Noradrenaline blocks accommodation of pyramidal cell discharge in the hippocampus

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)

Membrane electrophysiology of epileptiform activity in the hippocampus

Several different types of Na+ and Ca++ channels in the membrane of neurones provide the driving force for excitation. Whilst some of these may be activated by the transmembrane voltage or ionic concentrations, others are mediated by neurotransmitters and neuromodulators. The role of these ionic mechanisms in epileptiform activity are discussed, with particular reference to the involvement of the NMDA receptor mediated channel. Multiple K+ and Cl- mediated mechanisms provide the stabilizing influence on the electrophysiological behavior of the cells. Loss or reduction in activity of one or more of these conductances may lead to the expression of epileptiform activity. The role of the extracellular concentration of K+ in burst firing of populations of cells is discussed. The examples are primarily chosen from studies of the hippocampus in animal models of epilepsy, however wherever possible experiments on human tissue have been discussed. These studies on the membrane and synaptic mechanisms that contribute to epileptiform activity provide us with the necessary insights to allow the development of new methods for controlling such activity.

Membrane currents in hippocampal neurons

This chapter reviews properties and functions of endogenous ionic currents in hippocampal neurones. Currents considered are: Na currents INa(fast) and INa(slow); Ca currents; K currents--delayed rectifier IK(DR), transient IK(A), 'delay' current IK(D) and M current IK(M); inward rectifiers IQ, IK(IR) and ICl(V); Ca-activated currents IK(Ca) (IC and IAHP), ICl(Ca) and Ication(Ca); Na-activated currents; and anoxia-induced currents.

Pharmacology of nootropics and metabolically active compounds in relation to their use in dementia

The development of effective drugs for the treatment of dementia is an important therapeutic target. Drugs which stop the progression of dementia have not been developed; however, nootropics and metabolically active compounds such as the vinca alkaloids and the ergot alkaloids as well as alkylxanthines are widely used to alleviate the symptoms. This review summarises animal studies investigating the mechanism of action of these compounds and highlights gaps in our knowledge of their pharmacology. Nootropics, such as piracetam, facilitate learning and retrieval of information and protect the brain from physical and chemical intoxication. Nootropics may produce these effects via an enhancement of acetylcholine or dopamine release; however, this postulate requires further evaluation. The pharmacology of vinca alkaloids is reviewed with particular reference to vinpocetine. This compound attenuates cognitive deficits, reduces ischaemia-induced hippocampal cell loss and increases cerebral blood flow and glucose utilisation. These effects may be induced by modulation of cyclic nucleotide levels and adenosine re-uptake inhibition. An extensively examined ergot alkaloid is co-dergocrine; this compound increases both the oxygen tension and the electrical activity of the ischaemic cerebral cortex. Alkylxanthines have a wide range of pharmacological activities, and in this review the pharmacology of pentoxifylline, propentofylline and denbufylline is contrasted with that of theophylline and caffeine. In particular, the pharmacology of propentofylline and the selective low Km cyclic AMP phosphodiesterase inhibitor denbufylline is summarised. Although more carefully controlled clinical trials in well defined patient collectives are required, present evidence suggests some therapeutic efficacy for nootropics and metabolically active compounds. Further studies to more closely evaluate their mechanism of action may lead to the development of more effective agents for the therapy of dementia.

A role for N-methyl-D-aspartate receptors in norepinephrine-induced long-lasting potentiation in the dentate gyrus

Mechanisms of action of norepinephrine (NE) on dentate gyrus granule cells were studied in rat hippocampal slices using extra- and intracellular recordings and measurements of stimulus and amino acid-induced changes in extracellular Ca2+ and K+ concentration. Bath application of NE (10-50 microM) induced long-lasting potentiation of perforant path evoked potentials, and markedly enhanced high-frequency stimulus-induced Ca2+ influx and K+ efflux, actions blocked by beta-receptor antagonists and mimicked by beta agonists. Enhanced Ca2+ influx was primarily postsynaptic, since presynaptic delta [Ca2+]o in the stratum moleculare synaptic field was not altered by NE. Interestingly, the potentiation of both ionic fluxes and evoked population potentials were antagonized by the N-methyl-D-aspartate (NMDA) receptor antagonist 2-amino-5-phosphonovalerate (APV). Furthermore, NE selectively enhanced the delta [Ca2+]o delta [K+]o and extracellular slow negative field potentials elicited by iontophoretically applied NMDA, but not those induced by the excitatory amino acid quisqualate. These results suggest that granule cell influx of Ca2+ through NMDA ionophores is enhanced by NE via beta-receptor activation. In intracellular recordings, NE depolarized granule cells (4.8 +/- 1.1 mV), and increased input resistance (RN) by 34 +/- 6.5%. These actions were also blocked by either the beta-antagonist propranolol or specific beta 1-blocker metoprolol. Moreover, the depolarization and RN increase persisted for long periods (93 +/- 12 min) after NE washout. In contrast, while NE, in the presence of APV, still depolarized granule cells and increased RN, APV made these actions quickly reversible upon NE washout (16 +/- 9 min). This suggested that NE induction of long-term, but not short-term, plasticity in the dentate gyrus requires NMDA receptor activation. NE may be enhancing granule cell firing by some combination of blockade on the late Ca2+-activated K+ conductance and depolarization of granule cells, both actions that can bring granule cells into a voltage range where NMDA receptors are more easily activated. Furthermore, NE also elicited activity-independent long-lasting depolarization and RN increases, which required functional NMDA receptors to persist.

Imipramine alters beta-adrenergic, but not serotonergic, mediated responses in rat hippocampal pyramidal cells

Imipramine, a tricyclic antidepressant, acts acutely to block the reuptake of serotonin (5-HT) and norepinephrine (NE). However, imipramine's action as an antidepressant takes several weeks to develop. This study investigated acute and chronic effects of imipramine on intracellularly-recorded responses mediated by 5-HT and beta-adrenergic receptors on pyramidal cells from area CA1 of rat hippocampal slices maintained in vitro. Addition of 10 microM imipramine in the perfusion medium sinistrally shifted the 5-HT1A concentration-response curve for membrane hyperpolarization and the 5-HT concentration-response curve for the reduction in the amplitude of the slow afterhyperpolarization (AHP) elicited by a train of action potentials. After two weeks of treatment with imipramine (10 mg/kg daily i.p. injections or s.c. osmotic mini-pumps) the responses to 5-HT were not altered. In contrast the concentration-response curve for the beta-adrenergic mediated reduction in AHP amplitude was significantly altered; there was a reduction in Emax and a log unit dextral shift in EC50. There was no change in the concentration-response curve for the beta-adrenergic mediated depolarization. These data are in agreement with previous biochemical results reporting a decrease in beta-adrenergic receptor mediated stimulation in adenylyl cyclase and down-regulation of beta-receptor in cortex and hippocampus. These findings suggest that a consequence of long-term imipramine treatment is a decrease in the augmentation of cell excitation normally produced by beta-adrenergic receptor stimulation.

Direct evidence for acute and massive norepinephrine release in the hippocampus during transient ischemia

Recent studies suggest the norepinephrine (NE) may play a regulatory role in neuronal cell death in the hippocampus after transient ischemia. However, ischemia-induced changes in extracellular NE release have not been demonstrated. In the present study, we utilized the microdialysis technique to measure extracellular NE levels in the hippocampus before, during, and after 20 min of global ischemia induced by two-vessel occlusion combined with systemic hypotension in the rat. Stable basal concentrations of extracellular NE were detected in three consecutive samples collected prior to ischemia (1.86 +/- 1.21 pmol/ml of perfusate mean +/- SEM). During ischemia, NE levels increased to 30.1 +/- 5.5 pmol/ml, representing an 18-fold increase. The levels gradually returned to baseline by 40 min of reperfusion. These results are the first to demonstrate that acute and massive extracellular release of NE occurs in the hippocampus during ischemia and early recirculation. These results support the hypothesis that the activation of the noradrenergic system may play a significant role in modulating the development of ischemic neuronal damage.

Slow synaptic inhibition in relation to frequency habituation in dentate granule cells of rat hippocampal slices

In paired pulse stimulation experiments the mechanism underlying frequency habituation of postsynaptic potentials in dentate granule cells of rat hippocampal slices was studied by measuring extra- and intracellular potentials as well as changes in extracellular calcium [( ([Ca2+]0) and potassium concentrations ([K+]0). Orthodromic stimulation of the perforant path induced in most granule cells a late, slow hyperpolarization (SH), lasting for up to 1.2 s. During the SH the membrane conductance was increased by up to 40%. The reversal potential of the SH was around -90 mV and varied with the [K+]0. Frequency habituation was seen in all cells with the SH, whereas cells which display frequency potentiation had no SH. Lowering of [Ca2+]0 reversed paired pulse induced frequency habituation into frequency potentiation at [Ca2+]0 levels where the SH disappeared. Phaclofen blocked the SH and reversed frequency habituation into frequency potentiation. Elevating [Mg2+]0 also reversed frequency habituation into frequency potentiation and reduced the SH. We conclude that the SH represents a late, slow IPSP which is responsible for frequency habituation in dentate granule cells. We noted that during repetitive stimulation the SH soon started to fade. This effect can in part be attributed to extracellular K+-accumulation as suggested by the K+-dependence of the slow IPSP and the observations of changes in [K+]0 during repetitive stimulation. This could explain why frequency habituation reverses into frequency potentiation during repetitive stimulation.

The physiological role of calcium-dependent channels

Calcium (Ca2+)-dependent channels may be classified in three broad categories, which are, respectively, selective for potassium ions, for chloride ions, and for monovalent cations. The usual action of Ca2+ is to increase the probability of opening of the channels, but examples of the reverse, Ca2+-induced inhibition of ion channels, have recently been found. Ca2+-dependent channels help to shape the action potentials of excitable cells as well as the synaptic currents of muscular and neuronal preparations. They are involved in several aspects of electrolyte transport including regulation of osmolarity in animal cells and of turgor in plant cells, electrolyte secretion in exocrine glands, fluid absorption and secretion in epithelial tissues.

In vitro electrophysiological analysis of mature rat hippocampal transplants in oculo

We have investigated the maturation of isolated rat hippocampus grafted into the anterior chamber of the eye. Electrophysiological responses from transplants were compared to those recorded from the in vitro hippocampal slice preparation. Intracellular recording demonstrated that the passive membrane characteristics of intraocular hippocampal neurons were similar to those of the CA1 pyramidal cells in the in vitro slice preparation. However, the slow after-hyperpolarization which normally follows depolarization-induced action potentials was reduced or completely absent in the intraocular transplants, and the excitatory postsynaptic potential (EPSP) evoked by local stimulation was prolonged. The duration of the EPSP was reduced by perfusion with D-aminophosphonovaleric acid (2.5-50 microM), an N-methyl-D-aspartate receptor antagonist. Normal levels of glutamate decarboxylase (a marker for gamma-aminobutyric acidergic neurons) were found in the transplants, and responses to adenosine, bicuculline, and norepinephrine were similar in the in oculo transplants and in vitro slices. The data suggest that although many properties of hippocampal neurons are intrinsically determined, other aspects of the physiology of mature hippocampus either fail to develop, or develop abnormally in the absence of external inputs in oculo.

Modification of GABAA receptor function by an analog of cyclic AMP

Chloride-dependent current responses to gamma-aminobutyric acid (GABA) were recorded from cultured rat hippocampal neurons under voltage clamp. In the presence of the membrane-permeable cyclic AMP analog, 8-bromo-cyclic AMP (8-Br-cAMP), the peak current response to GABA was reduced, although the reversal potential for the current evoked by GABA was unaltered; similar concentrations of 8-bromo-cyclic GMP did not alter the GABA response. 8-Br-cAMP also increased spontaneous activity of the neurons and blocked accommodation of firing. It is possible that the alterations in responses to GABA result from the activation of cyclic AMP-dependent protein kinase (cAMP-PK) and subsequent phosphorylation of the GABAA receptor.

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.

Serotonin-induced bistability of turtle motoneurones caused by a nifedipine-sensitive calcium plateau potential

1. The effect of serotonin on the firing properties of motoneurones was studied in transverse sections of the adult turtle spinal cord in vitro with intracellular recording techniques. 2. In normal medium, turtle motoneurones adapt from an initial high frequency to a low steady firing during a depolarizing current pulse. In the presence of serotonin (4-100 microM) motoneurones responded with accelerated firing and a frequency jump during a depolarizing current pulse followed by an after-depolarization outlasting the stimulus. From a depolarized holding potential motoneuronal activity was shifted between two stable states by brief depolarizing and hyperpolarizing current pulses. As an expression of this bistable firing behaviour, the frequency-current relation in response to a triangular current injection was counter-clockwise in serotonin while clockwise in normal medium. 3. The delay to onset of the frequency jump was shortened as the amplitude of the activation pulse was increased. From a positive holding potential the after-depolarization exceeded spike threshold and its duration increased with an increase in steady bias current. The effect of serotonin on turtle motoneurones could be blocked by methysergide (10 microM). 4. When action potentials were depressed by tetrodotoxin, a voltage-dependent, non-inactivating plateau potential, intrinsic to the motoneurone, was revealed. Activation of this voltage plateau provides the motoneurones with two stable states of firing. The apparent input resistance was 2-4-fold lower during the plateau than at rest. 5. The serotonin-induced plateau potential was Ca2+-dependent and was blocked when Ca2+ was replaced by either Co2+ (3 mM) or Mn2+ (3 mM). 6. The Ca2+ plateau was blocked by nifedipine (1-15 microM). 7. Serotonin reduced the slow after-hyperpolarization following action potentials. The change in balance between inward and outward currents seems to be sufficient to reveal the plateau response. 8. Although a small plateau response was induced by Bay K 8644 (1-15 microM), this L-channel agonist could not reproduce the pronounced effect of serotonin. 9. It is concluded that serotonin induces a Ca2+-dependent and nifedipine-sensitive plateau potential in turtle motoneurones primarily by reducing a K+-current responsible for the slow after-hyperpolarization.

Cholinergic and noradrenergic modulation of thalamocortical processing

During periods of drowsiness and synchronized sleep, thalamocortical neuronal activity is dominated by rhythmic oscillations. The shift to waking and attentiveness is associated with an abolition of these rhythms and a marked increase in neuronal responsiveness to synaptic inputs. These shifts in thalamocortical processing are controlled by ascending modulatory neurotransmitter systems of which the cholinergic and noradrenergic components play a key role. By altering the amplitude of specialized potassium currents in thalamic and cortical neurons, acetylcholine and norepinephrine can block the generation of thalamocortical rhythms and promote a state of excitability that is consistent with cognition.

Ethanol suppresses hippocampal cell firing through a calcium and cyclic AMP-sensitive mechanism

The effects of ethanol were studied intracellularly in hippocampal pyramidal cells in vitro. Ethanol, 50-100 mM, produced a marked suppression of neuronal firing. This effect was blocked by treating the cell with cyclic 3', 5'-adenosine monophosphate (cAMP) or cadmium ions. Ethanol had no effect on the after-hyperpolarizing current. It is concluded that the ethanol-induced reduction of firing rate is due to a calcium-dependent process, and modulated by cAMP.

Long-term potentiation: studies in the hippocampal slice

Long-term potentiation (LTP) is an example of activity-dependent plasticity that was discovered in the hippocampal formation. There is growing evidence that LTP not only is a useful model for mnemonic processes, but also may represent the cellular substrate for at least some kinds of learning and memory. The hippocampal slice preparation has proven exceptionally useful in pharmacological studies of possible mechanisms of LTP. A slice remains viable and stable for several hours, and known concentrations of drugs in the bathing medium can be added and then washed out. Drugs can also be applied under visual guidance from micropipettes to discrete neuronal regions, an accomplishment that is aided by the lamellar organization of the hippocampus. Electrical stimulation of the perforant path (PP) in the molecular layer of the dentate gyrus produces a monosynaptic excitatory postsynaptic potential (EPSP) and action potential, which can be recorded extracellularly as a population EPSP and population spike, respectively. Presentation of a high-frequency train (HFT; 100 Hz X 1 s) to the PP results in a long-lasting (greater than 30 min) potentiation of the maximal EPSP slope and of the population spike amplitude. Similarly, exposure of the slice to norepinephrine (e.g. 20 microM for 30 min) results in a long-lasting potentiation (LLP) of both EPSP and population spike (Stanton and Sarvey (1987) Brain Res. Bull., 18: 115). No such LLP was seen in field CA1 following NE application (Stanton and Sarvey (1985) Brain Res., 361: 276). beta-Adrenergic antagonists, such as propranolol, inhibit both LTP and NE-induced LLP in dentate (Stanton and Sarvey, J. Neurosci., 5: 2169 (1985); Stanton and Sarvey (1985) Brain Res., 361: 276). Cyclic AMP levels are increased by either an HFT or NE (Stanton and Sarvey (1985) Brain Res., 358: 343). Thus, NE, acting through a beta-receptor, appears to be both necessary and sufficient to produce long-lasting enhancement of synaptic responses. Finally, inhibitors of protein synthesis, such as emetine, also block both LTP and NE-induced LLP (Stanton and Sarvey, J. Neurosci., (1984) 4: 3080; Stanton and Sarvey (1985) Brain Res., 361: 276). The N-methyl-D-aspartate (NMDA) excitatory amino acid receptor subtype appears to play a role in a number of forms of neuronal plasticity. Bath-application of a 1 microM concentration of the NMDA antagonists D-2-amino-5-phosphonavaleric acid (AVP) or 3-((+/-)2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid (CPP) blocked both LTP and NE-induced LLP in the dentate gyrus.(ABSTRACT TRUNCATED AT 400 WORDS)

Electrophysiological responsiveness to isoproterenol in rat hippocampal slices correlates with changes in beta-adrenergic receptor density induced by chronic morphine treatment

The effects of chronic morphine treatment and morphine withdrawal on beta-adrenergic receptor density and electrophysiological responsiveness in rat hippocampus were examined. Chronic treatment of rats with morphine for 14 days resulted in a 19% increase in the number of beta-adrenergic receptors in hippocampus, as measured by the binding of the specific antagonist [3H]dihydroalprenolol (DHA). In comparison, the number of specific binding sites for [3H]DHA was decreased 27% in hippocampus in morphine-withdrawn animals, compared to saline-treated controls. These alterations in beta-adrenergic receptor density were not accompanied by a significant change in the dissociation constant (Kd) for [3H]DHA or in the inhibitory constants (Ki) for the displacement of the [3H]-antagonist by either norepinephrine or isoproterenol. Electrophysiological experiments in the in vitro hippocampal slice preparation revealed that responses to threshold as well as maximal concentrations of isoproterenol were significantly enhanced in morphine-dependent animals, compared to controls, whereas electrophysiological responsiveness to maximal concentrations of isoproterenol was decreased in slices from morphine-withdrawn rats. The results of this study indicate that beta-adrenergic receptors in hippocampus are up-regulated during the development of morphine dependence and down-regulated during opiate withdrawal. These changes in hippocampal beta-adrenergic receptor density are likely to be of functional relevance since they are manifested in a corresponding increase and decrease, respectively, in electrophysiological responsiveness to an exogenously administered beta-adrenergic receptor agonist.

Ultrastructural localization of tyrosine hydroxylase-like immunoreactivity in the rat hippocampal formation

The light and electron microscopic localization of antigenic sites for a polyclonal antiserum directed against the catecholamine synthesizing enzyme, tyrosine hydroxylase (TH), was examined in the hippocampal formation of the rat brain with a double-bridged peroxidase-antiperoxidase method. By light microscopy, the majority of varicose processes with intense TH-like immunoreactivity (LI) were contained in the hilus of the dentate gyrus (DG) and strata radiatum and lacunosum-moleculare of the CA3 region of the hippocampus. Only a few immunoreactive fibers were observed in the molecular and granule cell layers of the DG, in strata oriens and pyramidale of CA3, and in all layers of CA1. Electron microscopy confirmed that these labeled processes were primarily axons and axon terminals. Terminals with TH-LI were 0.4-1.1 micron in diameter and contained many small clear vesicles and from 0 to 3 larger dense-core vesicles. The number and types of associations formed by terminals with TH-LI were remarkably similar in the DG and hippocampus proper despite known differences in intrinsic cells and function. In both regions, the majority of terminals with TH-LI formed junctions on small (distal dendrites (52% of 112 in the DG; 67% of 116 in CA3) and dendritic spines (30% in the DG; 18% in CA3) that were both asymmetric and symmetric. In the DG, axosomatic junctions (2% of 112) were symmetric and occurred exclusively on the perikarya of granule cells, whereas junctions on large (proximal) dendrites were more numerous (16%), exhibited symmetric as well as asymmetric membrane specializations, and were of both granule (molecular layer) and nongranule (hilus) cell origin. In CA3, synaptic contacts on perikarya (5% of 116) and large (proximal) dendrites (10%) of both pyramidal cell and nonpyramidal cell origin were few and all symmetric. The distribution and types of synaptic associations formed by terminals with TH-LI in the CA1 region paralleled that seen in the CA3 region. In both the dentate and hippocampus proper, 10% of the terminals with TH-LI were observed closely apposed to unlabeled terminals that formed asymmetric synapses with dendrites and dendritic spines. In rare instances, TH-immunoreactive terminals were found in close association with the basement membrane of blood vessels, astrocytic processes, or with other unlabeled terminals not forming recognizable junctions. In addition TH-LI was occasionally detected within the cytoplasm of a minority of astrocytes.(ABSTRACT TRUNCATED AT 400 WORDS)

The transient potassium current, the A-current, is involved in spike frequency adaptation in rat amygdala neurons

The possible functional roles of the transient K+ current, IA, in basolateral amygdala (BLA) neurons were studied using a rat brain slice preparation and conventional intracellular recording techniques. Conditioning depolarization, which inactivates IA, slowed the action potential repolarization while conditioning hyperpolarization accelerated the action potential repolarization. 4-Aminopyridine (4-AP, 100 microM), a specific IA antagonist, also caused a clear delay in spike repolarization similar to the effect of conditioning depolarization suggesting that IA is involved in the action potential repolarization. When BLA neurons were excited by injecting long depolarizing current pulses (500 ms), they responded with an initial rapid discharge of action potentials which slowed or accommodated; an afterhyperpolarization (AHP) followed the depolarizing current pulses. Superfusion of 4-AP (100 microM) blocked accommodation resulting in an increase in action potential discharge in 74% (32 out of 43) neurons tested. The remaining 11 cells responded with an increased frequency of discharge of the first few action potentials. Unlike the effect of cadmium (Cd2+, 100 microM), a calcium channel blocker, 4-AP did not reduce the AHP. In the presence of norepinephrine (NE, 10 microM), a neurotransmitter which has been shown to block calcium-activated potassium conductance, 4-AP caused a further increase in the number and frequency of action potential discharge. In addition, in BLA neurons, spontaneous interictal and ictal-like events were observed at low and high concentrations of 4-AP, respectively. We conclude that IA is involved in the action potential repolarization as well as spike frequency adaptation in BLA neurons and that these actions may contribute to the convulsant effect of 4-AP.

An after-hyperpolarization of medium duration in rat hippocampal pyramidal cells

1. In hippocampal pyramidal cells, action potentials are followed by three after-hyperpolarizations (AHPs): a fast AHP (fAHP) lasting 2-5 ms, a medium AHP (mAHP) lasting 50-100 ms, and a slow AHP (sAHP) lasting more than 1 s. The mechanism underlying the mAHP was studied in CA1 cells (n = 46) in rat hippocampal slices, using injection of depolarizing current to elicit discharge. 2. The current underlying the mAHP was studied by single-electrode voltage clamp in two ways. Either the voltage clamp was activated following a burst of spikes, thus recording the early tail current underlying the mAHP (hybrid clamp), or, after blocking the spikes with tetrodotoxin, the early tail current following a depolarizing voltage clamp command (to -20 to -45 mV for 100-400 ms) was measured. In both cases, the early tail current (measured at -60 mV) showed the following characteristics: (a) it decayed exponentially with a time constant of about 50 ms; (b) it was substantially reduced by the muscarinic agonist carbachol (40-50 microM); (c) it was moderately reduced (by 20% or less) by Ca2+-free medium and Ca2+ channel blockers (Cd2+, Mn2+), which abolished the fAHP and the sAHP; (d) it was partly blocked by tetraethylammonium (TEA, 1-10 mM) both before and during Ca2+ channel blockade; (e) it was resistant to noradrenaline (5-10 microM), which blocked the sAHP, and to apamin (100 nM). 3. The mAHP itself, recorded under current clamp, showed properties corresponding to those of the early tail current. 4. Unlike the current underlying the sAHP, which was reduced and reversed by hyperpolarization, the early tail current appeared to be reduced only at potentials down to -80 mV, and to increase at more negative potentials. The early tail current and mAHP-like undershoot at hyperpolarized potentials was blocked by external Cs+, but not by carbachol, in contrast to the early tail current and mAHP at -60 mV. 5. It was concluded that two currents contribute to the mAHP: IM (a voltage-gated muscarine-sensitive K+ current) and IC (a Ca2+-dependent TEA-sensitive K+ current). TEA reduced both the IM (5 mM) and the IC (1 mM) component of the mAHP. When the cell is hyperpolarized, a third current, IQ (a Ca+-sensitive mixed Na+-K+ inward current activated by hyperpolarization), masks the reversal of the mAHP by causing a depolarizing sag which resembles the decay of the mAHP.

Age-related alterations in noradrenergic input to the hippocampal formation: structural and functional studies in intraocular transplants

Intrinsic versus extrinsic determinants of age-related alterations in hippocampal noradrenergic transmission were investigated using intraocular allografts in rats. Three groups of animals were examined: young hippocampal transplants in young hosts, old transplants in old hosts and young transplants in old hosts. Postsynaptic sensitivity to noradrenaline (NA) was measured by extracellular recordings of spontaneous activity and superfusion with known concentrations of catecholamines in the anterior chamber of the eye. Hill plots demonstrated that the dose-response relationships of NA-induced depressions were linear and parallel in the 3 groups. Aged hippocampal grafts displayed a highly significant subsensitivity to NA of one order of magnitude. The EC50 for this group was 203.1 microM as compared to 29.2 in young grafts. Young intraocular grafts in old hosts responded similarly to transplants in young hosts, with an EC50 of 32.4 microM for the depressant actions of NA. Collaterals of the host iris sympathetic ground plexus invaded the hippocampal grafts. The density of this noradrenergic innervation was estimated by immunohistochemistry for tyrosine hydroxylase. A slightly increased density and fluorescence intensity of the noradrenergic fibers were observed in the old transplants as compared to the young transplants in young and old hosts. This was correlated with a significantly (P less than 0.01) increased content of NA in old transplants, as measured with high performance liquid chromatography. The old transplants also contained a large number of autofluorescent lipofuchsin granules, which were absent in the young transplants, regardless of the recipient age. Taken together, these results suggest the existence of alterations in pre- as well as postsynaptic noradrenergic mechanisms in the aging hippocampus. These changes were dependent on transplant age rather than host age, thus suggesting an involvement of intrinsic rather than extrinsic determinants in this model system.

Down-regulation of norepinephrine sensitivity after induction of long-term neuronal plasticity (kindling) in the rat dentate gyrus

Actions of norepinephrine (NE) in the dentate gyrus were examined before and after kindling-induced epilepsy, neuronal plasticity produced by daily high-frequency stimulation. NE, acting on beta 1-receptors, depolarized granule cells, increased input resistance, firing and influx of Ca2+ in response to repetitive stimulation, and elicited long-lasting potentiation of synaptic potentials. In addition, NE acting via alpha 1-receptors, attenuated Ca2+-dependent regenerative potentials. After kindling-induced plasticity, there were marked reductions in all these effects of NE on granule cells, changes likely to influence kindling-induced seizures, protecting against further enhancement of excitability once plasticity is in place.

Modulatory actions of serotonin on ionic conductances of hippocampal dentate granule cells

Pressure ejection of serotonin (2 x 10(-4) M) onto dentate granule neurons in vitro produced a short-lasting membrane hyperpolarization associated with a 10-30% decrease in the input resistance. The hyperpolarization magnitude depended on the extracellular K+ concentration but not on the extra or intracellular Ca2+ concentration. It was followed by a depolarization, especially when serotonin was applied onto the perisomatic area of the neuron. The post-spike-train afterhyperpolarization, which represents a Ca2+-dependent K+ conductance, was decreased by serotonin by 10-100% and remained reduced for 2-10 min following the serotonin-induced hyperpolarization. Decreased adaptation of cell firing was also observed following serotonin application. Ca2+ action potentials evoked by intracellular depolarizing current pulses in the presence of the Na+ channel blocker tetrodotoxin and the K+ channel blocker tetraethylammonium were followed by a large afterhyperpolarization, which was markedly reduced for several minutes following serotonin application. The preceding Ca2+ action potential was either unaffected or prolonged. The hyperpolarization occurring in response to localized application of serotonin, and the reduction of the afterhyperpolarization, may represent two different mechanisms of serotonin action, probably mediated by different mechanisms. The slow time course of the late depolarization and the afterhyperpolarization depression represent modulatory effects of serotonin on dentate granule neurons.

Mechanisms underlying the serotonergic modulation of the spinal circuitry for locomotion in lamprey

The central nervous system of the lamprey contains serotonergic (5-hydroxytryptamine, 5-HT) neurones both in the spinal cord and in the brainstem. Endogenously released 5-HT from these systems modulates the pattern of fictive locomotion induced in the in vitro preparation; the burst rate is lowered and burst discharges become longer and of higher intensity. Local application of 5-HT, mimicking activation of the 5-HT systems, has a specific effect on the late phase of the afterhyperpolarization (AHP) in motoneurones and interneurones. 5-HT markedly reduces the amplitude of the late AHP without affecting passive membrane properties or the shape or threshold of the action potential. This 5-HT effect appears to result from a direct action on the calcium-dependent potassium channels underlying the late phase of the AHP. A reduction of the amplitude of the AHP will result in altered spike discharge characteristics, with potentiation of the response (discharge rate) to a given excitatory input in all neurones influenced by 5-HT. It is suggested that the modulatory effect of 5-HT on fictive locomotion can be attributed to its action on the late AHP and thereby to the potentiation of excitability in excitatory and inhibitory interneurones in the generator circuitry. This has been further corroborated in computer simulation studies of a network model, where the action of 5-HT was simulated by decreasing AHP amplitude, resulting in a slowing of the rhythm analogous to the effect demonstrated experimentally.

The role of muscarinic acetylcholine receptors in ocular dominance plasticity

During a critical period of postnatal development neuronal connections in the visual cortex are susceptible to experience-dependent modifications. In normally reared kittens the majority of neurons respond to visual stimulation of either eye. A few days of monocular deprivation, however, are sufficient to render most cortical neurons unresponsive to visual stimuli presented to the deprived eye. Among other factors the cholinergic projection to striate cortex has been identified as having a permissive role in this use-dependent modification of synaptic transmission. In order to analyze further the influence of acetylcholine in cortical plasticity, we tested whether the blockade of muscarinic or nicotinic receptors interfered with ocular dominance plasticity. At four weeks of age kittens had one eyelid sutured closed and osmotic minipumps implanted, which delivered scopolamine (1 nmol/h) or hexamethonium (1 or 10 nmol/h) into the striate cortex of one hemisphere and vehicle solution (saline) into the other. After one week, ocular dominance distributions were determined in area 17 with single unit recording. In the control hemispheres, most neurons became unresponsive to the deprived eye, while in the scopolamine-treated hemispheres most neurons remained binocular. In contrast to the effects of scopolamine, the intracortical infusion of hexamethonium had no effect on ocular dominance plasticity. These results demonstrate that blockade of muscarinic, but not nicotinic receptors renders kitten striate cortex resistant to the effects of monocular deprivation.

Organotypic Co-Cultures of Rat Locus Coeruleus and Hippocampus

Slices from the brainstem at the level of the locus coeruleus and from the hippocampus of 5 - 7 day old rats were co-cultured using the roller tube technique. After 2 - 6 weeks in vitro the co-cultures were examined with antibodies raised against tyrosine-hydroxylase (TH). The cultures derived from the brainstem consistently contained a bilateral cluster of TH-positive neurons with 3 - 5 long slender dendrites. These neurons typically gave rise to several fine varicose fibres reminiscent of catecholaminergic axons. A morphologically distinct group of TH-positive neurons was detected in the hippocampal slices. The vast majority of them were located in the subicular region and a smaller number in the CA1/CA3 region of the hippocampal explant. TH-positive neurons were also present in mono-cultures of hippocampus or brainstem. In the vast majority of co-cultures, a variable number of TH-immunoreactive fibres of neurons derived from the locus coeruleus grew over considerable distances to terminate finally within the co-cultured hippocampus where they branched to form a diffuse innervation plexus with club-like endings. Even after several weeks in vitro, TH-positive fibres could still be seen exploring sites which were not related to their target, including the cell-free areas surrounding the cultures. Fibres in these outgrowth areas formed whirl-like endings. TH-positive fibres arising from neurons located in the hippocampus, on the other hand, did not branch extensively and never projected over long distances. Nerve growth factor had no apparent trophic effect on TH-positive cells in the hippocampus, the locus coeruleus, or in the co-cultures.

Synaptic and non-synaptic mechanisms underlying low calcium bursts in the in vitro hippocampal slice

1. The epileptiform activity generated by lowering extracellular [Ca++] was studied in the CA1 subfield of rat hippocampal slices maintained "in vitro" at 32 degrees C. Extracellular and intracellular recordings were performed with NaCl and KCl filled microelectrodes. 2. Synaptic potentials evoked by stimulation of the stratum radiatum and alveus were blocked upon perfusion with artificial cerebrospinal fluid (ACSF) containing 0.2 mM Ca++, 4 mM Mg++. Blockade of synaptic potentials was accompanied by the appearance of synchronous field bursts which either occurred spontaneously or could be induced by stimulation of the alveus. 3. Both spontaneous and stimulus-induced low Ca++ bursts recorded extracellularly in stratum pyramidale consisted of a negative potential shift with superimposed population spikes. This extracellular event was closely associated with intracellularly recorded action potentials rising from a prolonged depolarization shift. Steady hyperpolarization of the cell membrane potential decreased the amplitude of the depolarizing shift suggesting that synaptic conductance were not involved in the genesis of the low Ca++ burst. 4. Spontaneous depolarizing inhibitory potentials recorded in normal ACSF with KCl filled microelectrodes were reduced in size in low Ca++ ACSF. However, small amplitude potentials could still be observed at a time when low CA++ bursts were generated by hippocampal CA1 pyramidal neurons. 5. Bicuculline methiodide, an antagonist of gamma-aminobutyric acid (GABA), was capable of modifying the frequency of occurrence and the shape of synchronous field bursts. The effects evoked by bicuculline methiodide were, however, not observed when 81-100% of NaCl was replaced with Na-Methylsulphate.(ABSTRACT TRUNCATED AT 250 WORDS)

THA increases action potential duration of central histamine neurons in vitro

Long-term administration of 9-amino-1,2,3,4-tetrahydroacridine (THA) has been reported to produce marked clinical improvement in patients suffering from Alzheimer's disease. The dramatic enhancement of cognitive function seen with THA contrasts sharply with the modest improvements seen with other forms of anticholinesterase therapy, suggesting that additional mechanisms might play a role in its therapeutic efficacy. When applied to hypothalamic histamine neurons maintained in vitro, THA produced a dose-dependent increase in action potential duration. By its effect upon action potential duration, THA may increase release of transmitter from the axon terminals of cortically projecting aminergic neurons which have been shown to degenerate in Alzheimer's disease. Thus, the therapeutic efficacy of THA may derive from a combination of its anticholinesterase activity and its effects upon the duration of action potentials of aminergic neurons.

AHP reductions in rabbit hippocampal neurons during conditioning correlate with acquisition of the learned response

Young adult male albino rabbits were conditioned using a free field auditory conditioned stimulus (CS) and periorbital shock unconditioned stimulus (US) in a short delay eye blink paradigm. All rabbits received two 80-trial training sessions. Intracellular recordings were made from hippocampal CA1 pyramidal neurons within brain slices prepared 24 h following the second training session. All 46 CA1 neurons included in the analysis had stable penetration, at least 70 mV impulse amplitudes and at least 40 M omega input resistance. Recording and initial data analysis were done 'blind' regarding behavioral training performance of the rabbit from which the slices were prepared. The animals were separated into a High (86 +/- 6% CRs, n = 12), and Low (12 +/- 4% CRs, n = 10) Acquisition group based on the number of blink CRs shown on the second training day (P less than 0.001). CA1 pyramidal neurons from the High Acquisition group (n = 20) showed a significant reduction in the afterhypolarization (AHP) response following 4 impulses elicited by intracellular current injection as compared to neurons from the Low Acquisition group (n = 26). The mean maximal AHP amplitudes after 4 spikes were -2.9 +/- 0.34 mV and -4.0 +/- 0.31 mV, respectively, in the High and Low Acquisition groups (P less than 0.01). The size of the AHP examined at 100 ms intervals during the first 1.7 s after the current pulse proved to be reduced in the High group both when evaluated for all points (F = 5.88, df = 1.44, P less than 0.02) and for each of the individual time points (at least P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacological induction of use-dependent receptive field modifications in the visual cortex

Lasting modifications of the receptive fields of neurons in the visual cortex can be induced by pairing visual stimuli with iontophoretic application of the neuromodulators acetylcholine and noradrenaline or the excitatory amino acids N-methyl-D-aspartate (NMDA) and L-glutamate. The modifications are obtained in less than 1 hour and persist for more than 40 minutes. Thus, acetylcholine and norepinephrine have a permissive role in use-dependent neuronal plasticity. These results support the notion of a postsynaptic threshold for neuronal malleability that differs from that of sodium-dependent action potentials.

The neurophysiology of aging: insights from new applications of old techniques

There is a regrettable paucity of data on the neurophysiology of aging, particularly single unit electrophysiologic research. The present paper is a commentary on reviews of the work of three groups of investigators who have played a lead role in developing electrophysiologic correlates of brain aging.

Phorbol esters and thyroliberin have distinct actions regarding stimulation of prolactin secretion and activation of adenylate cyclase in rat pituitary tumour cells (GH4C1 cells)

The phorbol ester 12-O-tetradecanoyl phorbol 13-acetate (TPA) enhances the effects of TRH on phase II of prolactin secretion as well as on hormone synthesis at both low and high TPA receptor occupancy. Furthermore TPA, but not the biologically inactive substance 4 alpha-phorbol 12,13-didecanoate (4 alpha-PDD), stimulates the particulate bound adenylate cyclase with a time course paralleling that of TRH activation. However, the combined additions of TRH and TPA activate this cyclase in an additive manner while the Gpp(NH)p- and the forskolin-sensitive enzyme are unaffected by TPA addition. Polymyxin B, which inhibits protein kinase C, abolishes activation of adenylate cyclase by TPA without interfering with the stimulatory action of TRH. Also, when phosphatase activity is preferentially inhibited by pretreatment of the cells with sodium vanadate, the TRH-sensitive cyclase is unaltered, while TPA activation is obliterated. Maximal stimulation of adenylate cyclase by cholera toxin pretreatment, obliterated the actions of TRH and TPA. Cells pretreated with pertussis toxin retained their TRH-sensitive cyclase, however, TPA-responsiveness was lost. We therefore suggest that the action of TPA as it relates to activation of adenylate cyclase, is probably mediated via the Gi component of the adenylate cyclase complex, while TRH stimulates the enzyme via the classical pathway involving the stimulatory GTP binding protein (Gs).

Antagonism of the responses to isoproterenol in the rat hippocampal slice with subtype-selective antagonists

The electrophysiological and cAMP responses to the beta-adrenoceptor agonist isoproterenol were measured in the in vitro hippocampal slice preparation. Subtype-selective antagonists were used to evaluate the specificity of these responses. The beta 1-selective antagonist ICI 89,406 was 60-fold more potent than was the beta 2-selective antagonist ICI 118,551 at antagonizing the electrophysiological response. ICI 89,406 was 200 times more potent in its antagonism of the cAMP response. These results suggest that the electrophysiological and cAMP responses in this preparation are primarily mediated by beta 1-adrenoceptors.

Morphological and electrophysiological properties of a novel in vitro preparation: the electrosensory lateral line lobe brain slice

An in vitro brain slice preparation of the electrosensory lateral line lobe (ELL) of weakly electric fish was developed. The morphology of this slice was studied and revealed that most ELL neurons and synapses retained their normal appearance for at least 10 h in vitro. The electrophysiological characteristics of the main ELL output neurons, the pyramidal cells, were measured. Extracellular electrode recordings demonstrated that pyramidal cells are capable of spontaneous, rhythmic spike activity. Intracellular recordings showed that intrinsic oscillations in membrane potential underlie the bursting behavior. The majority of pyramidal cells respond to depolarizing current pulses with an initial lag in spike firing followed by a non-accommodating, higher frequency spike train. Time and voltage-dependent properties of pyramidal cell responsiveness, as well as the effects of pharmacological blocking agents indicated that rhythmic activity and repetitive firing are dominated by a persistent, subthreshold sodium conductance (gNa) which activates at depolarizing levels and is the driving force behind the membrane potential oscillations and the sustained (non-accommodating) spike firing. In addition, a transient, outward potassium conductance (gA) is responsible for the lag in spike firing by acting as a 'brake' during the initial 50-200 ms of a depolarizing stimulus. Calcium currents and calcium-dependent potassium conductance add to the interval between spontaneous bursts but appear insufficient for spike frequency accommodation. The in vitro behaviour of pyramidal cells differs substantially from the behaviour of the same cell type in vivo. These observations raise possibilities that intrinsic membrane properties together with local synaptic interactions may regulate pyramidal cell responsiveness.

Inhibitory processes in development of seizure activity in hippocampal slices

The possibility that changes in inhibitory processes are necessary for development of seizure activity was examined using guinea pig hippocampal slices. After repeated tetanic stimulation to the stratum radiatum in region CA3, seizure discharges were evoked in the stratum pyramidale by test stimuli. The latency of the seizure discharges was shortened and the duration was prolonged progressively with the number of tetanic stimulations. The latency ranged from 30 to 100 ms and it was decreased successively as the distance between the recording site and the site of tetanic stimulation was decreased. This suggests that the foci of the seizure discharges existed near the site of tetanic stimulation. In neurons within the foci, inhibitory postsynaptic potentials and the suppressing action of alveus stimulation on glutamate-induced single cell discharges remained unchanged during development of seizure activity, although excitatory postsynaptic potentials were potentiated. In addition, no marked changes were detected in the input resistance, resting membrane potential and the amplitude, threshold and afterhyperpolarization of action potentials. These results suggest that suppression of inhibitory processes do not necessary for tetanus-induced seizure activity.

Membrane properties, response to amines and to tetanic stimulation of hippocampal neurons in the genetically epileptic mutant mouse tottering

The petit-mal seizures of the "tottering" mutant mouse (tg) have been attributed to an exaggerated noradrenergic projection from locus coeruleus to the telencephalon (Noebels 1984). In order to investigate the possible epileptogenic mechanisms involved, we have compared hippocampal slices from epileptic (tg/tg) and phenotypically healthy (tg/+) mice. Resting potentials, action potentials and afterpotentials, membrane impedances and time constants were not significantly different in 11 neurons from each group. Bath application of noradrenaline, isoproterenol and histamine or a transient exposure to Mg++-free medium caused a long lasting increase in extracellularly recorded population spikes induced in CA1 by electrical stimulation of stratum radiatum. Isoproterenol blocked the calcium dependent afterhyperpolarization and accommodation of firing. Tetanization of afferent fibres evoked post-tetanic potentiation and long-term potentiation. All these results are qualitatively similar to those previously described in rats and guinea pigs and have revealed no significant difference between tg/tg and tg/+ mice.

The coupling of neurotransmitter receptors to ion channels in the brain

Recent studies on the action of neurotransmitters on hippocampal pyramidal cells indicate that different neurotransmitter receptors that use either the same or different coupling mechanisms converge onto the same ion channel. Conversely, virtually all of the neurotransmitters act on at least two distinct receptor subtypes coupled to different ion channels on the same cell. The existence of both convergence and divergence in the action of neurotransmitters results in a remarkable diversity in neuronal signaling.

Forskolin effects on the voltage-gated K+ conductance of human T cells

Forskolin, a direct activator of adenylate cyclase, modifies the voltage-dependent K+ conductance of quiescent human peripheral blood T lymphocytes. In the presence of greater than 20 microM forskolin, the average voltage-gated current in whole-cell patch clamp is significantly decreased. The voltage dependence and kinetics of activation are not changed from untreated control cells. However, inactivation becomes biphasic. Much of the current inactivates very quickly (complete in 10 ms), and the remaining outward current inactivates more slowly with a time constant closer to that of control cells. To determine whether this effect is mediated by a rise in intracellular cAMP, cells were preincubated and subsequently voltage-clamped in the presence of other agents that raise the cAMP levels in T cells (isoproterenol plus a phosphodiesterase inhibitor, or dibutyryl cAMP) with no effect on the K+ conductance. Similarly, cells put in whole-cell patch clamp with cAMP, GTP, ATP, and theophylline added to the electrode filling solution showed no change in K+ current. Because other procedures that raise cAMP did not duplicate the effect of forskolin, we investigated the effect of 1,9-dideoxyforskolin, an analogue of forskolin that does not stimulate adenylate cyclase in human lymphocytes. This drug induced changes in the whole-cell K+ conductance identical to those observed with forskolin. Both forskolin and dideoxyforskolin inhibit mitogen-induced proliferation of lymphocytes. Because inhibition of proliferation occurs in the presence of known K+ channel blockers, these results suggest that forskolin has an effect on T cell mitogenesis that is mediated by inhibition of K+ conductance and is independent of cAMP.

Inhibitory action of serotonin in CA1 hippocampal neurons in vitro

The ionic mechanism of the inhibitory effect of serotonin was investigated in vitro in the CA1 region of the rat hippocampus by extra- and intracellular recordings. Local or bath applications of serotonin induced a long-lasting reduction of extracellularly recorded synaptic potentials and orthodromic population spikes without affecting the afferent volley or the antidromic population spike. Serotonin can also reduce the frequency of occurrence of spontaneous excitatory and inhibitory postsynaptic potentials without any reduction of input resistance of the pyramidal neuron. During the response to serotonin, the conductance increase evoked by GABA, the inhibitory neurotransmitter, was not changed. A direct postsynaptic effect of serotonin was demonstrated: local or bath applications of serotonin induced a tetrodotoxin-resistant hyperpolarization and conductance increase. The conductance change was not reduced by manual clamp of the neurons to the control resting membrane potential; therefore, a possible involvement of the sodium-potassium electrogenic pump is unlikely. When neurons were loaded with chloride, serotonin could still induce a hyperpolarization with an apparent reversal more negative than the resting membrane potential. When neurons were loaded with caesium, the hyperpolarization and the conductance increase evoked by serotonin were blocked. It is therefore concluded that serotonin increases potassium permeability. Similar effects were induced by a 5-HT1A ligand. The slow after hyperpolarization was reduced by serotonin; the calcium spike was reduced at the same time. In caesium loaded neurons, the spike duration was not modified by serotonin. In the presence of extracellular caesium (4-5 mM), the serotonin-induced hyperpolarization and the conductance change were blocked, but the effect of serotonin on calcium spikes persisted. Tetraethylammonium (5-10 mM) or 4-aminopyridine (0.5 mM) had no effect on the response to serotonin. These data indicate that serotonin has a postsynaptic inhibitory action by an activating potassium conductance. The possibility of a regulation of calcium currents is discussed. The possible role of serotonin on intrinsic synaptic transmission is also discussed.

Intracellular responses of rat hippocampal granule cells in vitro to discrete applications of norepinephrine

In 75% of granule cells responsive to norepinephrine (NE), micropressure application of NE near the soma of intracellularly impaled granule cells produced membrane depolarizations. Depolarizations were associated with input resistance (Rin) increases; their amplitude increased with membrane depolarization; and had an equilibrium potential of -84 mV. The beta-adrenoceptor antagonist timolol blocked the depolarizations. In 38% of NE-sensitive granule cells, NE produced membrane hyperpolarizations. Hyperpolarizations were associated with decreases in Rin; increased with membrane depolarization; and reversed at greater than -99 mV. In some cells, in which NE was applied at different sites, both depolarizations and hyperpolarizations were observed. Both NE responses were observed in low Ca2+/high Mg2+ medium, suggesting they are due to direct postsynaptic actions of NE on granule cells.

Parallel processing of short-term memory for sensitization in Aplysia

How is the short-term memory for a single form of learning distributed among the various elements of a neuronal circuit? To answer this question, we examined the short-term memory for sensitization, using the siphon component of the defensive gill- and siphon-withdrawal reflex. We found that the memory for short-term sensitization is represented by at least four sites of circuit modification, each involving a different type of plasticity. These include (1) presynaptic facilitation of the sensory neuron connections onto both interneurons and motorneurons; (2) presynaptic inhibition at the connections of the L30 inhibitory neurons onto the excitatory interneuron L29; (3) posttetanic potentiation of the excitatory connections made by L29 onto a specific subclass of siphon motorneurons, the LFS cells; and (4) an increase in the tonic firing rate of the LFS siphon motor neurons, resulting in neuromuscular facilitation. Each of the heterosynaptic changes seems to involve a common modulatory transmitter and to utilize a common second messenger system. Moreover, each of these sites seems capable of encoding a different component of the short-term memory. Facilitation of the connections of sensory neurons should contribute to the increase in amplitude of the response; the disinhibition of the L29 interneurons and the posttetanic potentiation at L29 synapses should contribute to an increase in the duration of the response; and the increase in tonic firing of the LFS subclass of siphon motor neurons seems capable of contributing both to an increase in response amplitude and to changes in response topography.

Regeneration restores some of the altered electrical properties of axotomized bullfrog B-cells

In bullfrog B-type sympathetic neurones axon injury produces substantial changes in somal membrane properties. These include a shortening of action potential afterhyperpolarization (AHP) and an increase in action potential (AP) duration. In the present experiments we compared two injury situations: nerve crush, which was followed by regeneration, and nerve cut, after which regeneration to the original target was prevented, to investigate whether these electrophysiological changes were related to axon regeneration. Both crush and cut injuries produced a similar maximum decrease in AHP duration (to 33 and 30%) by 14 days after axotomy. After nerve crush, AHP duration recovered to within control values by 42 days, while after cut it remained depressed. AHP amplitude decreased to the same extent after nerve crush or cut (to 62 and 58%), but the rate of decrease was slower following crush when compared with cut, and following both types of injury it still remained depressed at 42 and 49 days. Changes in AP duration also took longer to occur following nerve crush, reaching maximal values at 35-42 days, at which time AHP duration had returned to within the normal range. The early reduction in AHP duration and its rapid recovery in regenerating neurones suggests that the current underlying this membrane property is regulated by events associated with axon outgrowth and peripheral reconnection. In contrast, changes in AHP amplitude and AP repolarization appeared to be independent of the occurrence of axon regeneration and remained abnormal at 49 days despite the recovery of AHP duration. These results imply that the electrophysiological changes seen in B-cells following injury are differentially regulated during subsequent regeneration.

Electrophysiological actions of norepinephrine in rat lateral hypothalamus. I. Norepinephrine-induced modulation of LH neuronal responsiveness to afferent synaptic inputs and putative neurotransmitters

The present studies were conducted as part of an ongoing investigation of the effects of norepinephrine (NE) in neuronal circuits of the mammalian brain. In this report, we describe noradrenergic actions in the lateral hypothalamus (LH), an area which has been implicated in the central integration of cardiovascular regulatory mechanisms, fluid balance and ingestive behaviors. Microiontophoretically applied NE was interacted with extracellularly recorded responses of LH neurons to iontophoretically applied putative neurotransmitters gamma-aminobutyric acid (GABA), acetylcholine (ACh) and glutamate (Glu); and activation of known input pathways from the reticular thalamus (RT) and the lateral preoptic area (LPO). Peri-event histograms of cell responses were computed before, during and after NE microiontophoresis (5-50 nA) and used to quantitatively evaluate monoamine-induced effects on spontaneous and stimulus evoked activity of LH neurons. In 16 of 23 LH neurons, RT-stimulus-induced inhibition was markedly prolonged from a mean of 28.3 +/- 4.8 ms to 44.7 +/- 5.2 ms, during iontophoretic application of NE. In 22 of 38 LH cells, LPO-stimulus-induced excitatory responses were enhanced above control levels during NE administration. In further tests, inhibitory responses of LH cells to iontophoretic pulses of GABA were potentiated during NE administration in 69% (24 of 35) of the cases tested. ACh-induced excitation was potentiated in 9 of 21 cells. In 4 of these cases, otherwise subthreshold doses of ACh caused marked increases in cell firing during the period of NE administration. By contrast, Glu-evoked excitation was antagonized by NE iontophoresis in 65.5% (17 of 26) of LH cells tested. These findings indicate that, as in other noradrenergic target regions of the CNS, NE can facilitate synaptically mediated responses of LH neurons. Taken together these observations suggest that NE may play an important regulatory role in the synaptic transfer of information within LH circuits, and consequently exert considerable influence over the homeostatic functions mediated by this structure.

Norepinephrine decreases synaptic inhibition in the rat hippocampus

The effects of norepinephrine (NE) on inhibitory synaptic potentials were studied on CA1 pyramidal neurons in the hippocampal slice in vitro. Norepinephrine caused the appearance of multiple population spikes in the CA1 region of the hippocampal slice, reminiscent of the actions of gamma-aminobutyric acid (GABA) antagonists. Intracellular recording revealed that NE causes a marked and reversible reduction in inhibitory postsynaptic potentials (IPSPs) recorded in CA1 pyramidal cells. This reduced IPSP results in a larger intracellular excitatory postsynaptic potential (EPSP), which can cause the cell to fire more than one action potential. This disinhibitory effect of NE appears to be mediated by an alpha-receptor, and occurs at a site presynaptic to the pyramidal cell, since NE does not change the reversal potential of the IPSP nor does it affect the amplitude or the reversal potential of iontophoretic GABA responses. In addition to reducing evoked IPSPs, NE causes an increase in the frequency of spontaneous IPSPs, suggesting that inhibition of interneuronal firing may not account for this disinhibitory action of NE.

Noradrenaline- and vasoactive intestinal peptide-containing neuronal systems in neocortex: functional convergence with contrasting morphology

Neurotransmitter-specific anatomical techniques have provided a tool to define the morphological constraints within which a given neurotransmitter will exert its cellular actions. Biochemical and electrophysiological approaches have revealed the nature of these cellular actions for several neurotransmitters. Furthermore, by using purified preparations and tissue cultures a certain degree of resolution has been achieved by which the cell type, where a neurotransmitter's effect takes place, can be determined. In this article we review these aspects for noradrenaline and vasoactive intestinal peptide, two neurotransmitters of the cerebral cortex contained within neuronal systems that present strikingly different morphologies. Nevertheless, noradrenaline and vasoactive intestinal peptide share certain cellular actions and can interact synergistically. The experimental evidence accumulated to date indicates that noradrenaline- and vasoactive intestinal peptide-containing neurons can influence three general cell types of the cerebral cortex, i.e. (i) other neurons, (ii) astrocytes and (iii) cells of the vasculature. This diversity in cellular partners supports the notion that noradrenaline and vasoactive intestinal peptide can be released from neurons at conventional synapses as well as at extrasynaptic sites, thus suggesting the co-existence of two modes of release within the same neuron.

Effects of behaviorally rewarding hypothalamic electrical stimulation on intracellularly recorded neuronal activity in the motor cortex of awake monkeys

Effects of hypothalamic stimulation (HS) were studied in intracellular recordings obtained from 125 neurons of the motor cortex (MC). HS that was effective in reinforcing bar-press behavior, i.e. satisfactory for intracranial self-stimulation (ICSS), evoked short-latency (less than 3 ms) activation of these cortical neurons more frequently (42% of cells tested) than did HS that was ineffective in reinforcing bar-press behavior (7% of cells tested). Longer latency activation (greater than 3 ms) and inhibition (of variable onset) also occurred, but their incidence was not significantly different when HS was effective or ineffective in producing ICSS. Effects of HS that was effective in producing ICSS were also examined in 23 cells in which the spikes were followed by afterhyperpolarization (AHP) of 1.4-10 mV amplitude and 1.7-54 ms duration. The amplitudes of AHPs of greater than 8 ms duration were reduced after presentations of HSs that were effective as a reinforcer for ICSS. These results suggest that: (1) MC neurons receive reward-related hypothalamic information through pathways sufficiently direct to produce short-latency activation; and (2) a modulation of spike afterhyperpolarization can be observed in conjunction with reception of this information.