The coupling of neurotransmitter receptors to ion channels in the brain

GABAB receptors expressed in Xenopus oocytes by guinea pig cerebral mRNA are functionally coupled with Ca2(+)-dependent Cl- channels and with K+ channels, through GTP-binding proteins

Transmembrane currents induced by (-)-baclofen (BAC), a specific agonist of the gamma-aminobutyric acid-B (GABAB) receptor, in Xenopus oocytes injected with guinea pig cerebral mRNA were electrophysiologically and pharmacologically characterized under a voltage-clamp condition. The oocytes injected with mRNA acquired responsiveness to BAC and showed two types of currents at a holding potential of -50 mV. One was the slow and smooth inward current which had a short latency and associated with a decrease in membrane conductance, and its amplitude was decreased by hyperpolarization and increased by depolarization. The other was the large fast oscillatory inward current with a long-latency, which was decreased in amplitude by depolarization and reversed at -26 mV. Both currents were not blocked by bicuculline but were depressed by 2-hydroxysaclofen (2-OH-SAC), though the smooth current was less sensitive to 2-OH-SAC; about 40% blockade at the 2-OH-SAC concentration capable of abolishing the oscillatory current. The smooth current was depressed by Ba2+. The oscillatory current was time-dependently attenuated and almost abolished by intracellularly injected pertussis toxin (PTX), while the smooth current was not depressed by this toxin even when the oscillatory current was nearly abolished. The intracellular injection of GTP-gamma-S into oocytes attenuated both oscillatory and smooth currents. These results suggest the possibility that GABAB receptors expressed in Xenopus oocytes by cerebral mRNA are functionally coupled with two signal transduction systems, one is the opening of Ca2(+)-dependent Cl- channels mediated by PTX-sensitive GTP-binding protein(s) and the other is the closure of K+ channels through PTX-insensitive GTP-binding protein(s).

Mechanisms generating the time course of dual component excitatory synaptic currents recorded in hippocampal slices

We studied with the whole-cell recording techniques, the mechanisms underlying the time course of the slow N-methyl-D-aspartate (NMDA), and fast non-NMDA receptor-mediated excitatory postsynaptic currents (EPSCs) in hippocampal slices. The rising phase of the NMDA receptor-mediated component of the EPSC as well as the decaying phase of the NMDA and non-NMDA component were highly temperature-sensitive, suggesting that neither of these processes is determined by free diffusion of transmitter. Moreover, glutamate uptake blockers enhanced the responses to exogenously applied glutamate, but had no effect on the decay of either the NMDA or non-NMDA components of the EPSCs. On the other hand, open channel blockers known to modify NMDA channel kinetics reduced the EPSC decay time. Thus, the present results support a model in which the rise time and decay of the NMDA component are determined primarily by slow channel kinetics and the decay of the non-NMDA component is due either to channel kinetics or to desensitization.

Markers for biogenic amines in the aged rat brain: relationship to decline in spatial learning ability

The major goal of the study was to evaluate the relationship of brain aging to individual differences in functional decline in rats. Forebrain choline-acetyltransferase (ChAT) and monoamines, including their metabolites, were examined in young and aged male Long-Evans rats in relation to their spatial learning ability. Aged rats that were unimpaired on a spatial learning task exhibited few changes in neurochemistry relative to the young group: each change in this subgroup was also evident in the remaining aged animals that were behaviorally impaired. Additional changes in neurochemical measures only found in the behaviorally impaired aged animals included decreased ChAT in the basal forebrain, striatum, and frontal cortex. A cluster analysis using the 15 neurochemical measures that were sensitive to aging yielded groupings of aged animals that differed with respect to their spatial learning ability, but not in their cue learning latencies. In this analysis the activity of ChAT in the basal forebrain and striatum appeared to be the best predictors of spatial learning impairment.

Intracellular regulation of ion channels in cell membranes

Cells communicate with their environment through receptor proteins on the cell membrane. Some ion channels are receptors, whereas others are linked to receptors through guanine nucleotide-binding proteins (G proteins). Ion channels control intracellular concentrations of ions such as calcium, and these concentrations control cell functions such as secretion and cell division. This review summarizes the current state of knowledge about the control of ion channels.

Immunocytochemical localization of the neural-specific regulatory subunit of the type II cyclic AMP-dependent protein kinase to postsynaptic structures in the rat brain

The cellular and subcellular distribution of a major cyclic AMP binding protein in the central nervous system, the neural-specific regulatory subunit of the type II cyclic AMP-dependent protein kinase (RII-B), was analyzed in rat brains with light and electron microscopic immunocytochemical methods. The distribution of the non-neural isoform of the regulatory subunit of the enzyme (RII-H) was also analyzed. It was found that RII-B immunoreactivity was predominantly localized to neurons whereas glial and endothelial cells were unlabeled. In the neurons the RII-B immunoreactivity occurred in the perikaryal cytoplasm and in the dendrites; there was no significant accumulation of immunoreaction product in nuclei, myelinated axons and axon terminals. Although immunoreactivity was never detected in axon terminals, it was characteristically associated with the postsynaptic densities and the surrounding non-synaptic sites in somata, dendrites and dendritic spines. The localization of RII-B antigenic sites did not show specificity to any type of neuron or synapse, but the amount of immunoreactivity varied. The distribution of RII-H immunoreactivity was similar to that of RII-B except that RII-H immunoreaction product was also observed in glial cells and occurred more frequently in myelinated axons. Our data confirm that RII-B is one of the major cyclic AMP binding proteins in neurons, and provide morphological support for the involvement of the type II cyclic AMP-dependent protein kinase in postsynaptic neural functions.

Mineralocorticoid receptor-mediated changes in membrane properties of rat CA1 pyramidal neurons in vitro

Pyramidal neurons in the rat hippocampus contain mineralocorticoid receptors (MRs) and glucocorticoid receptors (GRs) to which the adrenal steroid corticosterone binds with differential affinity. We have used intracellular recording techniques to examine MR-mediated effects on membrane properties of CA1 pyramidal neurons in hippocampal slices from adrenalectomized rats. Low doses of corticosterone (1 nM) applied by perfusion for 20 min decreased the spike accommodation observed during a depolarizing current pulse (0.5 nA for 500 ms) and the amplitude of the subsequent afterhyperpolarization without affecting other membrane properties tested. The decrease became apparent ca. 15 min after steroid perfusion was started and reached its peak value 10-20 min after the steroid perfusion was terminated. The steroid effect was blocked by the MR antagonist spironolactone and mimicked by the natural MR ligand aldosterone (1 nM). Neurons recorded 30-90 min after termination of aldosterone application still displayed a decreased spike accommodation. However, 30-90 min after corticosterone application, the decrease in spike accommodation/afterhyperpolarization appeared to be reversed. Higher doses of corticosterone (greater than or equal to 30 nM) induced a significant increase in accommodation and amplitude of the afterhyperpolarization, as was previously observed for selective GR ligands. The data indicate that MR and GR activations induce opposite actions on the spike accommodation/afterhyperpolarization of CA1 pyramidal neurons, an important intrinsic mechanism of these neurons to regulate their response to excitatory input. We suggest that occupation of both MR and GR by the endogenous ligand corticosterone will result in an initial MR-mediated enhanced cellular excitability, which is gradually reversed and overridden by a GR-mediated suppression of cellular activity.

Loss of channel modulation by transmitter and protein kinase C during innervation of an identified leech neuron

When serotonergic Retzius (R) neurons of the leech contact pressure-sensitive (P) neurons in culture, P cells selectively lose a protein kinase C-dependent cationic response to serotonin and the R cell reforms the inhibitory, chloride-dependent synapse seen in vivo. In P cells not contacted by R cells, cell-attached patches contained single cation channels sensitive to serotonin and phorbol ester with characteristic properties and high incidence (present in about one-half of the patches). P cells paired with R cells had a cation channel with similar biophysical properties and incidence, but channel activity was not stimulated by serotonin and phorbol ester. These results suggest that the early clearing of the non-synaptic (excitatory) response to serotonin is due to the loss of activation by protein kinase C (and not the number) of cation channels as a prelude to inhibitory synapse formation.

Messenger molecules in the cerebellum

As data accumulate, the mammalian brain reveals its complex and subtle synaptic mechanisms. In the simplest system, a neurotransmitter binds to the receptor portion of a molecular complex incorporating an ion channel and thus alters the membrane potential, leading to excitatory or inhibitory effects. In more complex systems, receptors are coupled to second messenger systems to generate signals of longer duration and to modulate more diverse molecular mechanisms. The cerebellar cortex has a relatively simple wiring diagram with the primary neurotransmitter of most inhibitory and excitatory synapses well established. The second messenger signalling systems are more complex and those of the cerebellar output, the Purkinje cells, are the best characterized. More recently, molecules that might act as neuromodulators, carrying messages between neurons and between neurons and glial cells, have been identified, such as endothelin and nitric oxide. The classic neurotransmitters and novel neuromodulators, together with second messenger-activated trophic factors, can interact in complex ways; in this review Christopher Ross, David Bredt and Solomon Snyder discuss how studies of cerebellar circuitry and biochemistry are revealing such interrelations.

Pharmacology of spinal opioids

This review presents the pharmacology of spinal opioid receptor systems which are primarily involved in pain processing. The major areas upon which we will focus are: the structure and cellular functioning of the opioid receptor systems; the physiologic effects induced by spinally administered opioids, particularly in pain modulation; and pharmacokinetic and dynamic considerations, with special attention to the problem of opioid tolerance development.

Changes in blood-brain barrier and cerebral blood flow following elevation of circulating serotonin level in anesthetized rats

Plasma serotonin (5-HT) was elevated by an intravenous infusion of this amine into urethane-anaesthetized rats and the concentration approximated that present in various neurological diseases and mental abnormalities. An infusion of 10 micrograms per kg body weight for 10 min significantly increased blood-brain barrier (BBB) permeability to Evans blue and 131I-sodium measured in whole brain. Regional BBB determinations with labelled 131I-sodium showed that the permeability to this compound was increased in the cerebral cortex, hippocampus, caudate nucleus, hypothalamus, colliculus and the cerebellum but not in the pons and the medulla oblongata. Regional blood flow was reduced in the same parts which showed BBB abnormality tested with 125I-labeled microspheres. Pretreatment with cyproheptadine, a 5-HT2 receptor antagonist, prevented the BBB increase and the regional blood flow was near normal values. Similar effects were obtained with indomethacin, a prostaglandin synthesis inhibitor. Vinblastine, known to influence vesicular transport, eliminated extravasation of the tracers but the regional blood flow remained depressed. A hypothesis is put forward that serotonin after binding to its receptor in the cerebral vessels stimulates prostaglandin which either directly or by means of cyclic adenosine monophosphate causes an increased vesicular transport across the endothelial cells and thus an extravasation of tracer substances in the brain. Obviously, this form of exudation can be influenced by pharmacological means.

Learning-induced afterhyperpolarization reductions in hippocampus are specific for cell type and potassium conductance

Hippocampal slices were prepared from rabbits trained in a trace eye-blink conditioning task and from naive and pseudoconditioned controls. Measurements of the post-burst afterhyperpolarization (AHP), action potential, and other cellular properties were obtained from intracellular recordings of CA1 pyramidal (N = 49) and dentate gyrus granule cells (N = 52). A conditioning-specific reduction in the amplitude of the AHP was found in CA1 cells but not in dentate granule cells. This reduction in the AHP was apparent at 50 ms after the end of a depolarizing current pulse, and was maintained for at least 650 ms. Other measured cell characteristics (input resistance, resting membrane potential, action potential shape, inward rectification, spike threshold) were not affected by training, in either CA1 pyramidal or dentate granule cells. Time-course measures indicate that both the medium, Ca2(+)-independent AHP and the slow, Ca2(+)-dependent AHP are reduced by conditioning. The slow AHP largely reflects the Ca2(+)-dependent K+ current, IAHP. Rising and falling slopes, peak amplitude, and width of individual action potentials were not changed by learning. This contrasts with observations from invertebrates in which action potential broadening was reported following learning. We conclude that the reduction in AHP that follows hippocampally-dependent associative learning occurs in specific hippocampal cell types and not others, and is mediated by changes in a Ca2(+)-independent AHP and a particular Ca2(+)-dependent K+ current, IAHP.

Thermal dependence of serotonergic modulation of neural activity in the hamster

1. The modulatory effect of serotonin on CA1 pyramidal cells in the hamster (Mesocricetus auratus) hippocampus was examined over a range of temperatures. 2. Following repetitive Schaffer collateral/commissural stimulation, changes in the amplitude of population spikes (the synchronous firing of CA1 pyramidal cells) were recorded in the hamster, a hibernator. Amplitudes were measured after 10 microM serotonin was added to and then withdrawn from the perfusing medium with the temperature of the bath fixed at different temperatures. 3. Between 35 degrees C and 15 degrees C a depression in population spike amplitude of at least 10% was seen in 36 of 43 trials, with an average depression of 68%. No significant temperature dependence of the depressive effect was seen. 4. Following the removal of serotonin from the perfusate, the spike amplitude was enhanced over the same range of temperatures, averaging 33% higher than control values. The enhancement was most pronounced at 35 degrees C and 15 degrees C and smallest at 25 degrees C. 5. Thus, over the entire temperature range of 35 degrees C to 15 degrees C, serotonin exerted a dual modulatory effect on the spike amplitude, a depression followed by an enhancement. Serotonin's modulatory effects on pyramidal cell excitation persist over temperatures encountered as the hamster enters hibernation.

The G protein-channel connection

Recent interest in the regulation of ion currents by hormones and neurotransmitters has focused on the role of G proteins as modulators. Which G proteins are involved? How is this regulation achieved? Initial results suggest that the pathways and mechanisms of action are complex and that delineation of this area of regulation has just begun.

Gamma-Aminobutyric Acid Modulation of Corticotrophin-Releasing Factor-41 Secretion from the Rat Hypothalamus in vitro

Abstract There is increasing evidence for a centrally mediated inhibitory effect of the amino-acid neurotransmitter y-aminobutyric acid (GABA) on the hypothalamo-pituitary-adrenal axis. In the present study, the direct effect of GABA in modulating the release of the 41-residue corticotrophin-releasing factor (CRF-41), the major CRF identified so far, was investigated in acute hypothalamic explants by utilizing previously validated incubation and assay techniques. While GABA (10(-7)'to 10(-5) M) had no effect on basal CRF-41 release (P > 0.05), it significantly suppressed K (-) (28 mM)-stimulated release in a dose-dependent manner (P < 0.01). A similar inhibitory effect was observed with the GABA agonist muscimol (10(-7) to 10(-5) M). Noradrenaline (10(-6) M) -induced CRF-41 release was also significantly inhibited by GABA 10(-6) M. The inhibitory effect of GABA on K(+)-stimulated CRF-41 secretion was completely. reversed by the GABA antagonists bicuculline and picrotoxin (10(-6) to 10(-5) M) in a dose-dependent fashion. Both bicuculline and picrotoxin stimulated basal and K(+) (28 mM)-stimulated CRF-41 release, indicating the presence of tonic inhibition by endogenous GABA in the basal state. Finally, GABA 10(-5) M was able to significantly inhibit the stimulated release of CRF-41 from the isolated median eminence. In summary, the present data provide strong evidence that GABA-induced inhibition of the hypothalamo-pituitary-adrenal axis is mediated, at least in part, through an inhibitory action on CRF-41 secretion. It is likely that these GABA receptors are located directly on CRF-41 neurons, probably on nerve terminals in the median eminence.

Inward rectification in neonatal rat spinal motoneurones

1. Inward rectifying currents were recorded, using tight-seal, whole-cell voltage-clamp methods, from motoneurones visually identified in thin slices of neonatal rat spinal cord. 2. When motoneurones were hyperpolarized from holding potentials near the resting potential (-60 to -70 mV), a slow inward-going current was recorded. After the hyperpolarizing command pulses, inward tail currents were recorded. Amplitudes of the inward current at the end of hyperpolarizing pulses as well as those of the tail current increased non-linearly with the membrane hyperpolarization, showing an inward rectification in the current-voltage relation. 3. Neither the amplitude nor the kinetics of the inward rectifying current (IIR) was appreciably affected by replacement of extracellularly Ca2+ with Mg2+ combined with the application of tetrodotoxin (1 microM), tetraethylammonium (30 mM), and 4-aminopyridine (4 mM). The current was relatively resistant to Ba2+, being only slightly suppressed at 2 but not at 0.2 mM. However, it was completely and reversibly abolished by Cs+ (2 mM). 4. When the external K+ concentration was raised, IIR was augmented. However, the activation curve of IIR constructed from relative tail current amplitudes in high K+ solutions was indistinguishable from that in normal solution. The chord conductance of IIR at various membrane potentials was similar for both normal and high K+ solutions. Thus the whole-cell conductance of inward rectification in motoneurones depends on the membrane potential but not appreciably on the external K+ concentration ([K+]o). 5. The reversal potential of IIR was estimated by measuring the tail currents. In standard solution ([K+]o = 3 mM), the reversal potential was about -44 mV. Increasing [K+]o shifted the reversal potential toward positive potentials by 22 mV for a tenfold change in potassium concentration. 6. A fivefold reduction in the external Na+ concentration shifted the reversal potential of IIR in a negative direction by about 7 mV, suggesting that Na+ may carry part of IIR. A fivefold reduction in external Cl- concentration shifted the reversal potential by about 2 mV but in a negative direction, the opposite of the expected shift in the Cl- equilibrium potential. 7. When external Cl- was substituted with isethionate or gluconate, IIR was markedly and reversibly suppressed. 8. It is concluded that in spinal motoneurones, IIR is carried by both K+ and Na+ ions and that external Cl- might be required to maintain the inward rectifier current.

Sensory gating deficits in psychiatric inpatients: relation to catecholamine metabolites in different diagnostic groups

Acutely ill psychiatric inpatients were examined for a deficit in sensory gating, measured as failure to suppress the P50 wave of the auditory-evoked response to the second of paired stimuli. Previously, we had found that in mania, this sensory gating deficit is correlated with increased plasma-free levels of the noradrenergic metabolite 3-methoxy, 4-hydroxyphenylglycol (pMHPG), whereas in schizophrenia, there is no correlation with catecholamine metabolism. To assess the generalizability of these findings, we examined inpatients with a broader range of diagnoses, including those with multiple DSM III-R Axis I, II, and III diagnoses. The patients were grouped into three diagnostic spectra for analysis: schizophrenic, manic, and depressive. In the schizophrenic patients, there was no relationship between pMHPG or other catecholamine metabolites and the sensory gating deficit. In manic patients, however, a positive correlation between pMHPG level and the sensory gating deficit was again observed. This relationship did not extend to the depressive patients, who uniquely showed sensory gating deficits that correlated negatively with the severity of their illness. The data suggest that sensory gating deficits are common to these three diagnostic spectra, but the deficits in each group have different relationships to catecholamine metabolism and symptom severity that may reflect differences in the underlying neuronal pathophysiology of these illnesses.

Excitotoxicity induced by enhanced excitatory neurotransmission in cultured hippocampal pyramidal neurons

Cultures of rat hippocampal pyramidal neurons were used to examine the roles of excitatory synaptic transmission, NMDA receptors, and elevated [Ca2+]i in the production of excitotoxicity. In integral of 70% of the cells observed, perfusion with Mg2(+)-free, glycine-supplemented medium induced large spontaneous fluctuations or maintained plateaus of [Ca2+]i. [Ca2+]i fluctuations could be blocked by tetrodotoxin, NMDA receptor antagonists, dihydropyridines, or compounds that inhibit synaptic transmission in the hippocampus, but not by the non-NMDA receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione. When cells were treated with Mg2(+)-free, glycine-supplemented medium and examined 24 hr later, integral of 30% of the neurons were found to have died. Cell death could be inhibited by the same agents that reduced [Ca2+]i fluctuations. These results support a role for direct excitatory synaptic transmission, as opposed to the general release of glutamate, in excitotoxicity. A major role for synaptically activated NMDA receptors, rather than kainate/quisqualate receptors, is also indicated. Neuronal death may be produced by abnormal changes in neuronal [Ca2+]i.

Inositol trisphosphate mediates cloned muscarinic receptor-activated conductances in transfected mouse fibroblast A9 L cells

1. The mechanism by which cloned m1 and m3 muscarinic receptor subtypes activate Ca2+-dependent channels was investigated with whole-cell and cell-attached patch-clamp recording techniques and with Fura-2 Ca2+ indicator dye measurements in cultured A9 L cells transfected with rat m1 and m3 cDNAs. 2. The Ca2+-dependent K+ and Cl- currents induced by muscarinic receptor stimulation were dependent on GTP. Responses were reduced when GTP was excluded from the intracellular recording solution or when GDP-beta-S was added. Intracellular GTP-gamma-S activated spontaneous fluctuations and permitted only one acetylcholine-(ACh) induced current response. These results implicate GTP-binding proteins (G protein) in the signal transduction pathway. This G protein is probably not pertussis toxin-sensitive as the ACh-induced electrical response was not abolished by pertussis toxin treatment. 3. Cell-attached single-channel recordings revealed activation of ion channels within the patch during application of ACh outside the patch, implying that second messengers might be involved in the ACh-induced response. Two types of K+ channel were activated, a discrete channel of 36 pS and channel activity calculated to be about 5 pS. 4. Application of 8-bromo cyclic AMP or 1-oleoyl-1,2-acetylglycerol (OAG) produced no electrical response and did not affect the ACh-induced responses. Phorbol myristic acetate (PMA) evoked no electrical response, but reduced the ACh-induced responses. 5. Inclusion of inositol 1,4,5-trisphosphate (IP3) in the intracellular pipette solution activated outward currents at -50 mV associated with an increase in conductance. The IP3-induced current response reversed polarity at -65 mV and showed a dependence on K+. Increasing the intracellular free Ca2+ concentration ([Ca2+]i) from 20 nM to 1 microM also induced an outward current response associated with an increase in conductance. Inclusion of inositol 1,3,4,5-tetrakisphosphate (IP4) in the intracellular solution had no effect on the A9 L cells. 6. Fura-2 measurements revealed ACh-induced increases in Cai2+. The Ca2+ responses were abolished by atropine showing that they were muscarinic in nature. Removal of extracellular Ca2+ did not affect the initial ACh-induced increase in Cai2+ but subsequent Cai2+ responses to ACh were depressed, suggesting depletion of Ca2+ intracellular stores. Residual though small responses continued to be elicited by ACh. Barium (5 mM) had little effect and cobalt slightly reduced the ACh-induced Ca2+ response. 7. The ACh-induced currents recorded at -50 mV were unaffected by removal of extracellular Ca2+.(ABSTRACT TRUNCATED AT 400 WORDS)

The 5HT2 receptor defines a family of structurally distinct but functionally conserved serotonin receptors

Serotonin exerts its diverse physiological effects by interacting with multiple distinct receptor subtypes. We have isolated a rat brain 5HT2 serotonin receptor cDNA by virtue of its homology with the 5HT1c receptor. The 5HT2 receptor is a member of the family of receptors that are linked to guanine nucleotide-binding proteins and are predicted to span the lipid bilayer seven times. Overall sequence identity between the 5HT2 and 5HT1c receptors is 49%, but identity within the transmembrane domains is 80%. Expression of both the 5HT2 and 5HT1c receptors in transfected mouse fibroblasts activates phospholipase C signaling pathways and promotes cellular transformation. However, RNA blotting shows that these two receptor subtypes are differentially expressed in the central nervous system. In this manner, structurally and functionally homologous receptor subtypes may elicit distinct physiologic actions.

Electrophysiological actions of luteinizing hormone-releasing hormone: intracellular studies in the rat hippocampal slice preparation

The electrophysiological effects of luteinizing hormone-releasing hormone (LHRH) on CA1 pyramidal cells were investigated utilizing intracellular recordings from the in vitro rat hippocampal slice preparation. Bath application of LHRH (10(-7) - 10(-12) M) resulted in several changes in the electrophysiological properties of CA1 neurons. LHRH induced a long-lasting depolarization associated with increased input resistance, a decrease in the afterhyperpolarization (AHP) following a train of action potentials, and a reduction in accommodation of repetitive cell discharge. These effects were blocked by the synthetic LHRH antagonist [Ac-delta-Pro1,pCl-D-Phe2,D-Trp3,6]-LHRH. These findings provide electrophysiological evidence for the role of LHRH as a neurotransmitter/neuromodulator in the hippocampus.

Somatostatin-14 and somatostatin-28 inhibit calcium currents in rat neocortical neurons

The prosomatostatin-derived peptides, somatostatin-14 and somatostatin-28, are believed to function as neurotransmitters or neuromodulators in the cerebral cortex. To investigate the molecular mechanisms by which these peptides induce their physiological effects in the cerebral cortex, we have examined the effects of somatostatin-14 and somatostatin-28 on voltage-dependent Ca2+ currents in rat neocortical neurons in culture. Ca2+ currents were recorded using whole-cell patch-clamp techniques under conditions in which K+ and Na+ currents were blocked. Ca2+ currents were induced by depolarization from the holding potential of -80 mV. Somatostatin-14 (100 nM) and somatostatin-28 (100 nM) did not significantly affect low-voltage activated Ca2+ currents, but blocked high-voltage activated Ca2+ currents and slowed the activation of this current. The effects of both peptides were concentration-dependent and reversible. Furthermore, the effects of somatostatin-14 and somatostatin-28 on the high-voltage activated Ca2+ currents were not additive, suggesting that both peptides regulate this ionic current through similar cellular mechanisms. When patch pipettes used to record the Ca2+ currents contained 100 microM cAMP and 0.5 mM isobutylmethylxanthine, a phosphodiesterase inhibitor, somatostatin-14 and somatostatin-28 still inhibited Ca2+ currents, indicating that the effects of these peptides on the Ca2+ currents were cAMP-independent. Inclusion of the non-hydrolysable guanine triphosphate analogue, guanine triphos-somatostatin-14 or somatostatin-28, suggesting the involvement of guanine nucleotide binding proteins in the actions of the peptides on the Ca2+ currents.(ABSTRACT TRUNCATED AT 250 WORDS)

Acetylcholine modifies neuronal acoustic rate-level functions in guinea pig auditory cortex by an action at muscarinic receptors

Cholinergic modification of neuronal responsiveness in auditory cortex includes alteration of spontaneous and tone-evoked neuronal discharge. Previously it was suggested that the effects of acetylcholine (ACh) and muscarinic agonists on neuronal discharge resembled those due to increases in the intensity of acoustic stimuli (Ashe et al. 1989). To determine the relationship between neuronal modifications due to ACh acting at muscarinic receptors and those due to changes in stimulus intensity, we determined acoustic rate-level functions for neurons in the auditory cortex of barbiturate-anesthetized guinea pigs before, during and after administration of ACh. ACh facilitated acoustic rate-level functions in 82% of the cells tested. In addition, during ACh administration 66% of neurons responded to stimuli that were previously subthreshold, that is, ACh decreased the response threshold. Cholinergic facilitation of rate-level functions was attenuated by the general muscarinic antagonist atropine. The nature of the muscarinic receptors involved in the actions of ACh was further examined by presenting single tones before, during, and after administration of ACh and specific muscarinic receptor subtype antagonists, either pirenzepine (M1) or gallamine (M2). ACh-induced facilitation of spontaneous and tone evoked neuronal discharge was antagonized by pirenzepine, but not by gallamine, suggesting the involvement of the M1 muscarinic receptor subtype. These data indicate that ACh can facilitate stimulus-evoked responses and decrease response thresholds for neurons in auditory cortex, possibly via activation of M1 muscarinic receptors. Such effects of ACh acting at muscarinic receptors could underly cholinergic regulation of information processing in the auditory cortex.

Synaptic connections of dentate granule cells and hilar neurons: results of paired intracellular recordings and intracellular horseradish peroxidase injections

Simultaneous intracellular recordings were made in the dentate gyrus of rat hippocampal slices, from pairs of the following cell types: granule cells, interneurons located in the granule cell layer, hilar interneurons, and spiny hilar "mossy cells". Granule cells were found to have strong excitatory effects on mossy cells and interneurons. Interneurons inhibited granule cells as well as other interneurons. No synaptic connections from mossy cells onto other cell types were found, within the confines of the slice, using intracellular recording methods. However, at the ultrastructural level, axon terminals of horseradish peroxidase-filled mossy cells were found making synaptic contacts in the hilus on dendrites of interneurons. These studies provide the first step towards determining the functional interactions of the various cell types in the fascia dentata.

Muscarinic receptor activation attenuates D2 dopamine receptor mediated inhibition of acetylcholine release in rat striatum: indications for a common signal transduction pathway

In the present investigations, we used a superfusion system to study the effect of simultaneous activation of D2 dopamine receptors and so-called muscarinic "autoreceptors" on the K(+)-evoked in vitro release of [3H]acetylcholine from rat striatal tissue slices. Activation of D2 receptors with the selective agonist LY 171555 (0.01-1 microM) clearly decreased the evoked release of [3H]acetylcholine. This effect was markedly attenuated in the presence of either the selective muscarinic receptor agonist oxotremorine (3 microM) or the cholinesterase inhibitor physostigmine (1 microM). Conversely, D2 receptor activation with LY 171555 (1 microM) completely abolished the muscarinic receptor mediated inhibition of evoked [3H]acetylcholine release induced by oxotremorine (0.03-10 microM). These results show that the inhibitory effects of D2 dopamine receptor and muscarinic receptor activation on striatal acetylcholine release are non-additive and therefore are interdependent processes. In addition, we investigated some aspects of the signal transduction mechanism by which the muscarinic receptor mediates inhibition of K(+)-evoked in vitro release of [3H]acetylcholine from rat striatal tissue slices. It appeared that the effect of muscarinic receptor activation was not significantly influenced either by a lowering of the extracellular Ca2+ concentration from the usual 1.2-0.12 mM or by an increase of the intracellular cyclic adenosine-3',5'-monophosphate content. However, increasing extracellular K+ strongly decreased the inhibition of evoked [3H]acetylcholine release mediated by activation of muscarinic receptors. This set of results indicates that the muscarinic "autoreceptor" mediates the decrease of depolarization induced [3H]acetylcholine release from rat striatum to a large extent through stimulation of K+ efflux (opening of K+ channels) in a cyclic adenosine-3',5'-monophosphate independent manner.(ABSTRACT TRUNCATED AT 250 WORDS)

GABA-receptors in peripheral tissues

Gamma-aminobutyric acid (GABA) and its receptors are found in a wide range of peripheral tissues, including parts of the peripheral nervous system, endocrines, and non-neural tissues such as smooth muscle and the female reproductive system. In all these, both GABAA- and GABAB-receptor types are found, with good evidence for a physiological role in the gut, pancreatic islets and the urinary bladder. In some tissues, the pharmacology of GABA-induced actions is quite atypical and should be further explored with the newer ligands and modulators for GABAA- and GABAB-receptors.

Potassium currents in hippocampal pyramidal cells

The hippocampal pyramidal cells provide an example of how multiple potassium (K) currents co-exist and function in central mammalian neurones. The data come from CA1 and CA3 neurones in hippocampal slices, cell cultures and acutely dissociated cells from rats and guinea-pigs. Six voltage- or calcium(Ca)-dependent K currents have so far been described in CA1 pyramidal cells in slices. Four of them (IA, ID, IK, IM) are activated by depolarization alone; the two others (IC, IAHP) are activated by voltage-dependent influx of Ca ions (IC may be both Ca- and voltage-gated). In addition, a transient Ca-dependent K current (ICT) has been described in certain preparations, but it is not yet clear whether it is distinct from IC and IA. (1) IA activates fast (within 10 ms) and inactivates rapidly (time constant typically 15-50 ms) at potentials positive to -60 mV; it probably contributes to early spike-repolarization, it can delay the first spike for about 0.1 s, and may regulate repetitive firing. (2) ID activates within about 20 ms but inactivates slowly (seconds) below the spike threshold (-90 to -60 mV), causing a long delay (0.5-5 s) in the onset of firing. Due to its slow recovery from inactivation (seconds), separate depolarizing inputs can be "integrated". ID probably also participates in spike repolarization. (3) IK activates slowly (time constant, tau, 20-60 ms) in response to depolarizations positive to -40 mV and inactivates (tau about 5s) at -80 to -40 mV; it probably participates in spike repolarization. (4) IM activates slowly (tau about 50 ms) positive to -60 mV and does not inactivate; it tends to attenuate excitatory inputs, it reduces the firing rate during maintained depolarization (adaptation) and contributes to the medium after-hyperpolarization (mAHP); IM is suppressed by acetylcholine (via muscarinic receptors), but may be enhanced by somatostatin. (5) IC is activated by influx of Ca ions during the action potential and is thought to cause the final spike repolarization and the fast AHP (although ICT may be involved). Like IM, it also contributes to the medium AHP and early adaptation. It differs from IAHP by being sensitive to tetraethylammonium (TEA, 1 mM), but insensitive to noradrenaline and muscarine. Large-conductance (BK; about 200 pS) Ca-activated K channels, which may mediate IC, have been recorded. (6) IAHP is slowly activated by Ca-influx during action potentials, causing spike-frequency adaptation and the slow AHP. Thus, IAHP exerts a strong negative feedback control of discharge activity.(ABSTRACT TRUNCATED AT 400 WORDS)

Neuromodulatory effects of corticotropin releasing factor on cerebellar Purkinje cells: an in vivo study in the cat

Corticotropin releasing factor, a 41 amino acid peptide, has been localized in climbing fibers and mossy fibers in the cat's cerebellar cortex. In the present study, corticotropin releasing factor was iontophoretically applied to Purkinje cells, isolated extracellularly, to assess the effect of this peptide on the firing rate of the neuron. By itself corticotropin releasing factor had little or no effect on cellular activity. However, this peptide potentiated the excitatory effects of aspartate and glutamate, the putative neurotransmitters of the climbing fiber and mossy fiber-parallel fiber systems, respectively. In addition, corticotropin releasing factor blocked the suppressive effects induced by the iontophoretic application of GABA. Finally, it shortened or eliminated the period of suppression produced by activation of climbing fibers in the cerebellar cortex. These data suggest that corticotropin releasing factor functions as a neuromodulator rather than as a neurotransmitter in cerebellar circuitry.

Cholinergic modulation of responses to single tones produces tone-specific receptive field alterations in cat auditory cortex

Acetylcholine (ACh), acting via muscarinic receptors, is known to modulate neuronal responsiveness in primary sensory neocortex. The administration of ACh to cortical neurons facilitates or suppresses responses to sensory stimuli, and these effects can endure well beyond the period of ACh application. In the present study, we sought to determine whether ACh produces a general change in sensory information processing, or whether it can specifically alter the processing of sensory stimuli with which it was "paired". To answer this question, we restricted acoustic stimulation in the presence of ACh to a single frequency, and determined single neuron frequency receptive fields in primary auditory cortex before and after this pairing. During its administration, ACh produced mostly facilitatory effects on spontaneous activity and on responses to the single frequency tone. Examination of frequency receptive fields after ACh administration revealed receptive field modifications in 56% of the cells. In half of these cases, the receptive field alterations were highly specific to the frequency of the tone previously paired with ACh. Thus ACh can produce stimulus-specific modulation of auditory information processing. An additional and unexpected finding was that the type of modulation during ACh administration did not predict the type of receptive field modulation observed after ACh administration; this may be related to the physiological "context" of the same stimulus in two different conditions. The implications of these findings for learning-induced plasticity in the auditory cortex is discussed.

Block of GABAb-activated K+ conductance by kainate and quisqualate in rat CA3 hippocampal pyramidal neurones

Current and voltage-clamp techniques were used to study the effects of kainic (KA) and quisqualic (quis) acids on the slow synaptic inhibition evoked by mossy fibre stimulation in CA3 hippocampal pyramidal neurones in vitro. The K+ conductance underlying the slow synaptic inhibition is coupled to a gamma-aminobutyric acid b (GABAb) receptor by a guanosine-triphosphate (GTP)-binding protein. Both KA and quis reduce (after 7-10 min) the slow inhibitory post-synaptic current (IPSC) without changing the reversal potential. They also reduce the cellular response to exogenously applied (-)baclofen and 5-hydroxytryptamine, which are known to activate a similar K+ conductance. We conclude that KA and quis block the post-synaptic K+ conductance underlying the slow IPSC.

The role of receptor subtype diversity in the CNS

The molecular characterization of neuroreceptors and voltage-gated ion channels has revealed that receptor subtype heterogeneity is a common feature of chemical and electrical signal reception. The use of distinct genes encoding receptor subtypes is a favoured mechanism for generation of this diversity. We propose that the significance of the multiplicity and diversity of signal reception proteins is to increase the information-handling capacity of neurons. This may contribute to neural plasticity.

GABAA receptor function is regulated by phosphorylation in acutely dissociated guinea-pig hippocampal neurones

1. Current mediated by GABAA receptors was examined in pyramidal cells acutely dissociated from the hippocampus of mature guinea-pigs. Current responses were measured using whole-cell voltage-clamp recordings. An internal perfusion technique was used to change the intracellular contents during recording. 2. Application of GABA (100-300 microM) by short duration pressure pulses produced outward current responses at a holding potential of -10 mV. When recordings were made with intracellular solutions which did not contain Mg-ATP, GABA responses progressively decreased to less than 10% of their initial values after 10 min. This 'run-down' of the GABA response could not be accounted for by desensitization since the rate of run-down was not dependent upon agonist application. 3. The run-down of the GABAA response was reversed when Mg2+ (4 mM) and ATP (2 mM) were introduced into the intracellular perfusate. In addition to the presence of Mg-ATP, buffering of Ca2+ in the intracellular solution to low levels (approximately 10(-8) M) was also necessary to stabilize the GABAA response. 4. The role of a phosphorylation process in regulating the GABAA receptor was tested. After the GABA response stabilized, introduction of alkaline phosphatase (100 micrograms/ml) to the intracellular perfusate caused a complete run-down of the GABA response. 5. Stable GABA responses were obtained when ATP was replaced by ATP-gamma-S (adenosine 5'-O-(thiotriphosphate), an analogue of ATP that donates a thiophosphate group resulting in a product that is more resistant to hydrolysis. Following such treatment GABA responses declined more slowly after the introduction of intracellular alkaline phosphatase. 6. Run-down of GABA responses accelerated when intracellular Ca2+ concentration ([Ca2+]i) was elevated to about 5 x 10(-4) M. The run-down caused by elevated [Ca2+]i could be stopped and reversed by reducing [Ca2+]i to about 10(-8) M. 7. The introduction of ATP-gamma-S to the intracellular medium retarded the run-down of GABA responses caused by elevation of [Ca2+]i. 8. N-(6-Aminohexyl)-5-chloro-1-naphthalenesulphonamide (W-7), a calmodulin inhibitor, reduced the rate of run-down induced by elevated [Ca2+]i. 9. These results suggest that the function of the GABAA receptor is maintained by phosphorylation of the receptor or some closely associated regulatory molecule. Elevation of [Ca2+]i destabilizes the function of the GABAA receptor, probably by activating a Ca2+/calmodulin-dependent phosphatase.

Tonic activation of NMDA receptors by ambient glutamate enhances excitability of neurons

Voltage clamp recordings and noise analysis from pyramidal cells in hippocampal slices indicate that N-methyl-D-aspartate (NMDA) receptors are tonically active. On the basis of the known concentration of glutamate in the extracellular fluid, this tonic action is likely caused by the ambient glutamate level. NMDA receptors are voltage-sensitive, thus background activation of these receptors imparts a regenerative electrical property to pyramidal cells, which facilitates the coupling between dendritic excitatory synaptic input and somatic action potential discharge in these neurons.

Convergence and divergence of neurotransmitter action in human cerebral cortex

The postsynaptic actions of acetylcholine, adenosine, gamma-aminobutyric acid, histamine, norepinephrine, and serotonin were analyzed in human cortical pyramidal cells maintained in vitro. The actions of these six putative neurotransmitters converged onto three distinct potassium currents. Application of acetylcholine, histamine, norepinephrine, or serotonin all increased spiking by reducing spike-frequency adaptation, in part by reducing the current that underlies the slow after hyperpolarization. In addition, application of muscarinic receptor agonists to all neurons or of serotonin to middle-layer cells substantially reduced or blocked the M-current (a K+ current that is voltage and time dependent). Inhibition of neuronal firing was elicited by adenosine, baclofen (a gamma-aminobutyric acid type B receptor agonist), or serotonin and appeared to be due to an increase in the same potassium current by all three agents. These data reveal that individual neuronal currents in the human cerebral cortex are under the control of several putative neurotransmitters and that each neurotransmitter may exhibit more than one postsynaptic action. The specific anatomical connections of these various neurotransmitter systems, as well as their heterogeneous distribution of postsynaptic receptors and responses, allows each to make a specific contribution to the modulation of cortical activity.

Effects of glucocorticoids and norepinephrine on the excitability in the hippocampus

The CA1 pyramidal neurons in the hippocampus contain a high density of adrenal corticosteroid receptors. By intracellular recording, CA1 neurons in slices from adrenalectomized rats have been found to display a markedly reduced afterhyperpolarization (that is, the hyperpolarizing phase after a brief depolarizing current pulse) when compared with their sham controls. No differences were found for other tested membrane properties. Brief exposure of hippocampal slices from adrenalectomized rats to glucocorticoid agonists, 30 to 90 minutes before recording, greatly enhanced the afterhyperpolarization. In addition, glucocorticoids attenuated the norepinephrine-induced blockade of action potential accommodation in CA1 neurons. The findings indicate that glucocorticoids can reduce transmitter-evoked excitability in the hippocampus, presumably via a receptor-mediated genomic action.

Presynaptic inhibition by neuropeptide Y and baclofen in hippocampus: insensitivity to pertussis toxin treatment

Neuropeptide Y (NPY) presynaptically inhibits excitatory transmission in area CA1 of rat hippocampus. As postsynaptic NPY receptors in certain other tissues have been shown to be coupled to G-proteins, we have tested the hypothesis that the hippocampal NPY effects are also mediated by G-proteins. Pretreatment of rats with pertussis toxin (PTX) was ineffective in blocking NPY's presynaptic inhibitory actions in area CA1 of the hippocampal slice. The presynaptic inhibitory action of baclofen was also unaffected by PTX pretreatment. However, in these same PTX-pretreated slices, the postsynaptic hyperpolarizing actions of baclofen and 5-hydroxytryptamine were blocked. We suggest that pre- and postsynaptic receptors possess different coupling mechanisms to their effectors.

A G Protein Mediates the Inhibition of the Voltage-Dependent Potassium M Current by Muscarine, LHRH, Substance P and UTP in Bullfrog Sympathetic Neurons

The involvement of G proteins in the transduction mechanism of M current (Im) inhibition by extracellular ligands in bullfrog sympathetic neurons was examined using the hydrolysis resistant nucleotide analogues GTPgammaS and GDPbetaS. Im was recorded in large (40 - 60 microm) isolated neurons using the patch-clamp technique in the whole-cell configuration, as well as in neurons from the intact ganglion impaled with conventional microelectrodes. In whole-cell recordings Im could be recorded without significant loss for 1 h or more provided ATP was present in the patch pipette. Muscarine, D-Ala6-LHRH, substance P and UTP reversibly inhibited Im in isolated control neurons, with full and rapid recovery of the current following agonist washout. Dialysis of isolated neurons with various concentrations of GTPgammaS (1 - 100 microM) affected, in a dose-dependent manner, the recovery of Im after its inhibition by brief agonist application. With 50 microM GTPgammaS, Im inhibition became completely irreversible. Similarly, the reversibility of Im inhibition by muscarine was reduced or abolished by the iontophoretic injection of GTPgammaS through a second microelectrode into neurons of the intact ganglion. GTPgammaS by itself caused a slow, agonist-independent suppression of Im in dialysed neurons, thus mimicking agonist action. Dialysis of isolated neurons with GDPbetaS (100 - 500 microM) attenuated by half or more the magnitude of Im inhibition by agonist as compared to control neurons. In addition, GDPbetaS attenuated the response of a given neuron to muscarine and D-Ala6-LHRH, and caused slow increase of Im, as a function of dialysis time. Incubation (2 - 72 h, 4 - 36 degrees C) of isolated neurons or intact ganglions with activated pertussis toxin had no effect on the response to muscarine. Toxin injections to experimental animals were equally ineffective. In contrast to Im, the additional inward current with increase in conductance induced by muscarine and D-Ala6-LHRH reversed with agonist washout in GTPgammaS-dialysed neurons, although more slowly than in control neurons. The results in this study indicate that a G protein, possibly pertussis toxin-insensitive, provides a common coupling step linking muscarinic, substance P, D-Ala6-LHRH and UTP receptors to the inhibition of M current.

Effects of dihydropyridine calcium channel ligands on rat brain gamma-aminobutyric acidB receptors

This study shows that low nanomolar concentrations of the calcium channel antagonist nifedipine displaced [3H]baclofen labeling of gamma-aminobutyric acidB (GABAB) receptors, whereas similar concentrations of two calcium channel agonists stimulated this GABAB receptor labeling. Neither effect was likely to be due to dihydropyridine (DHP) binding to baclofen recognition sites, because the inhibitory ligand nifedipine primarily affected apparent receptor density rather than affinity. Although these results could reflect the coupling of GABAB receptors with calcium channels, they do not rule out other, possibly more direct interactions between GABAB receptors and DHP binding sites. These DHP effects occur at much lower concentrations and display other significant differences from previously reported effects of DHPs on other transmitter receptors.

Noradrenaline and serotonin selectively modulate thalamic burst firing by enhancing a hyperpolarization-activated cation current

Neurons in many regions of the mammalian nervous system generate action potentials in two distinct modes: rhythmic oscillations in which spikes cluster together in a cyclical manner, and single spike firing in which action potentials occur relatively independently of one another. Which mode of action potential generation a neuron displays often varies with the behavioural state of the animal. For example, the shift from slow-wave sleep to waking and attentiveness is associated with a change in thalamic neurons from rhythmic burst firing to repetitive single spike activity, and a greatly increased responsiveness to excitatory synaptic inputs. This marked change in firing pattern and excitability is controlled in part by ascending noradrenergic and serotonergic inputs from the brainstem, although the cellular mechanisms of this effect have remained largely unknown. Here we report that noradrenaline and serotonin enhance a mixed Na+/K+ current which is activated by hyperpolarization (Ih) and that this enhancement may be mediated by increases in intracellular concentration of cyclic AMP. This novel action of noradrenaline and serotonin reduces the ability of thalamic neurons to generate rhythmic burst firing and promotes a state of excitability that is conducive to the thalamocortical synaptic processing associated with cognition.

Different GTP-binding proteins mediate regulation of calcium channels by acetylcholine and noradrenaline in rat sympathetic neurons

In dissociated neurons of rat superior cervical ganglion (SCG), noradrenaline (NA) and acetylcholine (ACh) suppressed Ca2+ currents elicited by depolarizations to 0 mV from -60 mV. With GTP-gamma-S in patch electrodes, ACh and NA caused persistent inhibition of Ca2+ currents. Pretreatment of SCG cells with pertussis toxin abolished the action of ACh but not of NA. The results suggest that ACh and NA reduce the Ca2+ currents in SCG cells through different G proteins.

Role of ion channels and intraterminal calcium homeostasis in the action of deltamethrin at presynaptic nerve terminals

Using a continuous perfusion system, synaptosomes prepared from rat brain released [3H]norepinephrine in a Ca2+-dependent manner when pulse depolarized by briefly elevating external potassium concentrations. Tetrodotoxin (10(-7) M), a sodium channel blocker, inhibited 48% of this pulsed release, and D595 (10(-5) M), a phenethylamine-type calcium channel blocker, inhibited 21%. In combination, these two specific ion channel antagonists appear to function independently of each other in an additive fashion. Addition of deltamethrin to this preparation resulted in an enhanced release of [3H]norepinephrine which occurred in a biphasic fashion. At 10(-7) M, deltamethrin produced a 42% enhancement in the first or initial peak of [3H]norepinephrine release and a 100% enhancement in the second or tailing peak. Addition of deltamethrin to tetrodotoxin-pretreated synaptosomes resulted in a net 37% enhancement of the initial peak release and a net increase of 277% in the tailing peak. Addition of deltamethrin to D595-pretreated synaptosomes produced no significant effect on enhanced [3H]norepinephrine release from either peak. Since tetrodotoxin is a specific sodium channel blocker, deltamethrin may be enhancing [3H]norepinephrine release by increasing the uptake of Ca2 via other voltage-gated channels (e.g. calcium) or exchange mechanisms in addition to its action at voltage-gated sodium channels. To determine whether deltamethrin may also have an effect on intraterminal Ca2+ homeostasis, external Ca2+ was replaced with Ba2+ and synaptosomes were depolarized with pentylenetetrazole (PTZ). At 10(-5) M, deltamethrin produced a 66% increase in neurotransmitter release over that produced by PTZ alone. An estimated EC50 value of deltamethrin for PTZ-induced release was calculated to be 2.4 x 10(-10) M.