The action of norepinephrine in the rat hippocampus. I. Iontophoretic studies

Evidence for a cyclic GMP mechanism in the mediation of hippocampal post-tetanic potentiation

Correlative electrophysiological and biochemical techniques were used to study hippocampal post-tetanic potentiation in acutely prepared rabbits following stimulation of the medial septal region and contralateral hippocampal field CA3. The results indicate that calcium ions, guanosine-3':5'-monophosphate, and phosphodiesterase inhibitors selectively enhanced the duration of post-tetanic potentiation. Potassium ions selectively enhanced tetanic potentiation. Adenosine-3':5'-cyclic monophosphate suppressed both tetanic and post-tetanic potentiation. The electrophysiological findings were supported by biochemical observations that guanosine-3':5'-monophosphate levels show marked increases following tetanic stimulation of either the medial septal region or contralateral hippocampal field CA3 pathways. The data suggest that a calcium-dependent process in the presence of a guanosine-3':5'-monophosphate mechanism promotes periods of hippocampal pyramidal cell hyperexcitability. The mechanism by which the cyclic nucleotide alters potentiation does not appear to be coupled to a single receptor variety.

Effects of norepinephrine and serotonin upon spontaneous activity and responses to mossy fiber stimulation of CA3 neurons in hippocampal slices

Effects of norepinephrine (NE) and 5-hydroxytryptamine (5-HT) upon spontaneous activity and responses to mossy fiber stimulation (mfs) were tested in 192 units of the field CA3 in the guinea pig and rat hippocampal slices. The drugs were added to the incubating medium or ejected by pressure from a micropipette. After NE superfusion firing rate increased in 52% of the reactive units, while activity of 48% was suppressed. The direction of the effect strongly correlated with pattern of spontaneous activity: only the cells with 'complex discharges' (short bursts of 2-4 spikes with attenuation of amplitude) were suppressed by NE; the cells with single spikes increased the level of activity. Similar excitatory effects of NE were observed in all units (n = 14) with single spike activity recorded in the field CA1. 5-HT increased activity in 30% of the reactive units and suppressed it in 70% of them. Some of the cells which were suppressed by 5-HT, were excited by NE. In more than a half of the units tested, 5-HT led to prolonged (up to 30-40 min) increase of the level of background activity irrespective of the initial excitatory or suppressive action; periodic grouped discharges appeared in some units under the influence of 5-HT. The response to mfs usually changed in the same direction as the level of background activity during application of NE and 5-HT, though some exceptions were observed in both cases. Prolonged (up to 30-40 min) facilitation of responses to mfs was present after application of 5-HT.

Single cell responses in cat visual cortex to visual stimulation during iontophoresis of noradrenaline

We studied how iontophoresis of noradrenaline (NA) changes responsiveness of individual cells in the feline visual cortex when their visual receptive fields are stimulated with the appropriate visual stimulus. We found three populations of cortical cells which either increased, decreased or did not change their visual responsiveness during NA iontophoresis. About equal numbers of cells belonged to each of these three groups. In the majority of such cells that changed visual responsiveness during NA iontophoresis and that had measureable amounts of spontaneous activity, the ratio of visually evoked to spontaneous activity (signal-to-noise ratio) improved during NA iontophoresis. This improvement was independent of the direction of changes in the response magnitude to visual stimulation. There was a differential effect of NA on simple and complex visual cortical cells: Although most simple cells (86%) clearly changed their responsiveness during NA iontophoresis, the effects were seen in only one-third of complex cells. Furthermore, the effects on complex cells were usually weak compared to those typically seen in simple cells. In some cases the effects of NA were more complicated than an overall enhancement of suppression of the cortical cell's responses to visual stimulation. The possible dual role of NA in the visual cortex is briefly discussed.

Locus coeruleus lesions and resistance to extinction of a classically conditioned response: involvement of the neocortex and hippocampus

Bilateral electrolytic lesions of the locus coeruleus were made in rabbits prior to classical conditioning of the nictitating membrane (NM) response. After recovery, the animals received one session of unpaired training followed by 3 days of paired acquisition training and 4 days of unpaired training (extinction). At the end of extinction norepinephrine (NE) and dopamine (DA) levels were measured in several brain regions. Each lesioned animal was placed into one of two groups according to whether or not the animal exhibited a significant depletion of cortical/hippocampal NE. A third group was formed by non-lesioned controls. There were no significant differences between the 3 groups during acquisition; however, during days 3 and 4 of unpaired extinction the group with cortical/hippocampal NE depletion showed significantly larger NM responses on the conditioned stimulus-alone trials than either of the two control groups. This extinction deficit appeared mainly in the unconditioned stimulus-period component of the tone-alone conditioned responses. The magnitude of the extinction deficit was highly correlated with the depletion of NE in both cortical and hippocampal samples but not with the depletion of NE in the hypothalamus/mid-thalamus, or cerebellum.

Relationships between norepinephrine and cyclic nucleotides in brain and seizure activity

To characterize further the roles of norepinephrine (NE) and cyclic nucleotides in seizure mechanisms, an examination was made of the effects of several drugs purported to depress noradrenergic influence in the CNS on pentylenetetrazol-induced seizure activity and regulation of cyclic AMP levels in the cerebral cortex and hippocampus in mice. Depletion of brain stores of NE with reserpine or treatment of neonatal mice with 6-hydroxy-dopamine decreased seizure latency and/or threshold and diminished seizure-induced accumulation of cyclic AMP in brain. Propranolol, a beta-adrenergic receptor antagonist, and yohimbine, an alpha 2-adrenergic receptor antagonist, had effects qualitatively similar to reserpine and 6-hydroxy-dopamine, but phentolamine, a mixed alpha-adrenergic antagonist, increased seizure threshold and latency and did not reduce the accumulation of cyclic AMP. None of the drugs tested had any consistent effect on the regulation of cyclic GMP levels in brain during seizures. These data are consistent with the hypothesis that cyclic AMP in brain may be mediating an inhibitory influence of NE on seizure activity.

Periodic bursting activities of locus coerulleus neurons in the rat

Unit activity of locus coeruleus (LC) neurons in rats was investigated. After the animal recovered from anesthesia, the spontaneous activity exhibited periodic bursting discharges at about 15-30 s intervals. The oscillation was observed to last for a long time (1-3 h). It is suggested that many LC neurons exhibited the oscillation synchronously during stress in the awake animal.

Hippocampal noradrenergic responses in vivo and in vitro. Characterization of alpha and beta components

Pressure ejection of l-norepinephrine (NE) in the in vivo rat hippocampus generally produced depression of pyramidal cell spontaneous activity. In addition, both excitation and biphasic responses were observed. NE-induced inhibition of firing rate was effectively antagonized by concurrent administration of the alpha antagonist phentolamine, but was largely unaltered by the beta antagonist timolol. On the other hand, NE-induced elevation in spontaneous firing rate was effectively blocked by timolol, and largely unaffected by phentolamine. Another beta antagonist, sotalol, did not selectively antagonize either NE-induced inhibition or NE-induced excitation. The beta agonist 2-fluoro-NE produced increases in pyramidal cell firing rates in most cells studied, while the alpha agonist 6-fluoro-NE inhibited the majority of cells examined. The effects of sotalol were also examined on alpha and beta receptor-mediated field responses in the in vitro hippocampal slice. Sotalol was shown to be a selective beta antagonist in this system, blocking excitation evoked by the beta agonist isoproterenol while having no effect on inhibition elicited by the alpha agonist clonidine; however, the potency of sotalol (Ki = 3.5 microM) was considerably less than that of timolol (Ki = 50 nM). Taken together, these results suggest that NE-induced depression and elevation in hippocampal pyramidal cell spontaneous discharge in vivo are mediated via alpha and beta adrenoceptors, respectively.

Behavior during hippocampal microinfusions. I. Norepinephrine and diversive exploration

Adult male Sprague-Dawley rats were surgically implanted with guide cannulas in the anterodorsal hippocampal formation. After recovery from surgery they were administered bilateral infusions into the dentate gyrus of D,L-norepinephrone (NE) at the rate of 0.025 microliter/min throughout a 40-min session in a holeboard/activity apparatus. The computerized holeboard system measured the animals' locomotor activity, stimulus responsivity, and response to novelty, and permitted the reconstruction and analysis of their sequential patterns of movement. The NE infusions failed to affect overall locomotion or holepoking, although group means were slightly elevated. Rearing frequency and duration were significantly increased, as were the number of different holes poked per 5-min epoch and the amount of time in and number of entries into the center region of the holeboard. The novel object reaction of NE-infused rats, measured as the increase in poke duration into holes with novel stimuli, was indistinguishable from that of saline-infused rats. The NE-infused rats exhibited more varied, widespread spatial distributions of sequential patterns of locomotor activity. A dose of the beta-adrenergic antagonist propranolol that was minimally effective when infused by itself blocked all of NE's affects when co-infused in the same solution. Infusions of the noradrenergic releasing agent tyramine mimicked NE's actions, whereas infusions of NE's relatively inactive stereoisomer D-NE or infusions into the overlying lateral ventrical failed to do so. Histological examination of dye-infused brains and microspectrofluorimetry of NE-infused brains treated using the Falck-Hillarp technique for the formaldehyde-induced fluorescence of monoamines indicated that spread of the infusate was confined to the dentate gyrus of the anterodorsal hippocampal formation. The behavioral profile of the NE-infused rats suggests a role for the noradrenergic input to the hippocampal formation in spontaneous environmental reconnaissance and the diversification of stimulus sampling-'diversive' exploration, as opposed to the inspection or 'specific' exploration of unfamiliar stimuli.

Altered neuronal responsiveness to biogenic amines in rat cerebral cortex after serotonin denervation or depletion

To further investigate monoaminergic mechanisms in cerebral cortex, responsiveness of cortical neurons to microiontophoretic applications of serotonin (5-HT), dopamine (DA) or noradrenaline (NA) was examined in the frontoparietal region of control, 5,7-dihydroxytryptamine (5,7-DHT)- and p-chlorophenylalanine (PCPA)-treated rats anesthetized with urethane. As a rule, 100 nA applications of either one of these biogenic amines induced marked slowing or total interruption of 'spontaneous' firing overlasting the 30 s period of ejection. Given the large amounts of monoamines ejected, it could be inferred that such microiontophoretic applications produced a maximal activation of receptors. In control rats, the responses to 5-HT, DA and NA were of approximately equal duration (approximately equal to 5 min). Two to 4 weeks after denervation with 5,7-DHT, most neurons (75%) exhibited greatly prolonged responses to 5-HT (approximately equal to 14 min), and marked depressions of firing could be induced by small ejection currents (approximately equal to 2 nA) having little or no effect in the controls. In addition, 85% of the units supersensitive to 5-HT showed considerably shortened responses to DA and NA (approximately equal to 1 min). After 2-14 days of depletion with PCPA, there was no change in the responsiveness to 5-HT in spite of a 91% lowering of cortical 5-HT content equivalent to that measured after denervation. Nevertheless, responsiveness to DA and NA was again diminished in a majority (80%) of the units tested. In control or PCPA-treated rats, acute administration of the 5-HT re-uptake blocker fluoxetine increased the duration of depressions induced by 100 nA applications of 5-HT but did not enhance responsiveness to low ejection currents. This suggested that, after 5-HT denervation, the suppression of re-uptake was mainly responsible for the prolongation of 5-HT responses ('presynaptic' component of supersensitivity), whereas a modification of 5-HT receptors accounted for the greater efficacy of small doses of 5-HT ('postsynaptic' component). Responsiveness to the microiontophoretic application of phenylephrine (PHE), a noradrenergic a-agonist, was comparable with that to NA in PCPA- and 5,7-DHT-treated as well as in control rats. Therefore, the hyposensitivity to DA and NA appeared indicative of a desensitization of catecholamine receptors caused by the absence of 5-HT. Such a desensitization may be viewed as an adaptive change resulting from an increased release of endogenous DA and NA. This interpretation would in turn imply that, normally, 5-HT regulates catecholamine release in the neocortex.

Interactions of a neuroleptic drug (fluphenazine) with catecholamines in hippocampus

The interactions of fluphenazine with the electrophysiological responses to catecholamines were studied in the rat hippocampus and parietal cortex. In the in vitro hippocampal slice, changes in synaptically evoked responses induced by norepinephrine, isoproterenol and dopamine were not altered by superfusion of fluphenazine. Both alpha- and beta- components of adrenergic responses were unaffected by neuroleptic administration in this preparation. Similarly, alterations in the spontaneous firing of single hippocampal pyramidal neurons in situ to adrenergic agonists or dopamine were not affected by local fluphenazine and administration using pressure ejection through multibarreled micropipettes. In contrast, norepinephrine- or isoproterenol-induced inhibitions of parietal cortical neurons in situ were potently antagonized by fluphenazine. A similar interaction was observed from a hippocampal basket neuron. It is concluded that while fluphenazine can antagonize well-defined noradrenergic effects in some brain regions (e. g., cerebellum, cortex), this property is not generalized to all brain regions receiving noradrenergic input.

D-Amphetamine at low doses suppresses noradrenergic functions

This study examined the effects of d-amphetamine on the firing rate of hippocampal cells which had been shown to have an inhibitory, noradrenergic input from the nucleus locus coeruleus (LC). d-Amphetamine at low doses of 0.1 mg/kg i.v. or 0.5 mg/kg i.p. increased the firing rates of these cells. With higher doses of d-amphetamine, both increases and decreases in the firing rates of hippocampal cells were observed. These differential effects on the firing rate of hippocampal cells were statistically significant (x2 = 13.32, d.f. = 3, P less than 0.01). The increased firing rate of hippocampal cells produced by the low doses of d-amphetamine was blocked by a prior destruction of the LC indicating that the drug effect was mediated by LC neurons. d-Amphetamine also significantly attenuated the decrement in the firing rates of hippocampal cells produced by LC stimulation (P less than 0.01). These results suggest that low doses of d-amphetamine suppress rather than enhance the actions os norepinephrine.

Noradrenergic responses in rat hippocampus: evidence for medication by alpha and beta receptors in the in vitro slice

The effect of perfused norepinephrine (NE) on evoked potentials in CA1 of the in vitro rat hippocampus was examined. Weak and variable effects on population spike amplitude were observed, with lower doses of NE generally producing excitations and higher doses more often producing inhibitions. Clonidine, an alpha-receptor agonist, produced a dose-dependent inhibition of population spike amplitude; this inhibition was effectively antagonized by the alpha-antagonist, phentolamine. Isoproterenol (ISO), a beta-agonist, produced marked increases in population spike amplitude which could be antagonized by timolol, a beta-receptor antagonist. Phentolamine did not antagonize the excitations produced by ISO, and timolol had no effect on the inhibitions seen with clonidine. After pretreatment with either phentolamine or timolol, NE perfusion elicited robust and consistent elevations or reductions in the population spike, respectively. A potent cyclic AMP derivative, 8-p-chlorophenylthio cyclic AMP, produced large increases in population spike amplitude which appeared similar to the responses seen with beta-agonists. No changes in field EPSP amplitudes were observed with any of the drugs tested. Taken together, these results suggest that NE may interact with alpha-adrenergic receptors to decrease pyramidal cell excitability, and the beta-adrenergic receptors to increase pyramidal cell excitability; the beta-effect may involve cAMP.

Aminergic neurons: state control and plasticity in three model systems

Aminergic neurons have particular functions in many systems, and in this review their role is discussed and compared in three systems: those parts of the central nervous system controlling sleep and waking in the cut; the superior cervical ganglion: and the isolated nervous system of Aplysia. In the cat the aminergic neurons are most important in a waking state during which time external information is received, processed, and can be retrieved, and during which time habituation and sensitization occur. Aminergic neurons appear to have similar roles in state control in plasticity in both the Aplysia nervous system and the superior cervical ganglion. The striking similarities in the role of aminergic neurons in these three systems support the speculation that aminergic neurons have uniquely important roles in regulation of the plastic properties of neurons.

Cyclic AMP-generating systems in rat hippocampal slices

Properties of the norepinephrine (NE) stimulated, cAMP-generating system were studied in rat hippocampal slices. NE but not other putative neurotransmitters, caused a 3--4-fold rise in cAMP levels in the slices. All 3 main subdivisions of the hippocampus (HPC), the dentate gyrus, areas CA3 and CA1, possessed the capacity to produce cAMP. The latency to the NE stimulation of cAMP formation was about 20 sec but maximal stimulation was reached only after 5--10 min of incubation. Intrahippocampal injection of kainic acid (KA) caused a nearly complete destruction of hippocampal neurons and a marked increase in number of glial cells. NE caused a 12--15-fold rise in cAMP levels in KA-treated HPC. Compared to normal HPC where potency order of noradrenergic agonists indicated activation of a beta-1 receptor type, the pattern for the KA-treated HPC indicated the dominance of beta-2 receptors. The beta-1 antagonist, practolol, and the beta-2 antagonist, H35/25, were about equipotent in blocking the NE-stimulated cAMP formation in normal HPC. In KA-treated HPC, on the other hand, H35/25 was much more potent than practolol in inhibiting NE-stimulated cAMP formation. It is suggested that in the HPC beta-1 adrenergic receptors are primarily neuronal and beta-2 receptors, glial, and that activation of both receptor species results in activation of a cAMP-generating system.

Forebrain norepinephrine and serotonin concentrations and cardiac conditioning in normal rabbits and rabbits with septal lesions

Septal lesioned or sham operated rabbits were subjected to two days of differential Pavlovian (classical) heart rate (HR) conditioning in which tones served as the conditioned stimuli and paraorbital electric shock served as the unconditioned stimulus. After completion of training, norepinephrine (NE) and serotonin (5-HT) concentrations were determined in the hippocampus and neocortex to determine if lesion-induced amine depletion was related to changes in HR conditioned response (CR). The magnitude of the bradycardiac CR was increased by septal lesions during the initial session but during the second session. several lesioned animals revealed accelerative HR changes resulting in an attenuated HR CR in the septal damaged group. The more accelerative HR responding in the septal lesioned animals was accompanied by increased EMG activity which appeared to be related to damage to more posteroventral areas of the septum. Septal lesions produced a depletion of forebrain NE of approximately 30%, but NE concentrations did not appear to be specifically related to lesion-induced changes in the HR CR. However, both NE and 5-HT concentrations were correlated with the magnitude of the HR CR in intact, but not in lesioned, animals.

Behavioral assessment of norepinephrine and serotonin function and interaction in the hippocampal formation

Norepinephrine (NE) and serotonin (5-HT) were injected either into the dorsal or ventral hippocampal formation of rats in doses ranging from 0.005 microgram/microliter to 5.0 microgram/microliter. Behavioral reactivity was assessed by recording latency to paw lick when placed on a hot plate and magnitude of force displaced in a vertical direction to a footshock. In addition open field activity was measured. NE injections resulted in a dose-dependent increase in behavioral reactivity to the hot plate and footshock; 5-HT injections resulted in a dose-dependent decrease in behavioral reactivity to hot plate and footshock. Both NE and 5-HT injections resulted in a dose-dependent increase in open field activity. NE injections were more effective in increasing reactivity when injected into the dorsal hippocampus while 5-HT injections were more effective in decreasing behavioral reactivity when injected into the ventral hippocampus. Both NE and 5-HT were most effective in increasing open field behavior, however, when injected into the dorsal hippocampus. When NE and 5-HT were injected simultaneously they resulted in no change in behavioral reactivity as compared to saline injections. Simultaneous injections of NE and 5-HT neither enhanced nor antagonized the increase in open field activity of each amine injected alone. The results are discussed in terms of the functional significance of NE and 5-HT in the hippocampus, their modes of action and significance for understanding dorsal-ventral hippocampal differences.

Mechanisms of norepinephrine actions on hippocampal pyramidal cells in vitro

Responses of pyramidal cells to topical application of norepinephrine (NE) were studied by intracellular recording in hippocampal slices in vitro. Norepinephrine hyperpolarized CA1 cells. Simultaneously, there was a decreased response to constant hyperpolarizing and depolarizing current pulses. The number of spikes evoked by constant depolarizing pulses was reduced. Spontaneous activity, when present, was reduced or abolished. The response to depolarizing current pulses was reduced more than the response to hyperpolarizing current pulses. The reduction of the depolarizing response was minimal for the first 6-8 msec of the pulse, whereafter it increased. The effects persisted after blocking synaptic transmission with low calcium-high magnesium concentrations in the incubation fluid. We conclude that the hyperpolarization is most likely due to a conductance increase. The mechanism behind the reduced response to depolarizing current pulses is discussed.

The action of norepinephrine in the rat hippocampus: intracellular studies in the slice preparation

The ionic basis of norepinephrine (NE) action was studied with intracellular recording techniques in the rat hippocampal slice. Topical application of NE caused, in CA1 neurons, a 3-4 mV hyperpolarization associated with a 10-20% decrease in input resistance. This effect was accompanied by a decrease in spontaneous action potential discharges and, in some cells, by a reduction in EPSPs produced by stimulation of the excitatory Schaffer collateral-commissural pathway. An analysis of the voltage and concentration dependency revealed that NE may activate two different mechanisms. Experiments performed to test this hypothesis have demonstrated that a short duration hyperpolarizing action of NE was still present in a low Cl- medium. The hyperpolarizing responses to NE were absent in ouabain-treated slices and in low temperature. Cyclic AMP produced a 3-4 mV hyperpolarization associated with minimal changes in input resistance. This effect of cAMP was blocked by ouabain. IBMX potentiated responses to low concentrations of NE. It is proposed that NE activates two mechanisms; one involves activation of Cl- conductance and the other activation of a Na+-K+ pump. This latter effect might be mediated by cAMP.

Postsynaptic inhibitory actions of catecholamines and opioid peptides in the bed nucleus of the stria terminalis

Effects of catecholamines, enkephalins and related compounds on electrical activity of the bed nucleus of stria terminalis (BST) were studied in vitro on thin BST sections prepared from guinea pig brains. Norepinephrine (NE) and epinephrine (E) suppressed field potentials elicited by a single shock to the stria terminalis (ST). The effects of NE and E were mimicked by phenylephrine and blocked by phenoxybenzamine. Isoproterenol and dichloroisoproterenol were without effect. NE and E suppressed the spontaneous firing of BST neurons and discharges elicited by ST stimulation. Dopamine was a less potent depressant. [D-Ala2]-Met-enkephalinamide (EKA) suppressed the field potentials and spike discharges elicited by ST stimulation. Spikes occurring spontaneously or during administration of glutamate were also suppressed by EKA. The action of EKA was blocked by naloxone. Late inhibition induced by stimulation of the lateral division of the ST was blocked by naloxone in about a third of the neurons examined. These results indicate that norepinephrine suppresses the activity of BST neurons by activating postsynaptic alpha-receptors. It is also suggested that opioid peptides mediate inhibitory control of the amygdala over the BST.

The influence of some neurotransmitter agonists and antagonists on the response of hippocampal units and the cortical EEG to ethanol in the awake rat

The spontaneous activity of single unit populations in the dorsal hippocampus and the cortical EEG were monitored in the awake rat. Experiments consisted of three consecutive recording periods; a drug-free baseline period, a pretreatment period and an ethanol period. Pretreatment with doses of dopaminergic or cholinergic agonists, which produced decreases in unit rate and an awake EEG attenuated the inhibitory effect of ethanol on hippocampal unit activity and reduced the amount of high-amplitude, slow (HAS), drowsy-state activity. GABAergic and adrenergic antagonists, which increased hippocampal unit rate, did not attenuate and sometimes enhanced the ethanol-induced inhibition in firing rate but had little additional effect on the EEG. These results point to the involvment of hippocampal neurons in those behavioural aspects of ethanol intoxication mediated by activity in the neurotransmitter systems examined here.

Metabolic changes induced in rat hippocampal slices by norepinephrine

The oxidative metabolic activity of restricted regions of hippocampal slices was assessed by a continuous measurement of the fluorescence of intramitochondrial nicotinamide-adenine dinucleotide (NADH). A large increase in NADH fluorescence was triggered by substituting the oxygen supply to the slice by nitrogen gas. A large and transient increase in NADH fluorescence was also produced by superfusion of the the slice with a high (50 mM) potassium-containing medium. Addition of norepinephrine (NE) to the superfusion medium caused a propranolol-inhibited increase in NADH fluorescence. Furthermore, ouabain, which inhibits the Na-K pump, blocked the effects of NE. An analog of cyclic adenosine monophosphate (cAMP), 8-bromo cAMP, mimicked the effect of NE. Finally, effects of NE could still be produced in a kainic acid-treated hippocampus, where most neurons were previously destroyed by the drug. It is suggested that NE activates a Na-K-ATPase, that this effect might be mediated by cAMP, and that these interrelations may underly the physiological action of NE in the brain.

Septal elicitation of hippocampal theta rhythm after localized de-afferentation of serotoninergic fibers

Previous experiments using serotonin antagonists and electrolytic raphe lesions suggest that the serotonergic input to the hippocampus inhibits low frequencey (< Hz) theta rhythm in the rat, whereas experiments using raphe stimulation suggest facilitation. The present experiments employed neurotoxic lesions of the serotonergic input to the hippocampus in an attempt to reproduce the effects of systemically administered antagonists. If the septal area is stimulated at frequencies between 6 and 10 Hz in the rat, the threshold current for driving hippocampal theta is minimum at 7.7 Hz. Systemic blockage of serotonergic synapses has been shown to shift this minimum to 6.9 Hz. In the present experiments, neurotoxic lesions were made with injections of 5,7-dihydroxytryptamine into the cingulum bundle, fornix or both. The observed effect depended on the loss of serotonin in the hippocampus, rather than the site of injection, and extensive depletion shifted the minimum to 6.9 Hz. These results indicate that the fornix and cingulum serotonergic inputs to the hippocampus are functionally homogenous, at least with respect to this response; and that the effects of systemic manipulation of serotonin systems on the septal elicitation of hippocampal theta rhythm may be attributed to changes in these two inputs.

Monoaminergic denervation of the rat hippocampus: microiontophoretic studies on pre- and postsynaptic supersensitivity to norepinephrine and serotonin

The responsiveness of hippocampal CA3 pyramidal neurons to microiontophoretic applications of serotonin (5-HT), norepinephrine (NE), gamma-aminobutyric acid (GABA) and isoproterenol (ISO) was assessed in rats following 5,7-dihydroxy-tryptamine (5,7-DHT) and 6-hydroxydopamine (6-OHDA) pretreatments and bilateral locus coeruleus lesions. The intraventricular administration of 200 micrograms (free base) of 5,7-DHT and of 6-OHDA produced 89% and 93% decreases of 5-HT and NE respectively. None of these pretreatments modified the inital responsiveness to, or recovery from iontophoretic application of 5-HT. In 6-OHDA pretreated and locus-lesioned rats, the initial effectiveness of NE was not altered but its effect was markedly prolonged. However, there was no such prolongation of the effect of ISO which is not a substrate for the high affinity NE reuptake. The effect of GABA was not affected by these pretreatments. Acute pharmacological blockade of the NE reuptake with desipramine (5 mg/kg, i.p.) similarly induced a prolongation of the effect of iontophoretically applied NE, while fluoxetine (10 mg/kg, i.p.) a 5-HT reuptake blocker, failed to alter the recovery of pyramidal cells from iontophoretic application of 5-HT. It is concluded that 5-HT denervation induces neither pre- nor postsynaptic types of supersensitivity in hippocampal pyramidal cells, contrasting with the previously shown supersensitivity of ventral lateral geniculate and amygdaloid neurons following 5-HT denervation. NE denervation fails to induce a postsynaptic type of supersensitivity but leads to a marked prolongation of the response to NE indicative of a presynaptic mechanism. These results underscore the necessity for regional studies of neurotransmitters and drug action.