Characterization of the neurons of the mouse hypogastric ganglion: morphology and electrophysiology

The somata of mouse hypogastric ganglion cells injected with Lucifer yellow were ovoid in shape, lacked dendritic processes but gave rise to a single axonal process. Antidromic activation demonstrated that some of the cells contained in this ganglion innervated the vas deferens. The passive and active membrane properties of the ganglion cells were determined in current clamp experiments. Cells fired tetrodotoxin-sensitive action potentials in response to intracellularly-applied depolarizing current. In voltage clamp evidence was obtained for both a persistent inward calcium current at potentials between -30 and -40 mV and a transient calcium current evoked by step depolarizations to around -20 mV. In current clamp, however, cells did not fire calcium action potentials in the presence of tetrodotoxin. Three potassium currents, IM (blocked by 1 mM barium and by 30 microM bethanechol), IA (blocked by 2 mM 4-aminopyridine) and IK(Ca) fast (blocked by 100 microM cadmium and by 5 mM tetraethylammonium) were characterized in these neurons. In addition, IK(Ca) slow was observed in a small proportion of cells. Fast, all-or-nothing, excitatory synaptic potentials were recorded in response to single stimuli applied to the afferent fibres running to the ganglion. In most cells the excitatory synaptic potentials were suprathreshold for action potential initiation and were markedly reduced or abolished by 100 microM mecamylamine, 1 mM hexamethonium and following desensitization to 100 microM nicotine. Excitatory synaptic potentials arose from stimulation of a single presynaptic nerve process and are typical of strong synaptic inputs.     

Transplanting the N-terminus from Kv1.4 to Kv1.1 generates an inwardly rectifying K+ channel

A chimeric channel, 4N/1, was generated from two outwardly rectifying K+ channels by linking the N-terminal cytoplasmic domain of hKv1.4 (N terminus ball and chain of hKv1.4) with the transmembrane body of hKv1.1 (delta78N1 construct of hKv1.1). The recombinant channel has properties similar to the six transmembrane inward rectifiers and opens on hyperpolarization with a threshold of activation at -90 mV. Outward currents are seen on depolarization provided the channel is first exposed to a hyperpolarizing pulse of -100 mV or more. Hyperpolarization at and beyond -130 mV provides evidence of channel deactivation. Delta78N1 does not show inward currents on hyperpolarization but does open on depolarizing from -80 mV with characteristics similar to native hKv1.1. The outward currents seen in both delta78N1 and 4N/1 inactivate slowly at rates consistent with C-type inactivation. The inward rectification of the 4N/1 chimera is consistent with the inactivation gating mechanism. This implies that the addition of the N-terminus from hKv1.4 to hKv1.1 shifts channel activation to hyperpolarizing potentials. These results suggest a mechanism involving the N-terminal cytoplasmic domain for conversion of outward rectifiers to inward rectifiers.     

Voltage-gated currents in identified rat olfactory receptor neurons

Whole-cell recording techniques were used to characterize voltage-gated membrane currents in neonatal rat olfactory receptor neurons (ORNs) in cell culture. Mature ORNs were identified in culture by their characteristic bipolar morphology, by retrograde labeling techniques, and by olfactory marker protein (OMP) immunoreactivity. ORNs did not have spontaneous activity, but fired action potentials to depolarizing current pulses. Action potentials were blocked by tetrodotoxin (TTX), which contrasts with the TTX-resistant action potentials in salamander olfactory receptor cells (e.g., Firestein and Werblin, 1987). Prolonged, suprathreshold current pulses evoked only a single action potential; however, repetitive firing up to 35 Hz could be elicited by a series of brief depolarizing pulses. Under voltage clamp, the TTX-sensitive sodium current had activation and inactivation properties similar to other excitable cells. In TTX and 20 mM barium, sustained inward current were evoked by voltage steps positive to -30 mV. This current was blocked by Cd (100 microM) and by nifedipine (IC50 = 368 nM) consistent with L-type calcium channels in other neurons. No T-type calcium current was observed. Voltage steps positive to -20 mV also evoked an outward current that did not inactivate during 100-msec depolarizations. Tail current analysis of this current was consistent with a selective potassium conductance. The outward current was blocked by external tetraethylammonium but was unaffected by Cd or 4-aminopyridine (4-AP) or by removal of external calcium. A transient outward current was not observed. The 3 voltage-dependent conductances in cultured rat ORNs appear to be sufficient for 2 essential functions: action potential generation and transmitter release. As a single odorant-activated channel can trigger an action potential (e.g., Lynch and Barry, 1989), the repetitive firing seen with brief depolarizing pulses suggests that ORNs do not integrate sensory input, but rather act as high-fidelity relays such that each opening of an odorant-activated channel reaches the olfactory bulb glomeruli as an action potential.     

Maitotoxin-induced membrane current in neuroblastoma cells

Maitotoxin (MTX) is a potent marine toxin isolated from the toxic dinoflagellate, Gambierdiscus toxicus. We have examined the possibility of MTX activating calcium channels using cultured neuroblastoma cells (N1E-115). MTX (10 ng/ml) produced a depolarization of the membrane, which was prevented by the removal of Ca2+ from the external medium. Under voltage clamp conditions, membrane currents were recorded with 50 mM Ba2+ as a charge carrier through calcium channels. After application of MTX (1 ng/ml), an inward current necessary to hold the membrane at -90 mV increased progressively. This was followed by a gradual decrease of the transient inward Ba2+ current through type I calcium channels recorded at -30 mV which was eventually abolished. A similar tendency was observed in the long-lasting inward Ba2+ current through type II calcium channels, which was recorded at +10 mV. The MTX action was antagonized by calcium channel blockers such as verapamil (100 microM) and La3+ (1 mM). A high concentration of verapamil (500 microM) blocked both types of calcium channels persistently. After washout of verapamil but while the calcium channels were still blocked, MTX (1 ng/ml) induced a steady-state current. The MTX-induced current showed an inward-rectifying property with a reversal potential of approximately -30 mV. The results suggest that the MTX-induced current does not flow through calcium channels. Thus, MTX may create a pore in the membrane with pharmacological properties similar to those of calcium channels.     

Membrane currents induced by pentylenetetrazol in identified neurons of Helix pomatia

After systemic application of pentylenetetrazol (PTZ), mammalian as well as molluscan neurons generate epileptic paroxysmal depolarization shifts. For a further analysis of these potential oscillations the membrane currents induced by local application of PTZ onto identified neurons of Helix pomatia were investigated. Different types of responses were obtained at membrane potentials negative and positive to ca. -30 mV. At holding potentials more negative than -30 mV, PTZ as a rule evoked an inward current, sometimes preceded by a brief outward current. In a few experiments only a solitary outward current was found. The amplitudes of the inward and outward currents increased towards more negative potentials. The inward current was associated with a decrease and the outward current with an increase in membrane resistance. Besides these findings pharmacological and ion substitution experiments indicate that the inward current represents an unspecific current. At holding potentials more positive than -30 mV, PTZ evoked a sequence of currents which was the same in all neurons. This stereotyped current sequence consisted of (i) an early inward current, (ii) an intermediate outward current, and (iii) a late long-lasting inward current. The amplitudes of all these components increased towards more positive potentials with the outward current being particularly enhanced. The early inward current and the following outward current were associated with a decrease and the late inward current with an increase of the membrane resistance. Besides these pharmacological and ion substitution experiments suggest that the early inward current represents a mixed sodium and calcium current, the intermediate outward current a calcium activated potassium current. The late inward current is assumed to be due to a decreased potassium conductance. On the basis of the present results, it may be concluded that the unspecific inward current in the negative potential range is involved in the initiation and the calcium dependent potassium current in the termination of spontaneously occurring paroxysmal depolarization shifts.     

Membrane currents in identified lactotrophs of rat anterior pituitary

Qualitative features of the primary inward and outward current components of identified lactotrophs of the rat anterior pituitary were examined. Identification of lactotrophs in heterogeneous dissociated anterior pituitary cultures was accomplished by application of the reverse hemolytic plaque assay. Currents in lactotrophs were subsequently examined using whole-cell or patch recording techniques. Two components of inward calcium current were observed: a transient component and a sustained component. The transient component activated at voltages as negative as -50 mV and was the major contributor to total lactotroph calcium current. The sustained component activated at voltages above about -10 mV. The 2 currents could be qualitatively separated by differences in inactivation properties and in sensitivity to cadmium. At least 3 components of outward current were distinguished. Either 30 mM TEA or 0 calcium eliminated a major portion of sustained outward current. This is likely to represent primarily calcium- and voltage-activated potassium current. The remaining current could be further differentiated into a transient current component that could be inactivated with conditioning potentials above -60 mV. A slowly activating and deactivating potassium current remained following inactivation of the transient current. Although the time course of the transient current is reminiscent of "A" current, activation of this current required potentials above -30 mV. Candidates for the single-channel currents that underlie the whole-cell outward currents were observed in cell-attached recordings. When combined with patch-clamp electrophysiological methods, the reverse hemolytic plaque assay promises to be a powerful technique for the electrophysiological characterization of specific cell subtypes in heterogeneous dissociated cell populations.     

Ionic currents on type-I cells of the rabbit carotid body measured by voltage-clamp experiments and the effect of hypoxia

Type-I cells (from rabbit embryos) in primary culture were studied in voltage-clamp experiments using the whole cell arrangement of the patch-clamp technique. With a pipette solution containing 130 mM K⁺ and 3 mM Mg-ATP, large outward currents were obtained positive to a threshold of about −30 mV by clamping cells from −50 mV to different test pulses (−80 to 50 mV). Negative to −30 mV, the slope conductance was low (outward rectification). The outward currents were blocked by external Cs⁺ (5 mM) and partially blocked by TEA (5 mM) and Co²⁺ (1 mM). The initial part of the outward currents during depolarizing voltage pulses exhibited a transient Ca²⁺ inward component partially superimposed to a Ca²⁺-dependent outward current. Inward currents were further characterized by replacing K⁺ with Cs⁺ in the intra- and extracellular solution in order to minimize the outward component and by using 1.8 mM Ca²⁺ or 10.8 mM Ba²⁺ as charge carrier. Slow-inactivating inward currents were recorded at test potentials ranging from −50 to 40 mV (holding potential −80 mV). The maximal amplitude, measured at 10 mV in the U-shaped I–V curve, amounted to 247 ± 103pA(n = 3). This inward current was insensitive to 3 μM TTX, but blocked by 1 mM Co²⁺ and partially reduced by 10 μM D600 and 3 μM PN 200-110. In contrast to outward currents, the inward currents exhibited a ‘run-down’ within about 10 min. Lowering the pO₂ from the control of 150 Torr (air-gassed medium) to 28 Torr had no apparent effect on inward currents, but depressed reversibly outward currents by 28%. In conclusion, it is suggested that type-I cells possess voltage-activated K⁺ and Ca²⁺ channels which might be essential for chemoreception in the carotid body.     

Responses to Metabotropic Glutamate Receptor Activation in Cerebellar Purkinje Cells: Induction of an Inward Current

The responses to activation of metabotropic glutamate receptors (mGluRs) of Purkinje cells in rat cerebellar slice cultures were investigated using intracellular recordings in single-electrode voltage-clamp mode combined with microfluorometric measurements of cytosolic free calcium using fura-2. Purkinje cells were perfused with saline containing 0.5 μM tetrodotoxin and 10 μM bicuculline and voltage-clamped at –60 mV. Bath-applied trans-(±)-1-amino-1,3-cyclopentanedicarboxylic acid ( t -ACPD, 50–100 μM), a selective agonist of mGluRs, induced a transient inward current that was followed by an outward current. The response induced by t -ACPD was not affected by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, up to 40 μM). In contrast, inward currents caused by (RS)-α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA, 1–2 μM) were completely abolished, while inward currents caused by quisqualate (0.25 μM) were only partially depressed by CNQX (5–40μM). The inward current induced by t -ACPD was unaffected by external Ba²⁺ (1 mM), tetraethylammonium (10 mM) and Cs⁺ (1 mM), and was associated with an increase in apparent input conductance of the cell membrane. The extrapolated reversal potential of inward currents induced by t -ACPD was +18 mV while Cl⁻ currents induced by muscimol reversed at –66 mV. Inward currents induced by t -ACPD, but not those induced by AMPA, were associated with a rise in cytosolic Ca²⁺ concentration and suppressed by intracellular injection of a calcium chelator. Replacement of external Na⁺ by choline or Li⁺ depressed the inward current and resulted in a slower decay of the Ca²⁺ signal.     

Calcium-dependent action potentials and associated inward currents in guinea-pig neocortical neurons in vitro

Calcium-dependent potential changes and inward currents were studied in guinea-pig neocortical neurons maintained in vitro. Under conditions of reduced outward potassium current, induced by external application of tetraethylammonium ions or internal application of caesium ions, regenerative Ca2+-dependent action potentials could be elicited. Strontium and barium ions could substitute for calcium as the charge carrier but not magnesium; cadmium blocked the calcium spikes. In caesium-loaded neurons, in the presence of tetrodotoxin and tetraethylammonium, inward currents were recorded when the membrane potential was step-depolarized to potentials more positive than -50 mV. These currents were blocked by cadmium. It is concluded that guinea-pig neocortical neurons are capable of generating a calcium action potential via the activation of a slow inward current.     

Cobalt-dependent potentiation of net inward current density in Helix aspersa neurons.

A low concentration of transition metal ions Co2+ and Ni2+ increases the inward current density in neurons from the land snail Helix aspersa. The currents were measured using a single electrode voltage-clamp/internal perfusion method under conditions in which the external Na+ was replaced by Tris+, the predominant external current carrying cation was Ca2+, and the internal perfusate contained 120 mM Cs+/0 K+; 30 mM tetraethylammonium (TEA) was added externally to block K+ current. In the presence of Co2+ (3 mM) or Ni2+ (0.5 mM) inward Ca2+ currents were stimulated normally by voltage-dependent activation of Ca2+ channels. There was a 5-10% decrease in the rate of rise of the inward current. The principal effect of Co2+ and Ni2+ in increasing the current density seems to be a decrease in the rate at which the inward currents decline during a depolarizing voltage pulse. The results may be due to a decrease in a voltage-dependent or Ca(2+)-dependent outward current and/or an inhibition of Ca2+ channel inactivation. Outward current under these conditions (zero internal K+) was significant and most likely due to Cs+ efflux through the voltage-activated or Ca(2+)-activated nonspecific cation channels. Co2+ is an extremely effective blocker of this outward current. These results are not an artifact of internal perfusion or the special ionic conditions. Intracellular recording of unperfused neurons in normal Helix Ringer's solution showed that the Ca(2+)-dependent action potential duration was increased significantly by low concentrations of Co2+. This result is consistant with the Co(2+)-dependent increase in inward (depolarizing) current seen in voltage-clamp experiments.     

Voltage- and ligand-activated inwardly rectifying currents in dorsal raphe neurons in vitro

Intracellular recordings were made from neurons in rat dorsal raphe in the slice preparation maintained at 37 degrees C. The single-electrode voltage-clamp method was used to measure membrane currents at potentials more negative than rest (-60 mV). Three types of inward rectification were observed: 2 in the absence of any drugs and the third induced by 5-HT 1 and GABA-B receptor agonists. In the absence of any drugs, an inward current activated over 1-2 sec when the membrane potential was stepped to potentials more negative than -70 mV. This current was blocked by cesium (2 mM) and resembles IQ or IH. A second inward current (IIR) occurred at membrane potentials near the potassium equilibrium potential (EK). This inward current activated within the settling time of the clamp and was abolished by both barium (10-100 microM) and cesium (2 mM). 5-HT 1 agonists activated a potassium conductance that hyperpolarized the cells at rest. This potassium conductance was about 2 nS at -60 mV and increased linearly with membrane hyperpolarization to about 4 nS at -120 mV. Baclofen activated a potassium conductance identical in amplitude and voltage dependence to that induced by 5-HT 1 agonists. Both the baclofen- and 5-HT-induced currents were nearly abolished in animals pretreated with pertussis toxin. The results indicate that a common potassium conductance is increased by 5-HT acting on 5-HT 1 receptors and baclofen acting on GABA-B receptors. This potassium conductance rectifies inwardly and is distinct from the Q-current. The ligand-activated potassium conductance also differs from the other form of inward rectification (IIR) in its voltage dependence and sensitivity to pertussis toxin.     

Phencyclidine blocks two potassium currents in spinal neurons in cell culture

We studied the effects of phencyclidine (PCP) on the transient and delayed outward K+ currents recorded from spinal cord neurons grown (10-20 days) in cell culture. Sodium channels were blocked with tetrodotoxin (1 microM) and solutions containing low calcium concentrations in the presence of Mg2+ or Co2+ (5 mM) were used to reduce Ca2+ currents. PCP decreased the amplitude and prolonged the decay phase of the action potentials recorded at a holding potential of -70 mV. PCP (0.1-0.5 mM) was more effective than tetraethylammonium (TEA) or 4-aminopyridine (4-AP) in reducing both transient and delayed currents. The amplitude of the transient current during control experiments was always larger than that of the delayed current. It appeared that 4-AP (5 mM) was more potent in blocking the transient current, while TEA (10 mM) modified the delayed current more effectively. Both currents were also reduced by about 10% when the cell soma was perfused with Co2+. This suggested that a small fraction of the total outward current is a Ca2+-activated K+ current. The PCP-induced blockade of K+ currents in central neurons coupled with the profound synaptic effects of the drug may provide the basis for explaining the psychopathology of this hallucinogenic agent.     

Voltage-gated ionic currents in an identified modulatory cell type controlling molluscan feeding

An important modulatory cell type, found in all molluscan feeding networks, was investigated using two-electrode voltage- and current-clamp methods. In the cerebral giant cells of Lymnaea, a transient inward Na+ current was identified with activation at -58 +/- 2 mV. It was sensitive to tetrodotoxin only in high concentrations (approximately 50% block at 100 microm), a characteristic of Na+ channels in many molluscan neurons. A much smaller low-threshold persistent Na+ current (activation at < -90 mV) was also identified. Two purely voltage-sensitive outward K+ currents were also found: (i) a transient A-current type which was activated at -59 +/- 4 mV and blocked by 4-aminopyridine; (ii) a sustained tetraethylammonium-sensitive delayed rectifier current which was activated at -47 +/- 2 mV. There was also evidence that a third, Ca2+-activated, K+ channel made a contribution to the total outward current. No inwardly rectifying currents were found. Two Ca2+ currents were characterized: (i) a transient low-voltage (-65 +/- 2 mV) activated T-type current, which was blocked in NiCl2 (2 mm) and was completely inactivated at approximately -50 mV; (ii) A sustained high voltage (-40 +/- 1 mV) activated current, which was blocked in CdCl2 (100 microm) but not in omega-conotoxin GVIA (10 microm), omega-agatoxin IVA (500 nm) or nifedipine (10 microm). This current was enhanced in Ba2+ saline. Current-clamp experiments revealed how these different current types could define the membrane potential and firing properties of the cerebral giant cells, which are important in shaping the wide-acting modulatory influence of this neuron on the rest of the feeding network.     

Voltage-gated Currents in Rabbit Retinal Astrocytes

The voltage-gated currents of the astrocytes associated with the retinal capillaries of the rabbit retina were studied using whole-cell patch clamp recording. The resting potential of these cells was −70 ± 4.8 mV (mean ± SEM; n = 54), and the input resistance and cell capacitance were 558 ± 3.6 MΩ and 19.5 ± 1.8 pF respectively. Depolarization to potentials positive to −50 mV evoked rapidly activating inward and outward currents. The inward current was transient, eliminated by substitution of choline for Na⁺ in the bathing solution, and reduced by 50% in the presence of 1 μM tetrodotoxin. The time-to-peak of the Na⁺ current was more than twice that for the Na⁺ current found in retinal neurons. The glial Na⁺ current was half-inactivated at −55 mV. A transient component of the outward K⁺ current was blocked by external 4-aminopyridine while a more sustained component was blocked by external tetraethylammonium. At potentials between −150 and −50 mV the membrane behaved Ohmically. Voltage-gated currents in retinal astrocytes recorded in situ appear qualitatively similar to those described for some glial cells in vitro.     

The effects of pumiliotoxin-B on sodium currents in guinea pig hippocampal neurons

The actions of pumiliotoxin-B, extracted from the skin of the frog Dendrobates pumilio, were examined on hippocampal slices and on acutely dissociated hippocampal neurons from the adult guinea pig. Application of 0.5-1 microM pumiliotoxin-B to hippocampal slices caused spontaneous, repetitive field discharges in the CA3 subfield. In whole-cell patch-clamp recordings of isolated CA1 and CA3 neurons, 1-2 microM pumiliotoxin-B shifted the midpoint of Na+ current activation by -11.4 +/- 1.1 mV. This shift was not dependent upon prior activation of the sodium channel. Pumiliotoxin-B did not block macroscopic Na+ inactivation but did reduce the apparent voltage-dependence of inactivation such that currents decayed faster at membrane potentials more negative than -30 mV. Single-channel recordings of sodium currents from excised membrane patches indicated that pumiliotoxin-B had little or no effect on channel closings due to entry into inactivated state(s) but did increase the rate of channel closings due to reversal of channel opening. The increase in the channel closing rate was consistent with a +8.7 mV shift in voltage sensitivity. Negative shifts in activation and positive shifts in closing rates implied a negative shift in the voltage-dependence of channel opening, suggesting that pumiliotoxin-B increases the rate of Na+ channel opening and closing in cells at rest, which could result in spontaneous activity in the neurons.     

Ion currents through batrachotoxin-modified sodium channels of node of Ranvier membranes at high positive and negative potentials

Ionic currents through batrachotoxin-modified sodium channels in frog nerve fibres were measured over a wide range of membrane potentials. At potentials above +80 mV currents decay in time and their steady-state level decreased as potentials increased. "Instantaneous" current measurements have shown that this phenomenon was due to the decrease in net channel conductance. Scorpion toxin affected current kinetics only slightly at these potentials, which suggested that these decays were not caused by usual inactivation process. Externally applied procaine induced slow (tens of ms) potential-dependent block of batrachotoxin-modified channels at large positive potentials. At large negative potentials (above -100 mV) "instantaneus" currents decreased due to fast voltage-dependent block of the channels by calcium ions.     

Effect of ethanol on subthreshold currents of Aplysia pacemaker neurons

The subthreshold currents in bursting pacemaker neurons of the Aplysia abdominal ganglion were individually studied with the voltage clamp technique for sensitivity to 4% ethanol. The most prevalent effect of ethanol on unclamped bursting neurons was a hyperpolarization. This was shown to be due to a decrease of a voltage independent inward leakage current. Direct measurement of the Na-dependent slow inward current showed that this current was eliminated by 4% ethanol. Direct measurement of the Ca-dependent slow inward current showed that this current was substantially reduced by 4% ethanol. Injection of EGTA into cell bodies did not eliminate the ethanol-induced block of the slow inward calcium current. Thus, ethanol cannot be reducing the Ca-dependent slow inward current solely by an increase of internal calcium concentration. The effect of ethanol on voltage dependent outward current was measured by blockage of all inward current. The peak outward current was increased by ethanol. The rate of inactivation of this outward current was also increased. Calcium activated potassium current (IK(Ca)) is particularly complicated in its response to ethanol because it is dependent on both Ca and voltage for its activation. The level of IK(Ca) elicited in response to constant Ca injection was increased by ethanol treatment. The level of this current as activated by voltage clamp pulses was either increased or decreased depending on the neuron type. Ca2+ activated potassium conductance increased e-fold for a 26 mV depolarization in membrane holding potential. Ethanol decreased this voltage dependence to e-fold for a 55 mV change in potential. This result was interpreted to mean that ethanol shifted an effective Ca2+ binding site of these channels from about halfway through the membrane field to one quarter of the way across. The same theoretical approach allowed the further conclusion that ethanol caused an increased internal free calcium concentration probably by decreasing calcium binding by intracellular buffers.     

Hyperpolarization-activated (Ih) current in mouse vestibular primary neurons

The presence of a hyperpolarization-activated inward current (Ih) was investigated in mouse vestibular primary neurons using the whole-cell patch-clamp technique. In current-clamp configuration, injection of hyperpolarizing currents induced variations of membrane voltage with prominent time-dependent rectification increasing with current amplitudes. This effect was abolished by 2 mM Cs+ or 100 microM ZD7288. In voltage-clamp configuration, hyperpolarization pulses from -60 mV to -140 mV triggered a slow activating and non inactivating inward current that was sensitive to the two blockers, but insensitive to 5 mM Ba2+. Changing Na+ and K+ concentrations demonstrated that Ih current is carried by both these monovalent cations. This is the first demonstration of a Ih current in vestibular primary neurons.