolation in vitro, proximal and distal neurons had similar input resistances (mean: 1.5 and 1.6 GOmega, respectively), input capacitances (mean: 25.0 and 27.4 pF, respectively), and resting potentials (mean: -53.9 and -53.3 mV, respectively). All neurons had similar voltage-dependent currents composed of: tetrodotoxin (TTX)-sensitive Na+ currents (IC50 approximately 0.2 microM), prolonged and transient Ca2+ currents, and delayed rectifier-type K+ currents. Threshold activation for the Na+ currents was approximately -30 mV and they were inactivated within 10 ms. Inward Ca2+ currents consisted of nifedipine-sensitive L-type, omega-agatoxin IVA-sensitive P/Q-type, omega-conotoxin GVIA-sensitive N-type, SNX-482-sensitive R-type, and Ni2+-sensitive, but SNX-482-insensitive, T-type channels. The voltage-dependent outward K+ currents were sensitive to tetraethylammonium (TEA; 10 mM) and 4-aminopyridine (4-AP; 2 mM). Exposure to a chemosensory stimulus, hypoxia (PO2 range: 80-5 Torr), caused a dose-dependent decrease in K+ current which persisted in the presence of TEA and 4-AP, consistent with the involvement of background K+ channels. Under current clamp, GPN neurons generated TTX-sensitive action potentials, and in spontaneously active neurons, hypoxia caused membrane depolarization and an increase in firing frequency. These properties endow GPN neurons with an exquisite ability to regulate carotid body chemoreceptor function during hypoxia, via voltage-gated Ca2+-entry, activation of nNOS, and release of NO.

Effects of the venom of a Mygalomorph spider (Lasiodora sp.) on the isolated rat heart

We studied the effect of the venom of the Brazilian spider, Lasiodora sp. (Mygalomorphae, Theraphosidae), on force generation and electrical activity in the isolated rat heart. Previous work showed that this venom is excitotoxic to excitable cells due to Na(+) channel gating modifier activity [Toxicon 39 (2001) 991]. In the isolated heart, the venom (10-100 microg bolus administration) caused a dose-dependent bradycardia, with transient cardiac arrest and rhythm disturbances. The electrocardiogram showed that the reduction of heart rate was due to sinus bradycardia, sinus arrest and partial or complete A-V block. All of the effects were reversible upon washout of the venom. The effect of the venom was potentiated by the anticholinesterase neostigmine (3.3 microM), suppressed by the muscarinic acetylcholine receptor antagonist atropine (1.4 microM), and inhibited by the vesicular acetylcholine transporter inhibitor (-)-vesamicol (10 microM). Tetrodotoxin (200 nM) did not inhibit the effect of the venom. Together, these data suggest that this Lasiodora venom evokes vesicular release of acetylcholine from parasympathetic nerve terminals by activating tetrodotoxin-resistant Na(+) channels.

Spontaneous miniature hyperpolarizations affect threshold for action potential generation in mudpuppy cardiac neurons

Mudpuppy parasympathetic neurons exhibit spontaneous miniature hyperpolarizations (SMHs) that are generated by potassium currents, which are spontaneous miniature outward currents (SMOCs), flowing through clusters of large conductance voltage- and calcium (Ca(2+))-activated potassium (BK) channels. The underlying SMOCs are initiated by a Ca(2+)-induced Ca(2+) release (CICR) mechanism. Perforated-patch whole cell voltage recordings were used to determine whether activation of SMHs contributed to action potential (AP) repolarization or affected the latency to AP generation. Blockade of BK channels by iberiotoxin (IBX, 100 nM) slowed AP repolarization and increased AP duration. Treatment with omega-conotoxin GVIA (3 microM) or nifedipine (10 microM) to inhibit Ca(2+) influx through N- or L-type voltage-dependent calcium channels (VDCCs), respectively, also decreased the rate of AP repolarization and increased AP duration. Elimination of CICR by treatment with either thapsigargin (1 microM) or ryanodine (10 microM) produced no significant change in AP repolarization or duration. Blockade of BK channels with IBX and inhibition of N-type VDCCs with omega-conotoxin GVIA, but not inhibition of L-type VDCCs with nifedipine, decreased the latency of AP generation. A decrease in latency to AP generation occurred with elimination of SMHs by inhibition of CICR following treatment with thapsigargin. Ryanodine treatment decreased AP latency in three of six cells. Apamin (100 nM) had no affect on AP repolarization, duration, or latency to AP generation, but did decrease the hyperpolarizing afterpotential (HAP). Inhibition of L-type VDCCs by nifedipine also decreased HAP amplitude. Inhibition of CICR by either thapsigargin or ryanodine treatment increased the number of APs generated with long depolarizing current pulses, whereas exposure to IBX or omega-conotoxin GVIA depressed excitability. We conclude that CICR, the process responsible for SMH generation, represents a unique mechanism to modulate the response to subthreshold depolarizing currents that drive the membrane potential toward the threshold for AP initiation but does not contribute to AP repolarization. Subthreshold depolarizations would not activate sufficient numbers of VDCCs to allow Ca(2+) influx to elevate [Ca(2+)](i) to the extent needed to directly activate nearby BK channels. However, the elevation in [Ca(2+)](i) is sufficient to trigger CICR from ryanodine-sensitive Ca(2+) stores. Thus CICR acts as an amplification mechanism to trigger a local elevation of [Ca(2+)](i) near a cluster of BK channels to activate these channels at negative levels of membrane potential.

Volatile anesthetics reduce calcium current in parasympathetic neurons from bullfrog hearts

Although the autonomic nervous system regulates cardiac function, the cellular mechanism(s) of general anesthetics on the activities of parasympathetic neurons have not been directly assessed. We therefore studied the volatile anesthetic actions on the Ca2+ current of parasympathetic neurons isolated from bullfrog hearts. Neurons were enzymatically isolated from the interatrial septum of bullfrog heart and maintained in a short-term tissue culture. The Ca2+ current was recorded with a whole-cell voltage-clamp method under a Na+, K+ -free condition. Isoflurane (2.5 vol%) and sevoflurane (5.0 vol%) reduced the peak amplitude of the Ca2+ current (to 79% and 72% of control, respectively) without changing the reversal potential. The curve-fit analysis of the inactivation kinetics revealed that isoflurane and sevoflurane accelerated the inactivation of the current and that isoflurane shifted the midpoint of the steady-state inactivation curve of the Ca2+ current toward negative by 13.6 mV. The results indicate that volatile anesthetics reduce the Ca2+ current of parasympathetic neurons and modify the inactivation kinetics.

IMPLICATIONS

The anesthetic reduction of the Ca2+ current of parasympathetic neurons can induce a decrease of acetylcholine release from the post-ganglionic endings. These findings, in part, account for the anesthetic attenuation of the vagal efferent activities observed in humans and experimental animals.

Calcium channel currents in acutely dissociated intracardiac neurons from adult rats

With the use of the whole cell patch-clamp technique, multiple subtypes of voltage-activated calcium channels, as indicated by measuring Ba2+ currents, were pharmacologically identified in acutely dissociated intracardiac neurons from adult rats. All tested neurons that were held at -80 mV displayed only high-voltage-activated (HVA) Ca2+ channel currents that were completely blocked by 100 microM CdCl2. The current density of HVA Ca2+ currents was dependent on the external Ca2+ concentration. The Ba2+ (5 mM) currents were half-activated at -16.3 mV with a slope of 5.6 mV per e-fold change. The steady-state inactivation was also voltage dependent with half-inactivation at -33.7 mV and a slope of -12.1 mV per e-fold change. The most effective L-type channel activator, FPL 64176 (2 microM), enhanced the Ba2+ current in a voltage-dependent manner. When cells were held at -80 mV, the saturating concentration (10 microM) of nifedipine blocked approximately 11% of the control Ba2+ current. The major component of the Ca2+ channels was N type (63%), which was blocked by a saturating concentration (1 microM) of omega-conotoxin GVIA. Approximately 19% of the control Ba2+ current was sensitive to omega-conotoxin MVIIC (5 microM) but insensitive to low concentrations (30 and 100 nM) of omega-agatoxin IVA (omega-Aga IVA). In addition, a high concentration (1 microM) of omega-Aga IVA occluded the effect of omega-conotoxin MVIIC. Taken together, these results indicate that the omega-conotoxin MVIIC-sensitive current represents only the Q type of Ca2+ channels. The current that was insensitive to nifedipine and various toxins represents the R-type current (7%), which was sensitive to 100 microM NiCl2. In conclusion, the intracardiac neurons from adult rats express at least four different subtypes (L, N, Q, and R) of HVA Ca2+ channels. This information is essential for understanding the regulation of synaptic transmission and excitability of intracardiac neurons by different neurotransmitters and neural regulation of cardiac functions.

Voltage-gated currents in identified parasympathetic cardiac neurons in the nucleus ambiguus

Heart rate is normally dominated by the activity of the cardioinhibitory parasympathetic nervous system, while abnormally low levels of parasympathetic cardiac activity have been implicated in many cardiovascular diseases including hypertension, heart failure and sudden cardiac death. In this study we have examined the voltage-gated currents in parasympathetic cardiac neurons that were identified with a retrograde fluorescent tracer in visualized sections (250 microns) of nucleus ambiguus. Depolarization of parasympathetic cardiac neurons to potentials more positive than -50 mV evoked a rapidly activating and inactivating inward current which could be blocked by tetrodotoxin (TTX), although in some neurons up to 10 microM was required for complete block. The voltage-dependent inactivation properties of this Na current showed relatively broad inactivation characteristics, a characteristic of TTX-resistant Na channels. Depolarization also elicited biphasic outward currents, which were separated into a transient IA type K current using the specific channel antagonist 4-aminopyridine and a long-lasting delayed rectified K current. These voltage-gated Na and K currents define the action potential firing patterns of parasympathetic cardiac neurons, such as frequency adaptation and spike delay, and also determine the activity of these neurons in response to depolarizing and hyperpolarizing synaptic innervation.

Single-channel analysis of two types of Na+ currents in rat dorsal root ganglia

The properties of voltage-gated Na+ channels were studied in neurones isolated from rat dorsal root ganglia using the outside-out configuration of the patch-clamp technique. Two types of single-channel currents were identified from the difference in unit amplitudes. Neither type was evoked in the medium in which extracellular Na+ ions were replaced by an equimolar amount of tetramethylammonium ions. The two types of single-channel currents differed in their sensitivity to tetrodotoxin (TTX). The smaller channel current was insensitive to 1 microM TTX (referred to as TTX-I), while the larger channel current was blocked by 1 nM TTX (TTX-S). The unit amplitudes measured during a step depolarization to -30 mV (1.4 mM internal and 250 mM external Na+ concentrations) were 1.16 pA for TTX-S and 0.57 pA for TTX-I, respectively. The slope conductance measured at -30 mV was 16.3 pS for TTX-S and 8.5 pS for TTX-I. TTX-S could be activated by step depolarizations positive to -60 mV, while TTX-I could be activated at potentials positive to -40 mV. When the test pulse was preceded by a depolarizing prepulse, the prepulse positive to -50 mV preferentially inactivated TTX-S with a minimal effect on TTX-I. Activation and inactivation time courses of the averaged ensemble currents computed from TTX-S showed remarkable resemblances to the time courses of the macroscopic TTX-sensitive Na+ current. Similarly, the ensemble currents of TTX-I mimicked the macroscopic TTX-insensitive Na+ current. It was concluded that the two types of Na+ channels in rat dorsal root ganglia differ not only in their sensitivity to TTX, but also in their single-channel conductances.

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.

The tetrodotoxin-insensitive sodium current in rat dorsal root ganglia is unlikely to involve the expression of the tetrodotoxin-resistant sodium channel, SkM2

Tetrodotoxin-insensitive (TTX-I) sodium currents have been recorded from newborn and adult rat sensory neurons, but the sodium channel gene(s) responsible for the TTX-I current are unknown. Because SkM2, one of six voltage-sensitive sodium channel genes cloned from rat, encodes the only cloned channel that is relatively resistant to tetrodotoxin, we sought to test whether the TTX-I current in rat sensory neurons is due to the SkM2 channel. We hypothesized that the TTX-I current might be generated from (1) an RNA splicing variant of SkM2, (2) post-translational modification of the SkM2 protein, or (3) interaction with alternate additional channel subunits. SkM2 mRNA expression was examined in newborn rat dorsal root ganglia (DRG) by RNase protection assay. No SkM2 expression was detected. Therefore, we conclude that the TTX-I sodium current in DRG is unlikely to result from the expression of the SkM2 gene.

Tetrodotoxin-resistant sodium channels

1. Tetrodotoxin (TTX) has been widely used as a chemical tool for blocking Na+ channels. However, reports are accumulating that some Na+ channels are resistant to TTX in various tissues and in different animal species. Studying the sensitivity of Na+ channels to TTX may provide us with an insight into the evolution of Na+ channels. 2. Na+ channels present in TTX-carrying animals such as pufferfish and some types of shellfish, frogs, salamanders, octopuses, etc., are resistant to TTX. 3. Denervation converts TTX-sensitive Na+ channels to TTX-resistant ones in skeletal muscle cells, i.e., reverting-back phenomenon. Also, undifferentiated skeletal muscle cells contain TTX-resistant Na+ channels. Cardiac muscle cells and some types of smooth muscle cells are considerably insensitive to TTX. 4. TTX-resistant Na+ channels have been found in cell bodies of many peripheral nervous system (PNS) neurons in both immature and mature animals. However, TTX-resistant Na+ channels have been reported in only a few types of central nervous system (CNS). Axons of PNS and CNS neurons are sensitive to TTX. However, some glial cells have TTX-resistant Na+ channels. 5. Properties of TTX-sensitive and TTX-resistant Na+ channels are different. Like Ca2+ channels, TTX-resistant Na+ channels can be blocked by inorganic (Co2+, Mn2+, Ni2+, Cd2+, Zn2+, La3+) and organic (D-600) Ca2+ channel blockers. Usually, TTX-resistant Na+ channels show smaller single-channel conductance, slower kinetics, and a more positive current-voltage relation than TTX-sensitive ones. 6. Molecular aspects of the TTX-resistant Na+ channel have been described. The structure of the channel has been revealed, and changing its amino acid(s) alters the sensitivity of the Na+ channel to TTX. 7. TTX-sensitive Na+ channels seem to be used preferentially in differentiated cells and in higher animals instead of TTX-resistant Na+ channels for rapid and effective processing of information. 8. Possible evolution courses for Na+ and Ca2+ channels are discussed with regard to ontogenesis and phylogenesis.

Short-term diabetes alters K+ currents in rat ventricular myocytes

The electrophysiological properties of single ventricular myocytes from control rats and from rats made diabetic by streptozotocin (STZ) injection (100 mg/kg body weight) have been investigated using whole-cell voltage-clamp measurements. Our major goal was to define the effects of diabetes on rate-dependent changes in action potential duration and the underlying outward K+ currents. As early as 4 to 6 days after STZ treatment, significant elevation of plasma glucose levels occurs, and the action potential duration increases. In both control and diabetic rats, when the stimulation rate is increased, the action potential is prolonged, but this lengthening is considerably more pronounced in myocytes from diabetic rats. In ventricular myocytes from diabetic rats, the Ca(2+)-independent transient outward K+ current (I(t)) is reduced in amplitude, and its reactivation kinetics are slowed. These changes result in a smaller I(t) at physiological heart rates. The steady-state outward K+ current (IK) also exhibits rate-dependent attenuation, and this phenomenon is more pronounced in cells from diabetic rats. These STZ-induced changes in I(t) and IK also develop when a lower dose (55 mg/kg) of STZ is used and measurements are made after 7 weeks of treatment. These electrophysiological effects are not related to the hypothyroid conditions that accompany the diabetic state, since they cannot be reversed by replacement of the hormone L-triiodothyronine to physiological levels. Direct effects of STZ could be ruled out, since preceding the STZ injection with a bolus injection of 3-O-methylglucose, which prevents development of hyperglycemia, prevents the electrophysiological changes.(ABSTRACT TRUNCATED AT 250 WORDS)

Intracellular ATP changes the voltage-dependence of delayed rectifier potassium current in bullfrog primary afferent neurons

Dissociated bullfrog dorsal root ganglion cells were voltage-clamped in the whole-cell configuration to study the steady-state activation and inactivation curves for a delayed rectifier potassium current. The 50%-activation of the current occurred at +15 mV when measured with ATP (5 mM) in the pipette solution as opposed to -11 mV with 5'-adenylylimidodiphosphate (AMP-PNP, 5 mM) and -15 mV with adenosine 5'-O-(3-thiotriphosphate) (5 mM). The 50%-inactivation of the current occurred at -6 mV with ATP but at -31 mM with AMP-PNP. The results suggest that intracellular ATP modulates voltage-dependence of the delayed rectifier in amphibian afferent neurons.

Kinetic analysis of two types of Na+ channels in rat dorsal root ganglia

1. The gating properties of two types of Na+ channels were studied in neurones isolated from rat dorsal root ganglia using the whole cell variation of the patch electrode voltage-clamp technique. 2. Two types of Na+ currents (INa) were identified on the basis of their sensitivity to tetrodotoxin (TTX). One type was insensitive to TTX (up to 0.1 mM), while the other type was blocked by 1 nM of TTX. Whereas they were both insensitive to 50 microM Cd2+, a high concentration (2 mM) of Co2+ selectively inhibited the TTX-insensitive type. 3. The activation thresholds were about -60 and -40 mV for the TTX-sensitive and the TTX-insensitive INa, respectively. Activation of the TTX-sensitive INa developed with a sigmoidal time course which was described by m3 kinetics, whereas the activation of the TTX-insensitive INa was described by a single exponential function. A deactivation process, as measured by the tail current upon repolarization, followed an exponential decay in either type of INa. 4. The rate constant of activation indicated that under comparable membrane potential conditions, the TTX-insensitive channels open 4-5 times slower than the TTX-sensitive ones upon depolarization. Likewise, the rate constant of inactivation indicated that the TTX-insensitive channels inactivate 3-7 times more slowly than the TTX-sensitive ones upon repolarization. 5. The steady-state activation curve for the TTX-insensitive INa was shifted about 20 mV in the positive direction from that for the TTX-sensitive INa. 6. The steady-state inactivation curve for the TTX-insensitive INa as obtained with a 0.5 s prepulse was shifted about 26 mV in the positive direction from that for the TTX-sensitive INa, indicating a greater availability for the TTX-insensitive INa in depolarized membrane. However, on increasing the duration of prepulse, the inactivation curve for the TTX-insensitive INa, but not for the TTX-sensitive INa, shifted in the negative direction due to an extremely slow inactivation process in the TTX-insensitive INa. Consequently, an overlap between the activation and inactivation curves which causes a steady influx of Na+ (window current) became progressively reduce. 7. The time course of INa decay was best described by a single exponential process in either the TTX-sensitive or TTX-insensitive INa, whereas the development of inactivation and the recovery from inactivation, which were measured by a conventional double-pulse protocol, followed a second order process in either channel type.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of TTX-sensitive and TTX-resistant sodium currents in small cells from adult rat dorsal root ganglia

1. The whole-cell patch-clamp technique was used to investigate the characteristics of two types of sodium current (INa) recorded at room temperature from small diameter (13-25 microns) dorsal root ganglion (DRG) cells, isolated from adult rats and maintained overnight in culture. 2. Sodium currents were isolated pharmacologically. Internal Cs+ and external tetraethylammonium (TEA) ions were used to suppress potassium currents. A combination of internal EGTA, internal F-, a low (10 microM) concentration of external Ca2+ and a relatively high (5 mM) concentration of internal and external Mg2+ was used to block calcium channels. The remaining voltage-dependent currents reversed direction at the calculated sodium equilibrium potential. Both the reversal potential and magnitude of the currents exhibited the expected dependence on the external sodium concentration. 3. INa subtypes were characterized initially in terms of their sensitivity to tetrodotoxin (TTX). TTX-sensitive (TTXs) currents were at least 97% suppressed by 0.1 microM TTX. TTX-resistant (TTXr) INa were recorded in the presence of 0.3 microM TTX and appeared to be reduced in amplitude by less than 50% in 75 microM TTX (n = 1). 4. As in earlier studies, the peak of the current-voltage relationship, the mid-point of the normalized conductance curve and the potential (Vh) at which the steady-state inactivation parameter (h infinity) was 0.5 were found to be significantly more depolarized for the TTXr INa (by ca 10, 14 and 37 mV respectively). There was little difference in the slope at the mid-point of the normalized conductance curves (the mean slope factors were 5.1 mV for the TTXs INa and 4.9 mV for the TTXr current) but the h infinity curves for TTXr currents were significantly steeper than those for TTXs currents (mean slope factors of 3.8 and 11.5 mV respectively). Both the time to peak and the decay time constant of the peak current recorded from a holding potential of -67 mV were more than a factor of three slower for the TTXr INa than for the TTXs current. 5. However, in direct contrast to the difference in activation and decay kinetics, 'slow' TTXr INa recovered from inactivation at -67mV, or reprimed, more than a factor of ten faster than 'fast' TTXs INa. 6. The differences apparent in both the repriming kinetics of TTXs and TTXr INa at -67 mV and the kinetics of the decay phase of the peak INa are shown to be explicable largely in terms of the voltage dependence of their respective inactivation systems.(ABSTRACT TRUNCATED AT 400 WORDS)

Nicotinic and muscarinic synaptic transmission in canine intracardiac ganglion cells innervating the sinoatrial node

Nicotinic and muscarinic mediated synaptic mechanisms were investigated in isolated, canine intracardiac ganglia taken from the right atrial fat pad. Using conventional intracellular microelectrode recording techniques on 216 neurons, fast and slow synaptic potentials were evoked by single or trains of stimulation of presynaptic fibers in interganglionic nerves. By varying the stimulus intensity, single or multiple fast excitatory postsynaptic potentials (f-EPSPs) were evoked, indicating the convergence of synaptic inputs on these cells. These f-EPSPs often reached the action potential threshold, were enhanced by the acetylcholinesterase inhibitor physostigmine and were blocked by the nicotinic antagonist hexamethonium. The f-EPSPs were accompanied by a decreased input resistance and had an extrapolated reversal potential of -7.1 mV, suggesting increased conductances to more than one cation. Repetitive presynaptic stimulation evoked slow excitatory postsynaptic potentials (s-EPSPs) in 41% of the cells while slow inhibitory postsynaptic potentials (s-IPSPs) or s-IPSPs followed by s-EPSPs were evoked in 19% of the cells. All slow potentials were abolished by atropine and low Ca2+/high Mg2+ solutions and enhanced by physostigmine. Hexamethonium and adrenergic receptor antagonists had no effects on s-EPSP and s-IPSP. The M1 receptor antagonist pirenzepine reversibly blocked the s-EPSP but not the s-IPSP. On the other hand, the M2 receptor blocker 4-diphenyl-acetoxy-N-methyl piperidine methiodide (4-DAMP) had no effects on the s-EPSP. These observations suggest that s-EPSPs and s-EPSPs are mediated by distinct muscarinic receptors. The amplitude of the s-EPSP and the depolarization evoked by the muscarinic agonist, bethanechol were accompanied by increased input resistance. These responses were decreased in amplitude by membrane hyperpolarization and either reversed polarity or declined to zero amplitude at about -80 mV, suggesting the inhibition of a potassium conductance.

Bethanechol-induced responses in mudpuppy parasympathetic neurons

The effect of bethanechol on membrane potential and excitability was determined in mudpuppy parasympathetic postganglionic neurons. Bethanechol induced a large amplitude hyperpolarization, which was followed by a smaller amplitude depolarization, in 115 out of 135 cells tested. In approximately 20% of these cells, a brief depolarization preceded the hyperpolarization. During the bethanechol-induced hyperpolarization, the membrane input resistance decreased markedly, whereas the input resistance was increased during the subsequent depolarization. The hyperpolarization and depolarization were blocked by atropine and were unaffected by d-tubocurarine, thus, both appeared to be mediated by muscarinic receptors. The bethanechol-induced hyperpolarization was inhibited by the M2 muscarinic receptor antagonist AF-DX 116, whereas the bethanechol-induced depolarization was unaffected. Both a nonselective increase in membrane conductance and a decrease in membrane potassium conductance appeared to be involved in the generation of the bethanechol-induced depolarization. Evidence for the first mechanism was obtained in barium-treated cells in which bethanechol initiated a rapid onset depolarization, which was reversed at membrane potentials near 0 mV. Evidence for the second mechanism was obtained when the hyperpolarization was inhibited by AF-DX 116. In AF-DX 116-treated cells, the membrane input resistance was increased during most of the bethanechol-induced depolarization. Mudpuppy neurons initiate repetitive action potential activity in response to long depolarizing current pulses. Following application of bethanechol, with the hyperpolarization negated electrotonically, the number of action potentials produced by a depolarizing current pulse was greater than that produced prior to application of bethanechol. It is suggested that activation of muscarinic receptors on mudpuppy cardiac neurons influences multiple conductance systems and determines the excitability of these neurons.

Voltage-dependent sodium and calcium currents in cultured parasympathetic neurones from rat intracardiac ganglia

1. Depolarization-activated Na+ and Ca2+ currents underlying the rising phase of the action potential in mammalian parasympathetic ganglion cells were investigated in voltage-clamped neurones dissociated from neonatal rat intracardiac ganglia and maintained in tissue culture. 2. A current component isolated by replacing intracellular K+ with Cs+ or arginine and adding 0.1 mM Cd2+ to the external solution was dependent on extracellular [Na+] and reversibly blocked in the presence of 300 nM tetrodotoxin (TTX). Peak amplitudes of Na+ currents elicited by step depolarization from a holding potential of -100 mV were 351 +/- 18 pA/pF (140 mM extracellular Na+). 3. The sodium current-voltage (I-V) curve exhibited a threshold for activation at -40 mV and reached a maximum at -10 mV. The Na+ conductance increased sigmoidally with increasing depolarization reaching half-maximal activation at -25 mV, with a maximum slope corresponding to 7.5 mV per e-fold change in conductance. 4. During a maintained depolarization, Na+ currents turned on and then decayed (inactivated) with an exponential time course. The time constant of inactivation was voltage dependent decreasing from 0.85 ms at -20 mV to 0.3 ms at +60 mV (23 degrees C). The steady-state inactivation of the Na+ conductance was voltage-dependent with half-inactivation occurring at -61 mV and near-complete inactivation at -20 mV. Recovery from inactivation also followed an exponential time course with a time constant that increased at depolarized membrane potentials. 5. A voltage- and Ca(2+)-dependent current was isolated by replacement of intracellular K+ with either Cs+ or arginine and of extracellular Na+ with tetraethylammonium and the addition of TTX. Extracellular Ba2+ or Na+ (in the absence of external divalent cation) could substitute for Ca2+. Peak Ca2+ current increased with increasing extracellular [Ca2+] and above 10 mM (Kd approximately 4 mM) approached saturation. The peak Ca2+ current density was 45 +/- 4 pA/pF (2.5 mM-extracellular Ca2+). 6. The Ca2+ I-V relation exhibited a high threshold for activation (-20 mV) and reached a maximum at +20 mV. Changing the holding potential from -100 to -40 mV did not alter the I-V relationship. Peak Ca2+ conductance increased sigmoidally with increasing depolarization reaching half-maximal activation at -4 mV, with a maximal slope of 4 mV per e-fold change in Ca2+ conductance. 7. The kinetics of activation and inactivation of the Ca2+ current were voltage dependent and the time course of inactivation was fitted by the sum of two exponentials.(ABSTRACT TRUNCATED AT 400 WORDS)

Resting membrane potential and potassium currents in cultured parasympathetic neurones from rat intracardiac ganglia

1. Whole-cell K+ currents contributing to the resting membrane potential and repolarization of the action potential were studied in voltage-clamped parasympathetic neurones dissociated from neonatal rat intracardiac ganglia and maintained in tissue culture. 2. Rat intracardiac neurones had a mean resting membrane potential of -52 mV and mean input resistance of 850 M omega. The current-voltage relationship recorded during slow voltage ramps indicated the presence of both leakage and voltage-dependent currents. The contribution of Na+, K+ and Cl- to the resting membrane potential was examined and relative ionic permeabilities PNa/PK = 0.12 and PCl/PK < 0.001 were calculated using the Goldman-Hodgkin-Katz voltage equation. Bath application of the potassium channel blockers, tetraethylammonium ions (TEA; 1 mM) or Ba2+ (1 mM) depolarized the neurone by approximately 10 mV. Inhibition of the Na(+)-K+ pump by exposure to K(+)-free medium or by the addition of 0.1 mM ouabain to the bath solution depolarized the neurone by 3-5 mV. 3. In most neurones, depolarizing current pulses (0.5-1 s duration) elicited a single action potential of 85-100 mV, followed by an after-hyperpolarization of 200-500 ms. In 10-15% of the neurones, sustained current injection produced repetitive firing at maximal frequency of 5-8 Hz. 4. Tetrodotoxin (TTX; 300 nM) reduced, but failed to abolish, the action potential. The magnitude and duration of the TTX-insensitive action potential increased with the extracellular Ca2+ concentration, and was inhibited by bath application of 0.1 mM Cd2+. The repolarization rate of the TTX-insensitive action potential was reduced, and after-hyperpolarization was replaced by after-depolarization upon substitution of internal K+ by Cs+. The after-hyperpolarization of the action potential was reduced by bath application of Cd2+ (0.1 mM) and abolished by the addition of Cd2+ and TEA (10 mM). 5. Depolarization-activated outward K+ currents were isolated by adding 300 nM TTX and 0.1 mM Cd2+ to the external solution. The outward currents evoked by step depolarizations increased to a steady-state plateau which was maintained for > 5 s. The instantaneous current-voltage relationship, examined under varying external K+ concentrations, was linear, and the reversal (zero current) potential shifted in accordance with that predicted by the Nernst equation for a K(+)-selective electrode. The shift in reversal potential of the tail currents as a function of the extracellular K+ concentration gave a relative permeability, PNa/PK = 0.02 for the delayed outward K+ channel(s).(ABSTRACT TRUNCATED AT 400 WORDS)

Membrane properties and firing characteristics of rat cardiac neurones in vitro

Electrophysiological characteristics of neurones in isolated cardiac ganglia from the left atrium and interatrial septum of the rat were studied with intracellular microelectrodes. At rest the neurones were characterized by a membrane potential of -52.6 +/- 0.83 mV, an input resistance of 85.6 +/- 7.6 M omega, a membrane time constant of 4.6 +/- 0.24 ms and an input capacitance of 63.1 +/- 5.25 pF. Removal of Ca2+ ions from the external solution resulted in a membrane depolarisation of 5.5 +/- 0.70 mV and an increase in input resistance of 96 +/- 52% which indicated that a substantial Ca(2+)-sensitive component contributed to resting membrane potential. A prolonged after-hyperpolarization (AHP) was recorded following a train of spikes; this was inhibited in a Ca(2+)-free solution, indicating that a Ca(2+)-sensitive component of potassium conductance contribute to it. On the basis of the duration of the AHP following a single spike, two types of neurones, I and II, were tentatively identified, having short (less than 300 ms) and long (greater than 300 ms) AHPs, respectively. Type I neurones responded to prolonged membrane depolarization with bursts of firing (Ib neurones) or multiple discharges (Im neurones). Type II neurones also responded with single spikes or multiple discharges to prolonged membrane depolarization. In some Im neurones, tonic firing was recorded which was inhibited by a hyperpolarizing current and accelerated by a depolarizing current injected through the recording microelectrode. Thus, neurones of isolated cardiac ganglia of the rat from the region studied here are heterogeneous in their electrical behaviour, suggesting the existence of functionally different groups within the ganglia.

Electrophysiological properties of in vitro intrinsic cardiac neurons in the pig (Sus scrofa)

Physiological properties and synaptically mediated responses of 34 ganglionated plexus neurons from the right atrium of the pig heart were studied with in vitro intracellular recording techniques. Whole-cell input resistance of these neurons was lower, time constant was shorter, and threshold for directly evoked action potentials was higher than the same properties in extracardiac autonomic neurons. Long intracellular depolarizing current pulses (400-500 ms) failed to generate more than one or two action potentials. Nicotinic and non-nicotinic synapses were present on neurons in cardiac ganglia and neuronal properties could be modified by norepinephrine. Based on their physiological properties, cardiac ganglionated plexus neurons in the pig appear to represent a distinct population of autonomic neurons that may be capable of intracardiac integration of efferent information to the heart.

TTX-sensitive Na+ channels and Ca2+ channels of the L- and N-type underlie the inward current in acutely dispersed coeliac-mesenteric ganglia neurons of adult rats

Inward membrane currents of sympathetic neurons acutely dispersed from coeliac-superior mesenteric ganglia (C-SMG) of adult rats were characterized using the whole-cell variant of the patch-clamp technique. Current-clamp studies indicated that C-SMG neurons retained electrical properties similar to intact ganglia. Voltage-clamp studies designed to isolate Na+ currents revealed that tetrodotoxin (TTX, 1 microM) completely inhibited the large transient inward current. Half activation potential (Vh) and slope factor (K) were -26.8 mV and 6.1 mV, respectively. Inactivation parameters for Vh and K were -65 mV and 8.2 mV, respectively. Voltage-clamp studies also revealed a high-voltage-activated sustained inward Ca2+ current which was blocked by the removal of external Ca2+ or the presence of Cd2+ (0.1 mM). The dihydropyridine agonist, (+)202-791 (1 microM), caused a small increase (20%) in the amplitude of the Ca2+ current at more negative potentials and markedly prolonged the tail currents. omega-Conotoxin GIVA (omega, CgTX, 15 microM) caused a 66% inhibition of the high-voltage-activated Ca2+ current amplitude. Norepinephrine (1 microM) caused a 49% reduction in the peak Ca2+ current. This study is the first demonstration that dispersed C-SMG neurons from adult rats retain electrical characteristics similar to intact ganglia. A TTX-sensitive Na+ current as well as a high voltage-activated sustained Ca2+ current underlie the inward current in C-SMG neurons. The macroscopic Ca2+ current is composed of a small dihydropyridine-sensitive (L-type current) and a large omega-CgTx-sensitive (N-type current) component.(ABSTRACT TRUNCATED AT 250 WORDS)

Whole-cell currents in two subpopulations of cultured rat petrosal neurons with different tetrodotoxin sensitivities

In this study we use whole-cell recording to characterize at least two distinct populations of cultured neurons from perinatal rat petrosal or petrosal/jugular ganglia based on differential sensitivity of the transient inward Na+ current to tetrodotoxin. These ganglia supply chemoreceptor and baroreceptor afferents which mediate several cardiovascular reflexes. Approximately 50% of the neurons sampled had Na+ currents that were virtually unaffected by bath addition of tetrodotoxin (0.5-2.0 microM) but were abolished by choline substitution for external Na+. The majority of the remaining neurons had Na+ currents that were rapidly and reversibly blocked by 500 nM tetrodotoxin. A few cells had both tetrodotoxin-resistant and tetrodotoxin-sensitive Na+ currents. All neurons had similar voltage-activated Ca2+ and K+ currents. The inward Ca2+ current had no obvious fast transient or T-type component and appeared to be due mainly to the presence of long-lasting L-type Ca2+ channels. The outward currents consisted largely of a delayed rectifying K+ current (IKdr) and a Ca(2+)-activated K+ current (IKca), but no obvious fast transient K+ current (IA) was observed. Exposure to a chemosensory stimulus, hypoxia (PO2 approximately 20 Torr), had no effect on these neurons, in contrast to the pronounced decrease in K+ current it produces in cultured glomus cells, the presumed chemoreceptors and normal targets for a subset of petrosal neurons in vivo. Current-clamp recordings indicated that some neurons gave single spikes while others gave multiple spikes in response to long-depolarizing stimuli. No correlation between spiking behaviour and tetrodotoxin-sensitivity was observed. Thus, cultures enriched in petrosal neurons contain subpopulations with differential sensitivities to tetrodotoxin. Since many of these neurons innervate a single chemosensory target organ, the carotid body, it is of interest to know whether one or both subtypes can form functional synapses with glomus cells of the carotid body and mediate a chemoreceptor reflex.

The effects of muscarine and adrenaline on patch-clamped frog cardiac parasympathetic neurones

1. The whole-cell patch-clamp technique was used to record membrane currents from neurones which were acutely dissociated from the intra-atrial parasympathetic ganglia of Rana pipiens. The effects of muscarine and adrenaline were observed at a holding potential of -30 mV. Extracellular potassium concentration ([K+]o) was 2, 6 or 20 mM. 2. Muscarine (10 microM) produced inward current in thirteen cells, outward current in eighteen cells and seven cells were unaffected. Inward currents were observed in six out of ten neurones in which the intracellular solution contained adenosine triphosphate (ATP; 100 microM) and outward currents were seen in eleven out of fourteen neurones which contained adenosine 3',5'-cyclic monophosphate (cyclic AMP; 100 microM). 3. In five out of nine cells tested, the inward current produced by muscarine was attributable to a 30% depression of a voltage-dependent current which resembled the M-current (IM). Muscarine-induced inward current in the other four cells involved a steady-state conductance increase that reached a null potential at -10 mV. Modest IM suppression also contributed to the response in three of these four cells. 4. Adrenaline (10 or 100 microM) produced inward currents in twelve cells, outward current in ten cells and three cells were unaffected. Outward currents were only seen in cells which contained ATP or cyclic AMP (ten out of sixteen cells) whereas inward currents were seen in eight out of nine cells which did not contain adenosine nucleotides. These inward currents were always attributable to IM suppression. 5. The outward currents induced by muscarine and adrenaline resulted from an increase in a potassium conductance (GK) that exhibited inward rectification.

Sodium currents in smooth muscle cells freshly isolated from stomach fundus of the rat and ureter of the guinea-pig

1. Inward currents elicited by depolarization from holding potentials of -80 to -10 mV in single smooth muscle cells isolated from stomach fundus of the rat and ureter of the guinea-pig had two components. The initial fast component (Ifi) was activated and mostly inactivated within 1-2 and 10 ms, respectively, at 21 degrees C. The following sustained component (Isi) lasted over 50 and 500 ms in fundus and ureter cells, respectively. Ifi was blocked by tetrodotoxin but not affected by 0.5 microM-mu-conotoxin in both types of cells. Isi was abolished by the substitution of extracellular Ca2+ with Mn2+. 2. The sensitivity of Ifis to TTX was markedly different in fundus and ureter cells. The half-inhibition was obtained at 870 and 11 nM, respectively. The amplitude of Ifi was highly dependent on extracellular Na+ concentration in a solution containing 2.2 mM-Mn2+ and 0 mM-Ca2+ in both cells. It is concluded that Ifis in these cells are TTX-sensitive and mu-conotoxin-insensitive Na+ currents. 3. Some of the kinetics of INa measured at 10 degrees C were markedly different in fundus and ureter cells. The current-voltage relationships for Ifi in fundus and ureter cells had peaks at about -10 and 0 mV, respectively. The voltage dependence of the steady-state inactivation of Ifi was also significantly different in these cell types. The half-inactivation voltages were about -74 and -45 mV, respectively. The recovery time course from inactivation in fundus cells was about 10 times slower than that in ureter at -80 mV, where it was 25 ms. 4. The contribution of Ifi to the rising phase of an action potential was examined using TTX under current clamp mode at 21 degrees C. A fast notch-like potential elicited by a subthreshold stimulus for action potential generation was blocked by TTX in both types of cells. Action potentials elicited by a stimulus around threshold were occasionally suppressed by TTX, whereas an action potential was never observed when extracellular Ca2+ was replaced with Mn2+. 5. In conclusion, the existence of at least two types of Na+ channel currents, which were distinguished by their TTX sensitivity and kinetics, was strongly suggested in smooth muscle cells from the rat fundus and the guinea-pig ureter. INa in these cells may have a physiological role to accelerate the generation of an action potential by triggering a rapid activation of ICa, while not being essential for activation of action potentials.

Analysis of the galanin-induced decrease in membrane excitability in mudpuppy parasympathetic neurons

Previously, we showed that the neuropeptide galanin hyperpolarizes and decreases membrane excitability of mudpuppy parasympathetic neurons [Konopka L. M., McKeon T. W. and Parsons R. L. (1989) J. Physiol. 410, 107-122]. We also demonstrated that membrane excitability remains depressed when the agonist-induced potential change is negated electrotonically. We hypothesized that galanin inhibits the membrane conductances associated with spike generation. However, we cannot rule out the possibility that the decreased excitability is due to a galanin-induced increase in membrane potassium conductance which reduces the effectiveness of subsequent depolarizing stimuli. Therefore, in the present study we tested, with the galanin-induced hyperpolarization negated, whether the galanin-induced increased membrane potassium conductance was responsible for the decreased excitability. The results showed that the galanin-induced decreased excitability was not dependent on the peak amplitude of the galanin-induced hyperpolarization. Furthermore, the decreased excitability occurred in cells in which there was no measurable galanin-induced hyperpolarization. Moreover, in most cells the galanin-induced decrease in input resistance, measured at the peak of the hyperpolarization (3-25 mV), was less than 15% and when the hyperpolarization was negated electronically, the decrease was even less (approximately 2%). These results indicated that when the hyperpolarization was negated, the galanin-induced increase in potassium conductance was not responsible for the decreased excitability. In preparations pretreated with 5 mM tetraethylammonium, galanin decreased excitability which indicated that a galanin-induced decrease in the calcium-dependent potassium current was not necessary for the decreased excitability. Galanin also decreased excitability in preparations exposed to either 1-3 microM tetrodotoxin or 100-200 microM cadmium. Following galanin application, the threshold for initiation of tetrodotoxin-insensitive spikes was shifted to more positive membrane potentials. Galanin also decreased the amplitude and hyperpolarizing afterpotential of barium spikes in the absence of any agonist-induced hyperpolarization. These observations confirmed that galanin decreased the voltage-dependent calcium conductance. In the present study, we showed that when the hyperpolarization was negated, galanin decreased excitability by shifting the threshold for spike generation regardless of whether voltage-dependent sodium or calcium currents were primarily responsible for the depolarizing component of the action potential.

Muscarinic modulation of calcium current in neurones from the interatrial septum of bull-frog heart

1. The effects of activation of muscarinic receptors on the voltage-dependent calcium current, ICa, in parasympathetic neurones were examined. 2. Neurones were enzymatically isolated from the interatrial septum of bull-frog (Rana catesbeiana) heart, and were maintained in short-term (1-6 day) tissue culture. ICa was recorded from the cells using whole-cell patch-clamp methods (Clark, Tse & Giles, 1990). 3. External application of 2 nM to 10 microM acetylcholine (ACh) reduced the amplitude and slowed the time course of activation of ICa. These effects were dependent on membrane potential; they were most pronounced at potentials near the peak of the current-voltage relation for ICa (i.e. +10 to +15 mV), whereas at more-negative potentials (i.e. -15 to -25 mV) the effects on both amplitude and time course were relatively small. 4. Atropine (1 microM) completely blocked the action of 1 microM-ACh, indicating that the effects of ACh on ICa were mediated by activation of muscarinic receptors. 5. Other muscarinic agonists, such as carbamylcholine (0.1-10 microM), DL-muscarine (0.1-2.5 microM) and oxotremorine (5 microM), had similar effects on ICa to ACh. 6. A guanine nucleotide-binding protein (G-protein) is involved in this muscarinic inhibition of ICa. Inclusion of the non-hydrolysable guanosine triphosphate analogue guanosine 5'-O-(3-thiotriphosphate) (GTP-gamma-S; 200 microM) in the intracellular solutions mimicked the effects of ACh, and application of external ACh in the presence of internal GTP-gamma-S produced smaller changes in ICa than in control conditions. Inclusion of another non-hydrolysable analogue, guanosine 5'-O-(2-thiodiphosphate) (GDP-beta-S; 0.5-5 mM), blocked the inhibitory effect of ACh on ICa. 7. The G-protein involved in the inhibition of ICa was sensitive to pertussis toxin (islet-activating protein; IAP). The inhibition of ICa by carbamylcholine (5 microM) was reduced by about 90% after incubating cells for 12-15 h in culture medium containing 200 ng/ml IAP. 8. The possible roles of cyclic AMP or cyclic GMP-dependent protein kinases, or protein kinase C, in the muscarinic inhibition of ICa were tested, but these enzymes appear not to be directly involved.