HERG-Like potassium current regulates the resting membrane potential in glomus cells of the rabbit carotid body

Direct evidence for a specific K(+) channel underlying the resting membrane potential in glomus cells of the carotid body has been absent. The product of the human ether-a-go-go-related gene (HERG) produces inward rectifier currents that are known to contribute to the resting membrane potential in other neuronal cells. The goal of the present study was to determine whether carotid body glomus cells express HERG-like K(+) current, and if so, to determine whether a HERG-like current regulates the resting membrane potential. Freshly dissociated rabbit glomus cells under whole cell voltage clamp exhibited slowly decaying outward currents that activated 20-30 mV positive to the resting membrane potential. Raising extracellular K(+) revealed a slowly deactivating inward tail current indicative of HERG-like K(+) current. HERG-like currents were not found in cells resembling type II cells. The HERG-like current was blocked by dofetilide (DOF) in a concentration-dependent manner (IC(50) = 13 +/- 4 nM, mean +/- SE) and high concentrations of Ba(2+) (1 and 10 mM). The biophysical and pharmacological characteristics of this inward tail current suggest that it is conducted by a HERG-like channel. The steady-state activation properties of the HERG-like current (V(h) = -44 +/- 2 mV) suggest that it is active at the resting membrane potential in glomus cells. In whole cell, current-clamped glomus cells (average resting membrane potential, - 48 +/- 4 mV), DOF, but not tetraethylammonium, caused a significant (13 mV) depolarizing shift in the resting membrane potential. Using fluorescence imaging, DOF increased [Ca(2+)](i) in isolated glomus cells. In an in-vitro carotid body preparation, DOF increased basal sensory discharge in the carotid sinus nerve in a concentration-dependent manner. These results demonstrate that glomus cells express a HERG-like current that is active at, and responsible for controlling the resting membrane potential.     

Ionic currents in retrogradely labeled trigeminothalamic neurons in slices of rat medulla

We have recorded the ionic currents of identified trigeminothalamic neurons in medulla slices in vitro. Trigeminothalamic cells were first retrogradely labeled by injecting fluorescent latex microspheres in the thalamus of a 7- to 10-day-old rat. Two days later, thin slices (80-100 microns) were prepared from the lower medulla of the injected rat. Whole cell recordings were performed on the labeled cells located in the spinal trigeminal nucleus caudalis using the patch clamp technique. The voltage dependent inward sodium, inward calcium and outward potassium currents are qualitatively similar to those obtained from the enzymatically dissociated trigeminothalamic neurons. Successful application of this thin slice method opens the opportunity of studying synaptic circuitry in the trigeminothalamic system.     

Two types of spontaneous depolarizations in the interstitial cells freshly prepared from the murine small intestine

To explore the electrophysiological properties of the interstitial cells of Cajal (ICCs) and fibroblast-like cells (FLCs), we developed a new preparation by treating the murine small intestine with collagenase. This thin muscle layer preparation contained at least two types of interstitial cells around the enteric nerve bundles, and the cluster of smooth muscle cells displayed a rhythmic contraction. We morphologically identified ICCs and FLCs and conducted patch clamp experiments on each type of cell. The c-kit-positive CD34-negative ICCs showed spontaneous and rhythmic potential fluctuations, and a large transient inward current was evoked by depolarization under voltage clamp conditions. Once the inward current was triggered, it took a regenerative time course and lasted approximately 500 ms. The current was inactivated by continuous depolarization, and by removal of external Ca²⁺. The application of acetylcholine (ACh) prolonged the duration of spontaneous depolarization as well as the depolarization-induced inward current. This inward current showed a reversal potential of around +3 mV and was considered to be due to non-selective cation channels. The c-kit-negative CD34-positive FLCs showed irregular or regular potential fluctuations, and spontaneous outward current was observed under voltage clamp conditions. This outward current showed a reversal potential of around −80 mV and might be classified as a potassium current. We failed to observe major time- and voltage-dependent currents except the above two currents in the interstitial cells.     

Chick spinal accessory lobes contain functional neurons expressing voltagegated sodium channels generating action potentials

Ten pairs of protrusions, called accessory lobes (ALs), exist at the lateral sides of avian lumbosacral spinal cords. Histological evidence has shown that neurons are present in AL and behavioral evidence suggests that AL acts as a sensory organ of equilibrium during bipedal walking. However, there is little functional evidence to indicate that cells in AL have neuronal functions. To elucidate this point, we developed a method to dissociate cells from chick AL and made electrophysiological recordings with the whole-cell patch clamp technique. Cells dissociated by enzymatic digestion from chick AL contained two major types of cells. One was round with clear cytosol and the other had a round cell body, rich cytosolic structures and some processes. Rapidly activating inward currents and slowly activating outward currents were recorded in response to depolarizing pulses to -10 mV under the voltage clamp configuration only from the latter type of cells. TTX at 100 nM inhibited the inward current by 85%, indicating the functional expression of TTX-sensitive voltage-gated Na(+) channel (VGSC). Activation and inactivation kinetics of the inward currents in AL cells were similar to those of mammalian VGSC. The VGSC-expressing AL cells generated action potentials in response to depolarization under the current clamp configuration. These results clearly indicate that functional neurons expressing fast inactivating and TTXsensitive VGSC which generate action potentials exist in the AL of the chick. These lines of cellular evidence clearly indicate that functional neurons exist in ALs and further support the proposal that the chick ALs function as the sensory organ of equilibrium.     

Heterogeneous composition of voltage-dependent K(+) currents in hepatic stellate cells

PURPOSE: Hepatic stellate cells (HSC) are a type of pericyte with varying characteristics according to their location. However, the electrophysiological properties of HSC are not completely understood. Therefore, this study investigated the difference in the voltage-dependent K(+) currents in HSC. MATERIALS AND METHODS: The voltage-dependent K(+) currents in rat HSC were evaluated using the whole cell configuration of the patch-clamp technique. RESULTS: Four different types of voltage-dependent K(+) currents in HSC were identified based on the outward and inward K(+) currents. Type D had the dominant delayed rectifier K(+) current, and type A had the dominant transient outward K(+) current. Type I had an inwardly rectifying K(+) current, whereas the non-type I did not. TEA (5 mM) and 4-AP (2 mM) suppressed the outward K(+) currents differentially in type D and A. Changing the holding potential from -80 to -40 mV reduced the amplitude of the transient outward K(+) currents in type A. The inwardly rectifying K(+) currents either declined markedly or were sustained in type I during the hyperpolarizing step pulses from -120 to -150 mV. CONCLUSION: There are four different configurations of voltage-dependent K(+) currents expressed in cultured HSC. These results are expected to provide information that will help determine the properties of the K(+) currents in HSC as well as the different type HSC populations.     

Regional analysis of whole cell currents from hair cells of the turtle posterior crista

The turtle posterior crista is made up of two hemicristae, each consisting of a central zone containing type I and type II hair cells and a surrounding peripheral zone containing only type II hair cells and extending from the planum semilunatum to the nonsensory torus. Afferents from various regions of a hemicrista differ in their discharge properties. To see if afferent diversity is related to the basolateral currents of the hair cells innervated, we selectively harvested type I and II hair cells from the central zone and type II hair cells from two parts of the peripheral zone, one near the planum and the other near the torus. Voltage-dependent currents were studied with the whole cell, ruptured-patch method and characterized in voltage-clamp mode. We found regional differences in both outwardly and inwardly rectifying voltage-sensitive currents. As in birds and mammals, type I hair cells have a distinctive outwardly rectifying current (I(K,L)), which begins activating at more hyperpolarized voltages than do the outward currents of type II hair cells. Activation of I(K,L) is slow and sigmoidal. Maximal outward conductances are large. Outward currents in type II cells vary in their activation kinetics. Cells with fast kinetics are associated with small conductances and with partial inactivation during 200-ms depolarizing voltage steps. Almost all type II cells in the peripheral zone and many in the central zone have fast kinetics. Some type II cells in the central zone have large outward currents with slow kinetics and little inactivation. Although these currents resemble I(K,L), they can be distinguished from the latter both electrophysiologically and pharmacologically. There are two varieties of inwardly rectifying currents in type II hair cells: activation of I(K1) is rapid and monoexponential, whereas that of I(h) is slow and sigmoidal. Many type II cells either have both inward currents or only have I(K1); very few cells only have I(h). Inward currents are less conspicuous in type I cells. Type II cells near the torus have smaller outwardly rectifying currents and larger inwardly rectifying currents than those near the planum, but the differences are too small to account for variations in discharge properties of bouton afferents innervating the two regions of the peripheral zone. The large outward conductances seen in central cells, by lowering impedances, may contribute to the low rotational gains of some central-zone afferents.     

A comparative electrophysiological study of enzymatically isolated single cells and strips of frog ventricle

Single heart cells were obtained from frog ventricle using an enzymatic dispersion technique. The whole cell variation of the patch clamp technique was used to monitor action potential and cell membrane currents. The clamp circuit could be switched electronically between voltage and current clamp modes. The effects of seal leakage currents were to depolarize the cell, reduce the amplitude of the plateau, and lengthen the action potential duration. A scheme to compensate for these currents is presented. The membrane currents obtained from the single cell under voltage clamp conditions were compared to those obtained from multicellular preparations using the single sucrose gap technique. Hyperpolarizing clamps showed time-dependent, depletion-related K+ currents for the multicellular preparation, whereas for the single cell no such currents were observed. The absence of extracellular accumulation or depletion of K+ in the single cell was confirmed by the lack of post-clamp afterpotentials or changes in resting potential following a train of frequently elicited action potentials. The TTX-insensitive inward current was relatively faster in the single cell, compared to that measured in the multicellular preparation. A delayed time-dependent outward current was observed in the positive potential range for both single and multicellular preparations. The isochronal current-voltage (I-V) relations obtained at 400 ms were N-shaped for both preparations, but was more negative for the single cell at potentials positive to -20 mV. The results indicate a strong similarity between membrane currents obtained in single and multicellular preparations. The differences in the currents in the two preparations are due in large part to accumulation or depletion of K+ in the extracellular space.     

Ionic currents in crustacean neurosecretory cells.

1. The patterns of electrical activity and membrane characteristics of a population of neurosecretory-cell somata in the X-organ of the crayfish were investigated with microelectrodes and whole-cell, voltage-clamp techniques. Some neurons (56%) were silent but could be excited by intracellular current injection: other cells showed spontaneous tonic activity (35%), and some had spontaneous bursting activity (9%). The spiking activity was abolished by tetrodotoxin (TTX) exposure and by severing the axon near the cell body. After axotomy, only a small, slow, regenerative depolarization remained that could be blocked by Cd2+. 2. Under voltage clamp the steady-state I-V curve in low [Ca2+]i (9 X 10(-9) M) showed a slope conductance of 16.7 +/- 3.9 (SD) nS (n = 10) at -50 mV and zero current potential of -50.1 +/- 7.7 mV. In current-clamp mode these neurons were either silent or fired tonically. With high [Ca2+]i (1.7 X 10(-6) M) both the slope conductance and inward and outward currents were reduced. In some neurons high [Ca2+]i reveals a negative slope resistance in the range of -46 to -41 mV. It could be supressed by removing [Na+]o, but it was TTX insensitive. These are the neurons that under current clamp showed bursting activity. 3. The main inward current in cell somata was a Ca2+ current of 2 +/- 0.6 nA (n = 18), activated at -40 mV and peaking at 20 mV. It showed relaxation with prolonged pulses. No Na(+)-dependent, TTX-sensitive inward currents were recorded with short (100-ms) pulses in axotomized neurons. 4. Two outward currents could be distinguished.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ion channel regulation of the dynamical instability of the resting membrane potential in saccular hair cells of the green frog (Rana esculenta)

AIMS: We investigated the ion channel regulation of the resting membrane potential of hair cells with the aim to determine if the resting membrane potential is poised close to instability and thereby a potential cause of the spontaneous afferent spike activity. METHODS: The ionic mechanism and the dynamic properties of the resting membrane potential were examined with the whole-cell patch clamp technique in dissociated saccular hair cells and in a mathematical model including all identified ion channels. RESULTS: In hair cells showing I/V curves with a low membrane conductance flanked by large inward and outward rectifying potassium conductances, the inward rectifier (K(IR)), the delayed outward rectifier (K(V)) and the large conductance, calcium-sensitive, voltage-gated potassium channel (BK(Ca)) were all activated at rest. Under current clamp conditions, the outward current through these channels balanced the inward current through mechano-electrical transduction (MET) and Ca2+ channels. In 45% (22/49) of the cells, the membrane potential fluctuated spontaneously between two voltage levels determined by the voltage extent of the low membrane conductance range. These fluctuations were not influenced by blocking the MET channels but could be reversibly stopped by increasing [K+]o or by blocking of K(IR) channels. Blocking the BK(Ca) channels induced regular voltage oscillations. CONCLUSIONS: Two intrinsic dynamical instabilities of V(m) are present in hair cells. One of these is observed as spontaneous voltage fluctuations by currents through K(IR), K(V) and h-channels in combination with a steady current through MET channels. The other instability shows as regenerative voltage changes involving Ca2+ and K(V) channels. The BK(Ca) channels prevent the spontaneous voltage fluctuations from activating the regenerative system.     

Non-typical K+-current in cesium-loaded guinea pig type I vestibular hair cell

Isolated guinea pig type I vestibular hair cells were voltage clamped at HP-110 mV in whole cell clamp configuration and depolarized up to +20 mV. Increasing depolarizations elicited large outward currents. These currents were replaced, in cesium-loaded cells, by inward/outward currents that reversed at membrane potentials between –55 and –30 mV. The reversal potential varied from cell to cell, and appeared to depend on the intracellular potassium cesium ratio. The current remaining in the presence of intracellular cesium was essentially due to a non-typical potassium conductance, which decreased in the presence of 4-AP and was blocked by 4-AP plus TEA. This current appeared as soon as the membrane was depolarized, showing the high potassium permeability of type I vestibular hair cells. A small part of this current was a strictly calcium inward current, sensitive to flunarizine, with a leakage component in the hyperpolarized state and a voltage component when the cell was depolarized.     

Calcium-dependent chloride current induced by axotomy in rat sympathetic neurons.

1. Seven to ten days after sectioning their axons, rat sympathetic neurons were studied using intracellular recording techniques in an in vitro preparation of the superior cervical ganglion. 2. In 75% of axotomized cells, an after-depolarization (ADP) was observed following spike firing or depolarization with intracellular current pulses. Discontinuous single-electrode voltage-clamp techniques were employed to study the ADP. When the membrane potential was clamped at the resting level just after an action potential, a slow inward current was recorded in cells that showed an ADP. 3. In the presence of TTX and TEA, inward peaks and outward currents were recorded during depolarizing voltage jumps, followed by slowly decaying inward tail currents accompanied by large increases in membrane conductance. The inward peak and tail currents activated between -10 and -20 mV and reached maximum amplitudes around 0 mV. With depolarizing jumps to between +40 and +50 mV, net outward currents were recorded during the depolarizing jumps but inward tail currents were still activated. 4. In the presence of the Ca2+ channel blocker cadmium, or when Ca2+ was substituted by Mg2+, the ADP disappeared. In voltage-clamped cells, cadmium blocked the inward tail currents. The reversal potential for the inward tail current was approximately -15 mV. Substitution of the extracellular NaCl by sucrose or sodium isethionate increased the amplitude of the inward tail current, and displaced its equilibrium potential to more positive values. Changes in extracellular [K+] did not appreciably affect the inward tail current amplitude or equilibrium potential. Niflumic acid, a blocker of chloride channels activated by Ca2+, almost completely blocked the tail current. 5. No ADPs were observed in non-axotomized neurons, and when depolarizing pulses were applied while in voltage clamp no inward tail currents were evoked in these normal cells. 6. It is concluded that axotomy of sympathetic ganglion cells produces the appearance of a Ca(2+)-dependent chloride current responsible for the ADP observed following spike firing.     

Identification and dissociation of cardiovascular neurons from the medulla for patch clamp analysis.

This study describes a preparation that will enable us to study, using voltage clamp techniques, ionic currents from dissociated cardiovascular neurons that have retained their anatomical and functional identity of the intact animal. To identify dispersed preganglionic cardiac motoneurons various fluorescent dyes (rhodamine, fluorogold, microspheres, bizbenzimide and dextrans) were examined to determine which can be absorbed by preganglionic cardiac motorneuron nerve terminals (without surgical penetration of cardiac tissue), transported retrogradely to their soma in the medulla and retained during dissociation of the neurons. Rhodamine fulfilled these criteria. Dissociated preganglionic cardiac motorneurons had resting membrane potentials of -52.4 +/- 3 mV and input resistances of 236 +/- 71 M omega (mean +/- S.E.M., n = 10). Depolarizing voltage steps to -50 mV or above evoked a tetrodotoxin (TTX) sensitive inward sodium current followed by a biphasic outward current.     

Patch clamp study of mouse glomus cells using a whole carotid body

Some electrophysiological characteristics of mouse glomus cells (DBA/2J strain) were investigated using an undissociated carotid body. The carotid body with major carotid arteries was placed in a recording chamber, and glomus cells were visualized with a water immersion lens combined with an infrared differential interference video camera. Patch clamp experiments revealed that voltage-gated outward current, but not inward current, was easily observed in glomus cells. Pharmacological experiments and the kinetics of the current suggest that outward current is via delayed rectifier, A type, and large conductance calcium-activated K channels. Furthermore, K current was reversibly attenuated by mild hypoxia. The results suggest electrophysiological similarities of glomus cells among the cat, the rat, and the DBA/2J mouse. The method appears useful for physiological experiments.     

Some limitations of the double sucrose gap, and its use in a study of the slow outward current in mammalian ventricular muscle. With an Appendix

1. A double sucrose gap method to clamp small bundles (diameter 0.8-1.2 mm) of sheep or calf ventricular fibres is described.2. Comparison between micro-electrode recordings from the central gap and the externally recorded potentials showed good agreement between the time course and amplitude of the action potentials. The rapid sodium inward current was not controlled on depolarizing clamp steps. On repolarization, control was obtained within 20 msec. The method is regarded as only suitable for a study of slow currents.3. During clamps of several seconds duration slow changes in outward current can be demonstrated. The potential, where the instantaneous current-voltage relationship crosses the voltage axis, shifted in a positive direction as the clamp duration was increased (clamp amplitude constant), and did not alter much if the clamp amplitude was increased while the duration remained constant. For these reasons it is concluded that K ions accumulate round the cells.4. A comparison between the instantaneous current-voltage relationship in various K solutions and after a depolarizing clamp, showed that an increase in external K could not exactly mimic the changes during a clamp. Because of this, a conductance change, unrelated to accumulation, is also postulated.5. To measure the influence of the slowly increasing outward current during an action potential, slowly increasing inward current (to reduce net outward current) was applied during an action potential and the prolongation of the action potential measured. In the same experiment the increase in outward current during a clamp in a solution with tetrodotoxin and Mn was measured. From these experiments it is concluded that the slow increase in outward current does not contribute much to repolarization in sheep or calf.6. Equations are derived for the voltage distribution and leakage current in the double sucrose gap. From the equations it is possible to calculate an optimal gap width. Too small a gap causes the membrane current to be swamped by the leakage current. Too wide a gap gives unequal potential distribution.     

Anoxia on slow inward currents of immature hippocampal neurons

1. The effects of brief anoxia (2-4 min) on membrane currents--especially the tetrodotoxin (TTX)-insensitive, Cd2+-sensitive slow inward currents, presumed to be Ca2+ currents--were studied by single-electrode voltage clamp in CA1 and CA3 neurons in submerged hippocampal slices from adult and newborn Wistar rats (PN1-13). 2. In mature neurons, anoxia had no effect on Q-type inward relaxations, but slowly activating C-type outward currents were depressed. The most striking change was the suppression of Ca inward currents (especially the slowly inactivating L-type, by greater than 95%). This effect of anoxia was not sensitive to the N-methyl-D-aspartate (NMDA) receptor blocker, D-aminophosphonovalerate. Anoxia also reversibly abolished the NMDA-evoked inward current. 3. In neurons from newborn animals (PN1-6), Q-type inward relaxations and postanoxic outward currents were very small or undetectable. The slow inward (Ca) currents were smaller than in mature cells, but they showed a clearer separation between low-threshold, fast-inactivating and high-threshold, slowly inactivating currents. Both types of current were more resistant to anoxia (mean depression of L-type was by only 53.3 +/- 5.6%, mean +/- SE). 4. In such immature neurons, the NMDA-evoked inward currents were also more resistant to anoxia. 5. By PN7-13, increasing maturation was reflected in 1) larger voltage-dependent inward currents, 2) increasingly evident Q-type relaxations and postanoxic outward currents, and 3) near-complete blockade of inward currents by anoxia (at PN11-13, mean depression of L-type currents was by 98.5 +/- 1.5%).     

Permeability characteristics of monovalent cations in atrial myocytes of the rat heart

We investigated the permeability of Cs+ and Na+ through various ion channels in rat atrial myocytes using the whole-cell voltage-clamp technique. With isotonic CsCl (140 mM) on both sides of the membrane and nominally [Ca2+]o-free conditions, depolarising clamp pulses induced an increase of outward currents which showed a biphasic time course. Repolarisation to the holding potential induced inward tail currents. With isotonic NaCl, depolarisation also induced outward currents which showed a monotonic decay, but inward tail currents were not observed. Both in NaCl and CsCl, currents were hardly affected by TEA (10 mM), 4-AP (5 mM) and DIDS (100 microM). Nicardipine (1 M) almost completely blocked time-dependent outward currents in isotonic NaCl solution, leaving only time-independent currents which showed linear I-V relationship. In isotonic CsCl conditions, nicardipine blocked outward current considerably, but there still remained time-dependent outward currents and inward tail currents. Addition of E-4031 (2-20 M) which is known as a specific blocker of the rapidly activating delayed rectifier K+ current (IKr) completely blocked these time-dependent outward and inward currents, leaving only a time-independent current. Time-independent currents recorded in the presence of nicardipine and E-4031 were inhibited by GdCl3, which is known to block non-selective cation (NSC) currents. From these results, it was suggested that NSC current in atrial myocytes can be investigated in isotonic Cs+ or Na+ solution in the presence of Ca2+ channel and IKr blockers.     

Diverse ionic currents and electrical activity of cultured myenteric neurons from the guinea pig proximal colon

The aim of this study was to perform a patch-clamp analysis of myenteric neurons from the guinea pig proximal colon. Neurons were enzymatically dispersed, cultured for 2-7 days, and recorded from using whole cell patch clamp. The majority of cells fired phasically, whereas about one-quarter of the neurons fired in a tonic manner. Neurons were divided into three types based on the currents activated. The majority of tonically firing neurons lacked an A-type current, but generated a large fast transient outward current that was associated with the rapid repolarizing phase of an action potential. The fast transient outward current was dependent on calcium entry and was blocked by tetraethylammonium. Cells that expressed both an A-type current and a fast transient outward current were mostly phasic. Depolarization of these cells to suprathreshold potentials from less than -60 mV failed to trigger action potentials, or action potentials were only triggered after a delay of >50 ms. However, depolarizations from more positive potentials triggered action potentials with minimal latency. Neurons that expressed neither the A-type current or the fast transient outward current were all phasic. Sixteen percent of neurons were similar to AH/type II neurons in that they generated a prolonged afterhyperpolarization following an action potential. The current underlying the prolonged afterhyperpolarization showed weak inward rectification and had a reversal potential near the potassium equilibrium potential. Thus cultured isolated myenteric neurons of the guinea pig proximal colon retain many of the diverse properties of intact neurons. This preparation is suitable for further biophysical and molecular characterization of channels expressed in colonic myenteric neurons.     

Modulation by cGMP of the voltage-gated currents in newt olfactory receptor cells

Effects of cGMP on voltage-gated currents in the somatic membrane of isolated newt olfactory receptor cells were investigated using the whole-cell mode of the patch-clamp technique. Under voltage clamp, membrane depolarization generated time- and voltage-dependent current responses, a transient inward current and a sustained outward current. When cGMP or a membrane permeant analog of cGMP, 8-p-chlorophenylthio-cGMP (CPT-cGMP), was applied to the recorded cell, the amplitude of the transient inward current increased markedly, but that of the sustained outward current did not change significantly. When each current was isolated by pharmacological agents, 0.1 mM CPT-cGMP increased the peak amplitude of a Na(+) current (I(Na)) by approximately 40%, a T-type Ca(2+) current (I(Ca,T)) by approximately 40%, and an L-type Ca(2+)current (I(Ca,L)) by approximately 10%; however it did not change significantly the amplitude of a delayed rectifier K(+) current (I(K)). A selective cGMP-dependent protein kinase inhibitor, KT5823, blocked the enhancement by cGMP of I(Na) and I(Ca,T), suggesting that cGMP increases these currents via cGMP-dependent phosphorylation. Under current-clamp conditions, application of CPT-cGMP lowered the current threshold of action potentials induced by current injection, and increased the maximum spike frequency in response to strong stimuli. We suggest that cGMP may lower the threshold in olfactory perception by decreasing the current threshold to generate spikes, and also prevent the saturation of odor signals by increasing the maximum spike frequency.     

Membrane currents underlying activity in frog sinus venosus.

1. The spontaneous electrical activity of small strips of muscle from the sinus venosus region of the heart of Rana catesbeiana was investigated using the double sucrose gap technique. The voltage clamp was used to record the ionic currents underlying the pace-maker depolarization and the action potential.2. The records of spontaneous electrical activity are very similar to those obtained from the sinus venosus using micro-electrodes. Moreover, the pace-maker activity is almost completely insensitive to tetrodotoxin (TTX) at 2.0 x 10(-6) g/ml., which suggests that the pace-maker responses can be classified as primary, as opposed to follower pacing.3. In response to short rectangular depolarizing voltage clamp pulses, only one inward current is activated. This current is almost completely insensitive to TTX but can be blocked by manganese ions. It appears, therefore, to be equivalent to the slow inward (Ca(2+)/Na(+)) current, I(si), of other cardiac tissues. The threshold for I(si) is near to the maximum diastolic potential, indicating that it must be activated during the pace-maker depolarization.4. Interruption of the normal pace-maker depolarization by rapid activation of the voltage clamp circuit reveals the time-dependent decay of outward current. This current reverses between -75 and -90 mV and, therefore, is probably carried mainly by potassium ions.5. Outward current decay is not a simple exponential, and Hodgkin-Huxley analysis suggests that two distinct components of outward current may be present. One of these is activated in the potential range of the pace-maker depolarization and the other at more positive potentials. Both outward currents reach full, steady-state activation at about zero mV, i.e. within the ;plateau' range of the sinus action potential.6. These results are compared with other recently published voltage clamp data from the rabbit sino-atrial node.7. A hypothesis for the generation of pace-maker activity is presented which involves (i) decay of outward current and (ii) activation of the slow inward current, I(si).     

Membrane currents of cultured rat sympathetic neurons under voltage clamp

Sympathetic neurons, dissociated from neonatal rat superior cervical ganglia, were voltage clamped with two microelectrodes. Depolarization from resting potential activated a rapid transient inward current carried by sodium and a slow inward current blocked by cobalt. Depolarization from resting potential also activated up to three kinetically distinct outward currents, which were further studied by tail current analysis. Following long depolarizing steps, outward current decayed biphasically. The fast phase (delayed rectifier) decayed over 10-20 ms. The slow phase (calcium dependent) required as much as 1-2 s to decay to base line. A small component of the total outward current was a persistent current activated between -70 and -30 mV (M-current), which decayed over 200-300 ms. This current was studied in isolation following hyperpolarizing steps from potentials negative to the threshold for activation of the other delayed outward currents. Tetraethylammonium (TEA) blocked the fast tail current, partially inhibited the slow tail current, and reduced M-currents. Cobalt selectively decreased the slow tail current. Muscarine blocked M-current but not other outward currents. A transient outward current was activated by depolarization from only holding potentials negative to -60 mV. This current peaked in 10-20 ms and decayed over about 50 ms. A persistent ("anomalous") inward current was evoked by hyperpolarizing steps from only holding potentials negative to -50 to -60 mV. These seven membrane currents may be separately characterized on the basis of their voltage- and time-dependent properties. Further identification is aided by the use of channel-blocking chemicals, although the latter may lack specificity, especially when used to study potassium channels.