Activation of calcium channel currents in rat sensory neurons by large depolarizations: effect of Guanine nucleotides and (-)-baclofen

Calcium channel currents have been recorded from cultured rat sensory neurons at clamp potentials of between -30 and +120 mV. At large depolarizing potentials between +50 and +120 mV, the current was outward. This outward current was shown to be largely due to ions passing through calcium channels, because it was substantially although generally incompletely blocked by Cd2+ (1 mM) and omega-conotoxin (1 microM). Internal GTP-gamma-S (100 microM) and to a lesser extent GTP (1 mM) reduced the amplitude and slowed the activation of the outward, as well as the inward calcium channel current. Baclofen (100 microM) reversibly inhibited both the inward and outward currents. These results suggest that the effect of baclofen and G protein activation on calcium channel currents is not due to a shift in the voltage-dependence of channel availability.     

Calcium-dependent potassium conductance in neurons of rabbit vesical pelvic ganglia

Intracellular recordings were made from neurons of vesical pelvic (parasympathetic) ganglia (VPG) isolated from the rabbit urinary bladder. Spontaneous hyperpolarizations (SH), occurring at intervals of 30 s to 5 min, could be recorded from 53% of VPG neurons in Krebs solution. The action potential was associated with inward sodium and calcium currents and was followed by fast and slow afterhyperpolarizations (AHPs). The action potential also evoked an additional hyperpolarization which was identical to the SH. The SH and the AHPs were associated with a decrease in the input resistance and reversed their polarity close to the potassium equilibrium potential. Intracellular cesium ions blocked the AHPs and the SH. Superfusing the preparation with a calcium-free solution produced a depolarization associated with an increased input resistance. The outward rectification activated at the resting membrane potential was depressed in the calcium-free solution. The removal of extracellular calcium ions also depressed both the SH and the spike AHPs. Bath-application of caffeine (1-3 mM) increased the frequency of the appearance of the SH. Injection of EGTA into VPG neurons caused a depolarization due to a blockade of the outward rectification. EGTA also depressed the slow AHP and the SH. These results suggest that the neuronal membrane of the rabbit VPG is endowed with a calcium-dependent potassium conductance (gKCa). Apamin (0.3-5 nM) and (+)-tubocurarine (30-300 microM) blocked the slow AHP and the SH without affecting the fast AHP and the resting membrane potential. Tetraethylammonium (TEA, 0.3-5 mM) suppressed the fast AHP and the SH without affecting the outward rectification. TEA augmented the slow AHP. Barium ions (0.1-1 mM) depressed the AHPs, the SH and the outward rectification. These pharmacological properties imply that at least 3 kinds of gKCa systems underlie the generation of the outward rectification, the spike AHPs and the SH.     

The role of intrinsic and agonist-activated conductances in determining the firing patterns of preoptic area neurons in the guinea pig

Whole-cell and intracellular recordings were made in coronal hypothalamic slices prepared from ovariectomized female guinea pigs. 62% of preoptic area (POA) neurons fired action potentials in a bursting manner, and exhibited a significantly greater afterhyperpolarization (AHP) than did non-bursting POA neurons. The majority (70%) of POA neurons (n=76) displayed a time-dependent inward rectification (I(h)) that was blocked by CsCl (3 mM) or by ZD 7288 (30 microM). In addition, 51% of the cells expressed a low-threshold spike (LTS) associated with a transient inward current (I(T)) that was blocked by NiCl(2) (200 microM). A smaller percentage of POA neurons (29%) expressed a transient outward, A-type K(+) current that was antagonized by a high concentration of 4-aminopyridine (3 mM). Moreover, POA neurons responded to bath application of the mu-opioid receptor agonist DAMGO (93%) or the GABA(B) receptor agonist baclofen (83%) with a membrane hyperpolarization or an outward current. These responses were accompanied by a decrease in input resistance or an increase in conductance, respectively, and were attenuated by BaCl(2) (100 microM). In addition, the reversal potential for these responses closely approximated the Nernst equilibrium potential for K(+). These results suggest that POA neurons endogenously express to varying degrees an AHP, an I(h), an I(T) and an A-type K(+) current. The vast majority of these neurons also are inhibited upon mu-opioid or GABA(B) receptor stimulation via the activation of an inwardly-rectifying K(+) conductance. Such intrinsic and transmitter-activated conductances likely serve as important determinants of the firing patterns of POA neurons.     

Inhibition of delayed rectifier K+ conductance in cultured rat cerebellar granule neurons by activation of calcium-permeable AMPA receptors

Activation of AMPA (alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid) receptors in cerebellar granule cells during perforated-patch whole-cell recordings activated an inward current at negative voltages which was followed, after a delay, by the inhibition of an outward potassium current at voltages positive to -20 mV. The activated inward current was inwardly rectifying suggesting that the AMPA receptors were Ca2+-permeable. This was confirmed by direct measurements of intracellular calcium where Ca2+ rises were seen following AMPA receptor activation in Na+-free external solution. Ca2+ rises were equally large in the presence of 100 microM Cd2+ to block voltage-gated Ca2+ channels. Specific voltage-protocols, allowing selective activation of the delayed rectifier potassium current (KV) and the transient A current (KA), showed that kainate inhibited KV, but not to any great extent KA. The inhibition of KV was blocked by the AMPA receptor antagonist CNQX (6-cyano-7-nitroquinoxaline-2,3-dione) and was no longer observed when the KV current was abolished with high concentrations of Ba2+. The responses to kainate were not altered by pre-treating the cells with pertussis toxin, suggesting that the AMPA receptor stimulation of the G-protein Gi cannot account for the effects observed. Replacing extracellular Na+ with choline did not alter the inhibition of KV by kainate, however, removing extracellular Ca2+ reduced the kainate response. The inhibition of KV by kainate was unaffected by the presence of 100 microM Cd2+. The guanylyl cyclase inhibitor, ODQ (1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one), did not alter kainate inhibition of KV. It is concluded that ion influx (particularly Ca2+ ions) through AMPA receptor channels following receptor activation leads to an inhibition of KV currents in cerebellar granule neurons.     

Excitation of substantia nigra pars compacta neurones by 5-hydroxy-tryptamine in-vitro.

Incoming serotonergic fibres are known to make direct synaptic contact with dopamine-containing neurones in the substantia nigra pars compacta (SNc). However, the effects of 5-HT (5-hydroxytryptamine) on these cells have not been thoroughly investigated. In the present study we show that application of 10-50 microM 5-HT increases the firing frequency of SNc neurones in-vitro, and produces inward rectification in a voltage region negative to -50mV. This effect is sensitive to extracellular Cs+, but not to Ba2+, and has similar properties as the intrinsic inward rectifier current, Ih. Antagonists of the 5-HT1A and 5-HT2 receptors were inefficacious. It is concluded that 5-HT excites SNc neurones via an enhancement of the conductance underlying Ih.     

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.     

Inward rectifier produced by Xenopus oocytes injected with mRNA extracted from carp olfactory epithelium

Ionic channels encoded by mRNA extracted from carp olfactory epithelium were investigated by injection into Xenopus laevis oocytes. The oocytes expressed an inward rectifier K+ -channel, as detected under two-electrode voltage clamp conditions. The results were as follows. An inactivating inward current appeared on hyperpolarization and increased with increasing extracellular K+ concentrations. The 0 current potentials plotted as a function of log [K+]0 in the range between 2 to 20 mMK+ fell on a straight line, with a slope of 58 mV per tenfold change in K+ concentration, indicating that the current carrier is K+. Chord conductances reached saturation levels on extreme hyperpolarization. The chord conductances at the saturation levels were 35.7, 22.5, and 13.4 muSec in 20, 10, and 5 mM extracellular K+, respectively. Extracellular application of 0.1 mM Cs+ or 0.1 mM Ba2+ blocked the inward current in 2 mM K+, whereas 1 microM TTX or 0.3 mM Cd2+ did not affect the inward current. Inactivation of the inward currents, which became clear on extreme hyperpolarization, was suppressed with decreasing extracellular Na+ concentration. The present results suggest that carp olfactory epithelium is rich in the inward rectifier and is an excellent source of mRNA for cloning cDNA coding the inward rectifier.     

Nicotinic and muscarinic acetylcholine responses in differentiated PC12 cells

Nicotinic and muscarinic acetylcholine (ACh) responses were investigated in PC12 cells using the conventional whole-cell and nystatin perforated patch techniques. With the nystatin perforated patch, ACh induced three kinds of ionic currents: a rapid transient inward current, a subsequent transient outward current and a long-lasting slow inward current, whereas only a transient inward current was recorded by conventional whole-cell patch. The transient rapid inward current was mimicked by nicotine, but not by muscarine. On the contrary, the transient outward current and the long-lasting slow inward current were mimicked by muscarine but not by nicotine. Both nicotinic and muscarinic antagonists inhibited the transient inward current and the subsequent outward current in a concentration-dependent manner. The current-voltage relationship for the nicotine-induced transient current showed an inward rectification and the reversal potential was close to the Na⁺ equilibrium potential. The ACh-, muscarine-, CCh- and oxotremorine-M induced outward currents increased in a sigmoidal fashion with an increase in the concentration. Neither McN-A-343, an M1 agonist, nor oxotremorine, an M2 agonist, mimicked the muscarinic response. The reversal potential of the muscarinic response was close to the K⁺ equilibrium potential. The muscarinic response was not affected by pre-treatment with pertussis toxin but was enhanced by pre-treatment with Li⁺. In the cells perfused with Ca²⁺-free external solution, only the first application of ACh induced the muscarinic response. Calmodulin antagonists reversibly blocked the muscarinic response in a concentration-dependent manner. Neither protein kinase C inhibitor (H-7), protein kinase A inhibitor (H-8), nor Ca-calmodulin dependent kinase II inhibitor (KN-62) affected the muscarinic response. It was concluded that the ACh-induced rapid inward current was passing through non-selectivecation channels coupled with nicotinic ACh receptors. On the other hand, the muscarinic response is mediated by the activation of M3 receptors coupled to IAP-insensitive G-protein which stimulates the phosphatidylinositol pathway through phospholipase C. Consequently, Ca²⁺ was released by the increase in IP₃. Finally, Ca²⁺-calmodulin binding may lead to opening of the K⁺ channels.     

D2 dopamine receptor activation of potassium channels in identified rat lactotrophs: whole-cell and single-channel recording.

Dopamine (DA) is the major physiological regulator of prolactin secretion from the anterior pituitary, exerting a tonic inhibitory control that is mediated by D2 DA receptors. D2 receptors in both the anterior pituitary and CNS are thought to produce some of their inhibitory effects via a coupling to potassium (K+) channels to increase K+ conductance. Utilizing the reverse hemolytic plaque assay and patch-clamp techniques, we characterize the actions of DA on membrane potential and associated DA-activated whole-cell current, as well as the single K+ channels that underlie the response in primary rat lactotrophs. We demonstrate that DA (5 nM to 1 microM) or D2-selective agonists (RU24213 and quinpirole) evoke a hyperpolarization of membrane potential that was blocked by D2 antagonists and associated with an increased K+ conductance. Whole-cell current responses to ramp voltage commands revealed a DA-activated current whose reversal potential was near the calculated Nernst potential for K+, varied as a function of K+ concentration, exhibited some inward rectification, and was Ca2+ independent. The current was insensitive to tetraethylammonium (TEA; 10 mM), partially blocked by 4-aminopyridine (4-AP; 5 mM), and almost completely inhibited by quinine (100 microM). Cell-attached recordings in the presence of DA or a D2 agonist revealed the opening of a K+ channel that was not present in the absence of DA or when a D2 receptor antagonist was included with DA. Analysis of the single-channel current showed the current-voltage relationship to be linear at negative patch potentials and yielded a unitary conductance of 40.2 pS in the presence of 150 mM KCl. The channels were not blocked by TEA (10 mM), were slightly suppressed by 4-AP (5 mM), and were almost completely inhibited by quinine (100 microM). These experiments establish that in primary rat lactotrophs, DA acts at D2 receptors to activate the opening of single K+ channels, which results in an increase in K+ conductance and associated membrane hyperpolarization. This is the first characterization of single DA-activated K+ channels in an endocrine cell.     

Analysis of FMRF-amide effects on Aplysia bursting neurons

The peptide L-phenylalanyl-L-methionyl-L-arginyl-L-phenylalaninamide (FMRF-amide) was pressure-applied onto the somata of bursting neurons L4 and L6 in the Aplysia abdominal ganglion. FMRF-amide causes a biphasic response, first depolarizing and then hyperpolarizing the neuron. In voltage-clamp experiments, FMRF-amide induces an inward current that begins 100-200 msec after applying the peptide and peaks in 2-10 sec. This is followed by an outward current that begins with a latency of 2-5 sec and peaks in 15-65 sec. The entire response lasts 1-5 min. Experiments were done to separate the two currents induced by FMRF-amide on the basis of ion selectivity and kinetics and to determine their I(V) relationships. The currents were studied using a method to quickly measure I(V) curves. The inward current is caused by a conductance increase and has a reversal potential of approximately +18 mV. This current depends on the concentration of extracellular Na ions but not Ca, Cl, or K ions and is insensitive to tetrodotoxin, hexamethonium, and curare. The outward current is caused by a conductance increase and has a reversal potential of approximately -61 mV, which is similar to the reversal potential of the fast, transient K current (IA) in the same cells. This current is sensitive to changes in the external K ion concentration but not to changes in Cl, Ca, or Na concentration. The outward current is partially blocked by 1 mM 4-aminopyridine but not TEA or curare. Neither current is significantly voltage dependent within the range from -70 to -40 mV.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro electrophysiology of rat subicular bursting neurons

Intracellular recordings were used to study the electrophysiological properties of rat subicular neurons in a brain slice preparation in vitro. Cells were classified as bursting neurons (n = 102) based on the firing pattern induced by depolarizing current pulses. The bursting response recorded at resting membrane potential (−66.1 ± 6.2 mV, mean ± SD n = 94) was made up of a cluster of fast action potentials riding on a slow depolarization and was followed by an afterhyperpolarization. Tonic firing occurred at a membrane potential of approximately −55 mV. A burst also occurred upon termination of a hyperpolarizing current pulse. Tetrodotoxin (TTX, 1 μM) blocked the burst and decreased or abolished the underlying slow depolarization. These effects were not induced by the concomitant application of the Ca²⁺ channel blockers Co²⁺ (2 mM) and Cd²⁺ (1 mM). Subicular bursting neurons displayed voltage- and time-dependent inward rectifications of the membrane during depolarizing and hyperpolarizing current pulses. The inward rectification in the depolarizing direction was abolished by TTX, while that in the hyperpolarizing direction was blocked by extracellular Cs⁺ (3 mM), but not modified by Ba²⁺ (0.5–1 mM), TTX, or Co²⁺ and Cd²⁺. Tetraethylammonium (10 mM)-sensitive, outward rectification became apparent in the presence of TTX. These results suggest that neurons in the rat subiculum can display voltage-dependent bursts of action potentials as well as membrane rectification in the depolarizing and hyperpolarizing directions. These results also indicate that activation of a voltage-gated Na⁺ conductance may be instrumental in the initiation of bursting activity. Hippocampus 7:48–57, 1997. © 1997 Wiley-Liss, Inc.     

An inward rectifier is present in presynaptic nerve terminals in the chick ciliary ganglion

Inwardly rectifying voltage-sensitive channels have been detected in the cell bodies and axons of a number of excitable cells. The question of whether similar channels exist at axon terminals has been a matter of speculation for some time. We now report the first direct evidence for the existence of inward rectifiers in vertebrate presynaptic nerve terminals. Following impalement with intracellular electrodes, the large calyciform nerve terminals innervating chick ciliary ganglion neurons exhibit pronounced inward rectification upon hyperpolarization that increases with increasing current strength. The response is blocked by 2 mM Cs+, but is insensitive to Ba2+, tetraethylammonium and tetrodotoxin. The inward rectifier exhibits dependence on both Na+ and K+, but is unaffected by altering extracellular Ca2+. Ciliary neurons innervated by these nerve terminals display inward rectification with similar properties. We conclude that the inward rectifier present in these presynaptic nerve terminals resembles the H-current previously described in sensory ganglion neurons and the Q-current found in hippocampal pyramidal neurons. The presence of channels that are activated by hyperpolarization may serve to enhance the excitability of the calyciform nerve terminals, which are capable of relatively high frequencies (greater than 100 Hz) of discharge.     

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.     

Intrinsic membrane potential oscillations in hippocampal neurons in vitro

Membrane potential oscillations (MPOs) of 2-10 Hz and up to 6 mV were found in almost all stable hippocampal CA1 and CA3 neurons in the in vitro slice preparation. MPOs were prominent for pyramidal cells but less pronounced in putative interneurons. MPOs were activated at threshold depolarizations that evoked a spike and the frequency of the MPOs increased with the level of depolarization. MPOs were distinct from and seemed to regulate spiking, with a spike often riding near the top of a depolarizing MPO wave. Analysis of the periodicity of the oscillations indicate that the period of MPOs did not depend on the afterhyperpolarization (AHP) following a single spike. MPOs persisted in low (0-0.1 mM) Ca2+ medium, with or without Cd2+ (0.2 mM), when synaptic transmission was blocked. Choline-substituted low-Na+ (0-26 mM) medium, 3 microM tetrodotoxin (TTX) or intracellular injection of QX-314 reduced or abolished the fast Na(+)-spike and reduced inward anomalous rectification. About 40% of CA1 neurons had no MPOs after Na+ currents were blocked, suggesting that these MPOs were Na(+)-dependent. In about 60% of the cells, a large depolarization activated Ca(2+)-dependent MPOs and slow spikes. MPOs were not critically affected by extracellular Ba2+ or Cs2+, or by 0.2 mM 4-aminopyridine, with or without 2 mM tetraethylammonium (TEA). However, in 5-10 mM TEA medium, MPOs were mostly replaced by 0.2-3 Hz spontaneous bursts of wide-duration spikes followed by large AHPs. Low Ca2+, Cd2+ medium greatly reduced the spike width but not the spike-bursts. In conclusion, each cycle of an MPO in normal medium probably consists of a depolarization phase mediated by Na+ currents, possibly mixed with Ca2+ currents activated at a higher depolarization. The repolarization/hyperpolarization phase may be mediated by Na+/Ca2+ current inactivation and partly by TEA-sensitive, possibly the delayed rectifier, K+ currents. The presence of prominent intrinsic, low-threshold MPOs in all hippocampal pyramidal neurons suggests that MPOs may play an important role in information processing in the hippocampus.     

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.     

Regulation of bradykinin- and ATP-activated Ca(2+)-permeable channels in rat pheochromocytoma (PC12) cells.

Membrane currents activated by bradykinin (500 nM) and by extracellular ATP (50 microM) were studied in voltage-clamped, NGF-treated rat pheochromocytoma (PC12) cells. Under quasiphysiological ionic conditions, both substances caused an outward current due to opening of Ca(2+)-activated K+ channels. Bradykinin caused an additional inward current that could be studied after blockade by internal Cs+ of the initial transient outward current. The inward current became larger when the extracellular Ca2+ concentration was increased. Neither inositol-1,4,5-trisphosphate, dioctanoylglycerol, phorbol 12-myristat 13-acetate, forskolin, GTP, GTP-gamma-S, or pretreatment with pertussis toxin affected this current component. Increasing the internal Ca buffer concentration [EGTA or bis-(o-aminophenoxy)-ethane-N,N,N',N'-tetra-acetic acid] from 1 to 10 mM had no effect on the inward current as long as the free [Ca2+]i was kept constant. However, it was modulated by the resting free [Ca2+]i. Elevation of [Ca2+]i from nominally 0 to 60 or to 180 nM increased the bradykinin-induced average peak current density from 0.14 to 1.04 or to 2.29 pA/pF, respectively. This regulation may depend on a calmodulin-dependent pathway, since CGS 9343B, a calmodulin inhibitor, blocked the effect of elevated [Ca2+]i. With ATP as an agonist, outward current was preceded by a large inward current that was partially blocked by extracellular Ca2+ in the millimolar range. Extracellular Ca2+ was also found to reduce the single-channel conductance estimated from outside-out patches treated with ATP.     

Opioids act at mu-receptors to hyperpolarize arcuate neurons via an inwardly rectifying potassium conductance

Intracellular recordings were made from 48 hypothalamic arcuate (ARC) neurons under current- and voltage-clamp in slices prepared from female guinea pigs which had been ovariectomized and pretreated with estradiol. Twenty ARC neurons were silent (RMP: -62 +/- 2 mV) and 28 cells were spontaneously active (7.3 +/- 1.1 Hz; threshold -57 +/- 1 mV). The input resistance (Rin), determined in the potential range between -60 and -80 mV, was 358 +/- 30 M omega (n = 38) and ARC neurons showed inward rectification at potentials negative to the equilibrium potential for potassium. The selective mu-opioid agonist Tyr-D-Ala-Gly-MePhe-Gly-ol (DAGO) was applied by pressure pipette application at concentrations of 10 or 20 microM. DAGO decreased spontaneous firing and it hyperpolarized 26 of 31 neurons (9.6 +/- 0.8 mV; range 3-21 mV). Concomitant with the hyperpolarization, DAGO caused a decrease in Rin of 32 +/- 3, and the reversal potential, measured from current-voltage plots, was -94 +/- 2 mV. These effects were mimicked by bath concentrations of 0.5-1.0 microM DAGO. In voltage clamp, DAGO caused an outward current to flow at -60 mV (range 50-185 pA, n = 6). This current reversed at -92 +/- 2 mV (n = 6) and exhibited inward rectification. An additional 6 ARC neurons were tested with DAGO in varying extracellular concentrations of K+ (2.5, 5 and 10 mM) and the reversal potential for the effect of DAGO shifted by 58 mV per decade change in extracellular K+ concentration. DAGO decreased spontaneous postsynaptic potentials in some cells, but TTX (1 microM) had no effect on the ability of DAGO to hyperpolarize the membrane. The hyperpolarization and decrease in Rin induced by DAGO were blocked by the opioid antagonist naloxone (100 nM-1 microM). DAGO responsive cells were unaffected by a kappa-opioid agonist (trans-(+/-)-3,4-dichloro-N-methyl-N-[2-(1- pyrrolidinyl)cyclohexyl]benzeneacetamide methanesulphonate; U50,488H), however, 2 of 5 cells also were hyperpolarized by a selective delta-receptor opioid agonist (Tyr-D-Pen-Gly-Phe-D-Pen; DPDPE). The effects of DPDPE, but not DAGO, were blocked by a delta-antagonist (ICI 174,864; 1 microM). The present results indicate that activation of ARC mu-receptors leads to an increase in an inwardly rectifying potassium conductance and a subsequent hyperpolarization of most ARC neurons. We suggest that this mu-receptor-induced hyperpolarization of ARC neurons may underlie the opioid inhibition of reproductive events in the mammal.     

Ionic mechanism of the outward current induced by intracellular injection of inositol trisphosphate into Aplysia neurons

Inositol 1,4,5-trisphosphate (InsP3) has been proposed to be the intracellular second messenger in the mobilization of Ca2+ from intracellular stores in a variety of cell types. The ionic mechanism of the effect of intracellularly injected InsP3 on the membrane of identified neurons (R9-R12) of Aplysia kurodai was investigated with conventional voltage-clamp, pressure-injection, and ion-substitution techniques. Brief pressure injection of InsP3 into a neuron voltage-clamped at -40 mV reproducibly induced an outward current (10-60 sec in duration, 20-60 nA in amplitude) associated with a conductance increase. The current was increased by depolarization and decreased by hyperpolarization up to -80 mV, where it disappeared. Extracellular application of tetraethylammonium (TEA; 5 mM) blocked the InsP3-induced outward current, and the current was not affected by the presence of bath-applied 4-aminopyridine (4-AP; 5 mM). The InsP3-induced outward current recorded at a holding potential of -40 mV increased in amplitude in low-K+ solutions and decreased in amplitude in high-K+ solutions. Alteration of [Cl-]0, as well as perfusion with Ca2+ free plus 2 mM EGTA solution, did not affect the outward current. The InsP3-induced outward current was found to disappear when the neuron was injected with the Ca2+ chelator EGTA. The outward current evoked by repeated InsP3 injection at low doses exhibited summation and facilitation and, at high doses, was shown to desensitize. The calmodulin inhibitor N-(6-amino-hexyl)-5-chloro-1-naphthalene sulfonamide (W-7; 20-50 microM), inhibited both the InsP3-induced and the Ca2+-activated outward currents. An intracellular pressure injection of Ca2+ ions into the same identified neuron was shown to produce an outward current associated with a K+ conductance increase similar to the InsP3-induced current, and the current was blocked by bath-applied TEA (5mM). These results suggest that brief pressure injection of InsP3 into certain identified neurons of Aplysia induces a 4-AP-resistant, TEA-sensitive K+ current activated by increased intracellular free Ca2+ concentration, and this increase might be the result of the mobilization of Ca2+ from intracellular stores by InsP3.     

A muscarine-sensitive, slow, transient outward current in frog autonomic neurones

A slow, 4-aminopyridine-sensitive K+ current was observed in Rana pipiens autonomic neurones when they were studied under whole-cell patch-clamp recording conditions. This 'slow-A' current (ISA), which was independent of extracellular Ca2+, exhibited a similar voltage dependence to a classical A current (IA) yet inactivated with an 80-fold slower time course. Although ISA is difficult to distinguish from the delayed rectifier K+ current (IK), muscarine enhanced the current in sympathetic neurones and either enhanced or suppressed the current in parasympathetic neurones. Effects on slow transient outward currents must therefore be considered when attempting to understand cholinergic modulation of repetitive discharge in autonomic neurones.     

Ionic mechanism mediating Mytilus inhibitory peptides elicited membrane currents in identified Helix neurons

Effects of seven, pressure applied MIP (Mytilus inhibitory peptides) had been studied on D-neurons of the CNS of Helix pomatia in voltage-clamp experiments. In physiological saline, the peptides produced a hyperpolarization usually coupled with the cessation of any spontaneous spiking activity. Clamped at the resting potential (−60 mV), peptide applications elicited an outward current, which increased its amplitude by shifting the holding potential towards depolarisation. The response was concentration-dependent and accompanied by an increased membrane conductance. Reversal potentials obtained at different [K⁺]_o were plotted with a slope of 52 mV per ten-fold change in [K⁺]_o showing that the peptide-elicited current was mainly due to the increased K⁺-conductance(s). The peptide-induced outward current could partially be blocked by Ba²⁺ (5 mM), CdCl₂ (1 mM), TEACl (10 mM) or apamin (2.5×10⁻⁵ M) or furosemide (10 mg/ml) and decreased either in Na⁺-free or Cl⁻-free solutions. 4-Aminopyridine at 5 mM concentration completely blocked the peptide-induced current. In the presence of high [K⁺]_o, the peptide(s) was still found to induce an outward current at membrane potentials beyond K⁺-reversal potential. This component was not present in Cl⁻-free saline, suggesting that the current was due to the inward flow of Cl⁻ ions. Our results show that the MIPs have at least two (three) independent actions, each associated with different voltage-, concentration-dependence and ionic mechanisms. It is suggested, that the peptide-induced currents are carried by K⁺, and Cl⁻ ions. According to our present finding, the observed effects are mediated by the same receptor, activating different second messenger systems, inducing multiple conductance changes in the membrane of neurons of the snail ganglia.