Suppression of locomotor activity produced by acute injections of kainic acid into the median raphe nucleus

Ingestive and locomotor behaviours induced by pharmacological manipulation of <Alpha>-adrenoceptors into the median raphe nucleus

The present study evaluated the involvement of α-adrenoceptors of the median raphe nucleus (MRN) in satiated rats, in food and water intake and motor behaviour. Control groups were treated with saline (SAL) or adrenaline (ADR), injected into the MRN seven minutes after injection of the vehicle used to solubilize the antagonists, propylene glycol (PLG) or SAL. Experimental groups were treated with an α-adrenoceptor antagonist, prazosin (α1, 20 or 40 nmol) or yohimbine (α2, 20 or 40 nmol) or phentolamine (non-selective α, 20 or 40 nmol), followed (later) by injection of ADR or SAL. Behaviour was recorded for 30 min. The injection of ADR and the blockade of α1 receptors resulted in hyperphagia whereas blocking α2 or α1 and α2 simultaneously did not change feeding behaviour. Pre-treatment with prazosin, followed by injection of ADR was not able to cause an increase in the amount of food ingested, while the higher dose of the α1 antagonist reduced the latency to start feeding. Pre-treatment with prazosin also caused hyperactivity. However, pre-treatment with phentolamine or yohimbine was able to block ADR-induced feeding. The present study supports the hypothesis that there is a tonic activation of α1-adrenoceptors in the MRN in satiated rats, which activates an inhibitory influence in areas that control food intake. Injection of ADR seems to activate α2 receptors, resulting in a decrease in the availability of endogenous catecholamines, which reduces the release of the signal that inhibits food intake, leading to hyperphagia.

The median raphe nucleus in anxiety revisited

Although the role of the median raphe nucleus (MRN) in the regulation of anxiety has received less attention than that of the dorsal raphe nucleus (DRN) there is substantial evidence supporting this function. Reported results with different animal models of anxiety in rats show that whereas inactivation of serotonergic neurons in the MRN causes anxiolysis, the stimulation of the same neurons is anxiogenic. In particular, studies using the elevated T-maze comparing serotonergic interventions in the MRN and in the DRN indicate that the former affect only the inhibitory avoidance task, which has been related to generalized anxiety. In contrast, similar operations in the DRN change both the inhibitory avoidance and the one-way escape task, the latter being representative of panic disorder. Simultaneous injections of 5-HT-acting drugs in the MRN and in the dorsal hippocampus (DH) suggest that the MRN-DH pathway mediates the regulatory function of the MRN in anxiety. Overall, the results discussed in this review point to a relevant role of the MRN in the regulation of anxiety, but not panic, through the 5-HT pathway that innervates the DH.

5-HT1A receptors in the dorsal hippocampus mediate the anxiogenic effect induced by the stimulation of 5-HT neurons in the median raphe nucleus

We evaluated the involvement of dorsal hippocampus (DH) 5-HT1A receptors in the mediation of the behavioral effects caused by the pharmacological manipulation of 5-HT neurons in the median raphe nucleus (MRN). To this end, we used the rat elevated T-maze test of anxiety. The results showed that intra-DH injection of the 5-HT1A/7 agonist 8-OH-DPAT facilitated inhibitory avoidance, an anxiogenic effect, without affecting escape. Microinjection of the 5-HT1A antagonist WAY-100635 was ineffective. In the elevated T-maze, inhibitory avoidance and escape have been related to generalized anxiety and panic disorders, respectively. Intra-MRN administration of the excitatory amino acid kainic acid, which non-selectively stimulates 5-HT neurons in this brain area facilitated inhibitory avoidance and impaired escape performance, but also affected locomotion. Intra-MRN injection of WAY-100635, which has a disinhibitory effect on the activity of 5-HT neurons in this midbrain area, only facilitated inhibitory avoidance. Pre-administration of WAY-100635 into the DH blocked the behavioral effect of intra-MRN injection of WAY-100635, but not of kainic acid. These results indicate that DH 5-HT1A receptors mediate the anxiogenic effect induced by the selective stimulation of 5-HT neurons in the MRN.

Selective 5-HT receptor inhibition of glutamatergic and GABAergic synaptic activity in the rat dorsal and median raphe

The dorsal (DR) and median (MR) raphe nuclei contain 5-hydroxytryptamine (5-HT) cell bodies that give rise to the majority of the ascending 5-HT projections to the forebrain. The DR and MR have differential roles in mediating stress, anxiety and depression. Glutamate and GABA activity sculpt putative 5-HT neuronal firing and 5-HT release in a seemingly differential manner in the MR and DR, yet isolated glutamate and GABA activity within the DR and MR has not been systematically characterized. Visualized whole-cell voltage-clamp techniques were used to record excitatory and inhibitory postsynaptic currents (EPSC and IPSC) in 5-HT-containing neurons. There was a regional variation in action potential-dependent (spontaneous) and basal [miniature (m)] glutamate and GABAergic activity. mEPSC activity was greater than mIPSC activity in the DR, whereas in the MR the mIPSC activity was greater. These differences in EPSC and IPSC frequency indicate that glutamatergic and GABAergic input have distinct cytoarchitectures in the DR and MR. 5-HT(1B) receptor activation decreased mEPSC frequency in the DR and the MR, but selectively inhibited mIPSC activity only in the MR. This finding, in concert with its previously described function as an autoreceptor, suggests that 5-HT(1B) receptors influence the ascending 5-HT system through multiple mechanisms. The disparity in organization and integration of glutamatergic and GABAergic input to DR and MR neurons and their regulation by 5-HT(1B) receptors may contribute to the distinction in MR and DR regulation of forebrain regions and their differential function in the aetiology and pharmacological treatment of psychiatric disease states.

Serotonergic neurons in the median raphe nucleus regulate inhibitory avoidance but not escape behavior in the rat elevated T-maze test of anxiety

RATIONALE

A wealth of evidence supports the involvement of the serotonergic neurons of the median raphe nucleus (MRN) in anxiety. However, it is presently unclear whether serotonergic pathways arising from this nucleus play distinguishing regulatory roles in defensive behaviors that have been associated with specific subtypes of anxiety disorders.

OBJECTIVES

To evaluate the role of the MRN serotonergic neurons in the regulation of two defensive behaviors, inhibitory avoidance and escape, which have been related, respectively, to generalized anxiety and panic disorders.

METHODS

Male Wistar rats were submitted to the elevated T-maze test of anxiety after intra-MRN administration of drugs that either non-selectively or selectively change the activity of the serotonergic neurons.

RESULTS

Intra-MRN injection of FG 7142 (0.04 and 0.08 nmol) and kainic acid (0.03 and 0.06 nmol), drugs that non-selectively stimulate the MRN serotonergic neurons, facilitated inhibitory avoidance acquisition, but impaired escape performance. Microinjection of muscimol (0.11 and 0.22 nmol), a compound that non-selectively inhibits the activity of the MRN serotonergic neurons, impaired inhibitory avoidance and facilitated escape performance. Both kainic acid and muscimol also changed rat locomotion in the open-field test. Intra-MRN injection of 8-OH-DPAT (0.6-15 nmol) and WAY-100635 (0.18-0.74 nmol), respectively an agonist and an antagonist of somatodendritic 5-HT(1A) receptors located on serotonergic neurons of the MRN, only affected inhibitory avoidance-while the former inhibited the acquisition of this behavior, the latter facilitated it.

CONCLUSION

MRN serotonergic neurons seem to be selectively involved in the regulation of inhibitory avoidance in the elevated T-maze. This result supports the proposal that 5-HT pathways departing from this nucleus play an important role in anxiety processing, with implications for pathologies such as generalized anxiety disorder.

Effect of electrolytic and neurotoxic lesions of the median raphe nucleus on anxiety and stress

To study the role played by 5-HT mechanisms of the MRN, behavioural and physiological parameters were presently measured in rats having either electrolytic or 5,7-dihydroxytryptamine (5,7-DHT) lesion of the MRN made 7 days before testing. Half the animals were submitted to 2-h restraint 24 h before the test. In the elevated plus-maze, the electrolytic lesion increased the percentage of open-arm entries and of time spent on open arms - an anxiolytic effect - in both restrained and nonrestrained rats. The neurotoxic lesion had a similar effect, but only on restrained rats. Restraint had anxiogenic effect. The electrolytic lesion increased transitions between the light and dark compartments and the time spent in the bright compartment of the light-dark box in both restrained and nonrestrained rats. The neurotoxic lesion only increased bright time in restrained rats. The incidence, number and size of gastric ulcers were increased by either the electrolytic or the neurotoxic lesion in both restrained and nonrestrained animals. Both types of lesion depleted 5-HT in the hippocampus in restrained and nonrestrained rats. Restraint increased 5-HT levels. These results implicate 5-HT mechanisms of the median raphe nucleus in the regulation of anxiety and in the genesis of gastric stress ulcers.

Collateral projections from the median raphe nucleus to the medial septum and hippocampus

It has previously been shown that the median raphe nucleus (MR) is a source of pronounced projections to the septum and hippocampus. The present study examined collateral projections from MR to the medial septum (MS) and to various regions of the hippocampus. The fluorescent retrograde tracers, Fluororuby and Fluorogold, were injected into the septum and hippocampus, respectively, and the median raphe nucleus was examined for the presence of single- and double-labeled neurons. The dorsal raphe nucleus (DR) was also examined for the presence of single- and double-labeled cells and comparisons were made with the MR. The main findings were: (1) pronounced numbers of retrogradely labeled cells (approximately 50 cells/section) were present in MR with injections in the MS or in various regions of the hippocampus; (2) approximately 8-12% of MR cells were double-labeled following paired injections in the MS-CA1, MS-CA3, and MS-dentate gyrus of the dorsal hippocampus, the lateral MS-dentate gyrus, and the MS-ventral hippocampus; (3) single- and double-labeled cells were intermingled throughout MR and present in greater numbers in the rostral than caudal MR; and (4) significantly more single- and double-labeled cells were present in MR than in DR with all combinations of injections. These findings demonstrate that MR projects strongly to the MS and hippocampus, and that a significant population of MR neurons (8-12%) sends collateral projections to both sites. It is well established that the MR nucleus serves a direct role in the desynchronization of the electroencephalographic (EEG) activity of the hippocampus-or the blockade of the hippocampal theta rhythm. The MR neurons that we have identified with collateral projections to the septum and hippocampus may be critically involved in the modulation/control of the hippocampal EEG. A role for the MR in memory associated functions of the hippocampus is discussed.

Injections of excitatory amino acid antagonists into the median raphe nucleus produce hippocampal theta rhythm in the urethane-anesthetized rat

The median raphe nucleus (MR) exerts a pronounced desynchronizing influence on the hippocampal EEG. MR stimulation disrupts theta, while MR lesions produce constant uninterrupted theta. The MR receives pronounced excitatory amino acid (EAA)-containing afferents that have been implicated in several MR-mediated behaviors. The present study examined the effects on the hippocampal EEG of MR injections of the following EAA antagonists in the urethane-anesthetized rat: 2-amino-7-phosphonoheptanoate (AP-7), dizocilpine maleate (MK-801), and gamma-glutamyl-aminomethylsulfonic acid (GAMS). MR injections of the competitive (AP-7) and non-competitive (MK-801) N-methyl-D-aspartic acid (NMDA) receptor antagonists produced theta at short latencies (2.86 min; 4.02 min, respectively) and for long durations (116.1 min; 66.8 min, respectively). It was further shown that the theta-eliciting effects of AP-7 injections could be reliably and temporarily reversed with MR injections of NMDA. MR injections of the kainate/quisqualate receptor antagonist (GAMS) also produced theta at relatively short latencies (6.5 min) and for long durations (60.5 min) indicating that EAA effects on the MR are not NMDA receptor specific. Injections of each of the foregoing EAA antagonists into regions of the brainstem adjacent to the MR including the dorsal raphe nucleus and the medullary or pontine reticular formation generated theta at very long latencies or were without effect. The present findings indicate EAA afferents to the MR normally exert an excitatory influence on the MR in its desynchronization of the hippocampal EEG, whereas the removal of EAA inputs to MR produces the opposite: a reduction of MR activity and hence the elicitation of theta.(ABSTRACT TRUNCATED AT 250 WORDS)

Excitatory amino acids: implications for psychiatric disorders research

The hyperdopaminergic theory of schizophrenia may account for some types of schizophrenia, but schizophrenia with negative symptoms or resulting in a chronic state of deterioration after repeated relapses cannot be explained by this theory. This minireview first discusses the interactions between dopamine and excitatory amino acid (EAA) neurons to produce abnormal behavior. Secondly, it deals with the influence of the psychotropic drugs on EAA, such as the relationship between phencyclidine and the hypoglutamate theory, the involvement of EAA in behavioral sensitization induced by amphetamines, the interactions between antipsychotic, antidepressant and antianxiety drugs and EAA, considering the possibility of developing newer psychotropic drugs related with EAA. Finally, glutamate receptors measured in postmortem schizophrenic brains are tabulated and the bases of the hypoglutamate hypothesis are discussed.

Central neurophysiologic mechanisms of the regulation of inhibition

The neuronal populations of the cuneate nucleus of the midbrain, the medial parabrachial nucleus, the median and magnus nuclei of the raphé, the electrical and local chemical stimulation of which elicits the inhibition of the motor activity of animals, were determined in chronic experiments on freely-moving white male mongrel rats. It was established that when each of the enumerated regions of the brain are stimulated electrically in other zones which elicit motor inhibition, multineuronal responses with a latent period of less than 2.5 msec were recorded. At the same time, multidirectional bilateral changes in muscle tone of the flexors and extensors of the hind limbs are observed in sodium ethaminal anesthetized and unanesthetized animals. The electrolytic destruction of the inhibitory zones of the median raphé nucleus and raphé nucleus magnus blocks the motor inhibition elicited by electrical stimulation of the cuneate nucleus of the midbrain and the medial parabrachial nucleus.

Influence of brain stem structures on the formation of the defensive behavior of animals

The dependence of the dominant form of the defensive behavior of white male mongrel rats on the functional state of the brain stem inhibitory locomotor system has been studied in chronic experiments. It was established that the electrolytic destruction of the inhibitory zones of the cuneate nucleus of the midbrain, the medial parabrachial nucleus, the central and great nuclei of the raphé leads to the dominance of active defensive reactions in animals in confrontations with partners. The opposite effect is exerted by local injection of kainic acid into these regions of the brainstem. It is hypothesized that the functional state of the brain stem inhibitory locomotor system can exert a modulating influence on the formation of the defensive behavior of animals.

Differential behavioural activation following intra-raphe infusion of 5-HT1A receptor agonists

Microinfusion of the selective 5-HT1A receptor agonist, 8-hydroxy-(di-N-propylamino)tetralin (8-OHDPAT), into the dorsal raphe nucleus (DRN) produced a marked behavioural hypoactivity and flat body posture. Injections of similar doses into the median raphe nucleus (MRN) elicited hyperactivity but no postural change. Reductions in rearing and grooming were also observed after DRN and MRN infusions of 8-OHDPAT. The behavioural profiles of other 5-HT1A selective compounds, gepirone and BMY7378 were found to be similar to 8-OHDPAT. The contrasting behavioural profiles of the 5-HT1A agents observed after DRN or MRN microinfusions are probably related to the differential innervation of forebrain structures by each raphe nucleus. Thus, the present data confirms and extends previous results illustrating the influence of 5-HT systems on motor behaviour in the rat and identifies unique behavioural profiles following activation of the DRN and MRN.

Control of food intake by kainate/quisqualate receptors in the median raphe nucleus

In previous studies we have reported that increases in food and water intake can be produced by microinjections of both NMDA selective and broad spectrum excitatory amino acid antagonists into the median raphe nucleus (MR). In the current experiments we examined the influence of kainate/quisqualate receptors in the MR on ingestive behavior. The consumption of food and water by deprived rats could be suppressed by intra-MR microinjections of the excitatory amino acid agonists kainic acid (5-10 ng in 0.5 microliters vehicle) and quisqualic acid (125-500 ng). Conversely, intra-raphe injections of the kainate/quisqualate receptor antagonists pBB-PZDA (1.25-2.5 micrograms) and GAMS (10-20 micrograms) elicited feeding in nondeprived animals. pBB-PZDA was more potent in eliciting ingestive behavior than was the selective NMDA antagonist 2-amino-6-phosphonohexanoic acid, suggesting that the effects of pBB-PZDA were not mediated through the NMDA receptor. The current findings suggest that ingestive behaviors are tonically inhibited by excitatory amino acids acting at kainate/quisqualate receptors in the vicinity of the MR.

Contribution between dorsal and ventrolateral regions of medulla oblongata in vasomotor function of cats

In cats anesthetized with alpha-chloralose and urethane, the medulla oblongata was explored with electrical and/or chemical stimulation for vasopressor actions. Chemical stimulation included semimicroinjection of sodium glutamate or microinjection of dl-homocysteic acid (DLH). The dorsal (DM), particularly its dorsomedial (DMM) portion, and the ventrolateral (VLM) regions were found to be most sensitive to both electrical and chemical stimulation. In between these two regions there was an area in the ventral portion of the gigantocellular and the parvocellular reticular nuclei that was sensitive to electrical and somewhat sensitive also to chemical stimulation. The responses to chemical stimulation indicate the existence of perikarya in these three areas for vasopressor actions. The most active response of VLM followed microinjection of DLH into the region of nu. paragigantocellularis lateralis (PGL) and subretrofacial nu. These responses were about 30% greater than those from DM where the most active area was found in the DMM region including the nu. and tractus solitarius. When an extensive area of VLM was lesioned bilaterally with kainic acid (KA, 1 micrograms/100 nl), the resting systemic arterial blood pressure (SAP) fell 42% and the pressor response on DM stimulation fell by more than 80%. In contrast, after similar KA bilateral destruction of DM the resting SAP fell 38% and the pressor responses from 67%. When only a limited area in the PGL/subretrofacial nu. of the rostral VLM (3-4 pressor sites, 1 mm apart) on one side was lesioned, the resting SAP remained unaltered while the pressor response on the ipsilateral DMM decreased 76%. On the other hand, when a similar smaller KA lesion (3-4 sites) was made in the DMM, although the resting SAP did not change, the pressor response on stimulation of the ipsilateral rostral VLM decreased 28%. Further lesioning of the contralateral DMM then decreased the rostral VLM pressor response 62% without much alternation in the resting SAP. Results of the present experiments are in accordance with our previous results that neuronal perikarya for vasopressor action exist not only in VLM but also in DM (18,34) with the function of VLM slightly predominant over DM. It seems highly possible that reciprocal innervation exists between DM and VLM, at least between DMM and the PGL/subretrofacial nu. region.

Characterization of pretentorial periaqueductal gray matter neurons mediating intraspecific defensive behaviors in the rat by microinjections of kainic acid

Unilateral microinjections of 40 pmol of kainic acid (KA; in 0.2 microliter) within the periaqueductal gray matter (PAG) evoked intraspecific defensive postures (defensive uprights, defensive alterting, defensive sideways, backing) in rats confronted with a conspecific. These reactions, which lasted for up to 30 min, were seemingly identical to the rat's natural defensive reaction to attacks by a conspecific although they were evoked by the investigatory approach, rather than the attack, of another rat. Histological analysis revealed that the strongest defensive reactions were evoked from sites within a restricted part of the pretentorial periaqueductal gray matter. Lower doses of KA induced fewer (20 pmol) or non-significant increases (4 pmol) in defensive reactions. Higher doses (100 and 200 pmol) increased the percentage of defensive behavior and also induced oriented jumps out of the test cage. In tests with a conspecific, defensive reactions were elicited most frequently when investigation by the partner was localized to the side of the body contralateral to the injection site. This was confirmed in a sensory reactivity test in which tactile stimulation by the experimenter elicited most defensive reactions when applied on the side of the body contralateral to the injection side. This test also revealed a somatotopic gradient in the animal's reaction: tactile stimulation of the contralateral head and the forelimb evoked the strongest reactions, whereas no responses were observed upon tactile stimulation of the contralateral flank or hindlimb. Measurement of electroencephalographic activity at the cortical, hippocampal, amygdala and PAG levels indicated that the evoked defensive reactions were not secondary to epileptogenic effects. Finally, quantitative analysis of an autoradiographic study found that [3H]KA diffused within a diameter of 1.0-1.2 mm around the cannula tip. Taken together, these results indicate the existence of a population of neurons within a restricted part of the pretentorial PAG of the rat, the excitation of which produces defensive responses and demonstrate that these defensive reactions have a socially adaptive value.

Behavioral and biochemical evidence for a functional role of excitatory amino acids in the median raphe nucleus

Recent experiments have suggested the existence of excitatory amino acid (EAA)-containing afferents to the median raphe nucleus. In the present study we investigated the functional significance of EAAs in the median raphe (MR) by examining the behavioral and biochemical effects of intra-raphe injections of EAA antagonists. Injections of kynurenic acid, gamma-glutamylglycine, 2-amino-5-phosphonovaleric acid (2-APV) and 2-amino-7-phosphonoheptanoic acid (2-APH) into the median raphe resulted in marked hyperactivity. In contrast to the effect of 2-APV and 2-APH, intra-raphe injections of the homologues of these compounds with 4, 6 or 8 carbon atoms, which have a lower affinity for excitatory amino acid receptors, were without significant effects on activity. Additionally, the effects of 2-APV were shown to be stereospecific to the active D-isomer further suggesting receptor mediation of the effect. Injections of EAA antagonists into the dorsal raphe nucleus or the ventral tegmental area were much less effective in increasing activity than were injections into the MR, suggesting anatomical specificity of the effect. Injections of 2-APV into the median raphe were also shown to result in a reduction of serotonin metabolism within the hippocampus and an increase in dopamine metabolism within the nucleus accumbens and the magnitude of both of these effects was positively correlated with the behavioral responses to the injections. These findings suggest that cells within the median raphe may be subject to a tonic excitation exerted through EAA receptors.

Comparative studies of locomotor behavior following microinjections of muscimol into various sites in the paramedian tegmentum

Microinjections of various doses of muscimol into the median raphe nucleus, the dorsal raphe nucleus or the caudal portion of the ventral tegmental area elicited dose-dependent increases in locomotor activity. In contrast, injections into the rostral portion of the ventral tegmental area or the midline pontine tegmentum caudal to the median raphe were ineffective. Lower doses of muscimol were required to produce hyperactivity after injections into the median raphe than after injections into any of the other sites. These findings suggest that the median raphe nucleus is the most sensitive site in the paramedian tegmentum for the elicitation of hyperactivity by muscimol.

Limbic brain structures are important sites of kappa-opioid receptor-mediated actions in the rat: a [14C]-2-deoxyglucose study

The [1-14C]-2-deoxyglucose technique was employed to evaluate the regional pattern of alterations in glucose utilization in the rat brain, pituitary and spinal cord induced by the selective kappa-opioid agonist U-50,488H (trans-3,4-dichloro-N-methyl-N[2-(1-pyrolidinyl) cyclohexyl]-benzeneacetamide). Within the dose range used (0.5-5 mg/kg), U-50,488H produced a dose-dependent attenuation of nociceptive thresholds and a place aversion in the place conditioning test, allowing for a correlation of the regional pattern of changes in glucose utilization with certain behavioral responses. The regional changes in glucose utilization induced by U-50,488H in the brain were most pronounced in components of the limbic forebrain circuit such as the anterior thalamic nuclei, mammillary body, frontal cortex, lateral septal nucleus, nucleus accumbens and lateral habenular nucleus as well as in the brainstem tegmental nuclei and the dorsal and median raphe nucleus (components of the limbic midbrain area). Glucose utilization was decreased in the frontal cortex and increased in the other regions. An increase in glucose utilization also was observed in the central gray pons. Increases in glucose utilization in the pituitary were restricted to the intermediate lobe. In the lumbar part of the spinal cord, glucose metabolism was enhanced in the region around the central canal and in the ventral horn. The changes in glucose metabolism observed in these structures suggest that the aversive (dysphoric) effects of U-50,488H may be due to the altered activity of the limbic structures of the forebrain and midbrain which have been implicated in emotional and affective processes. The increased activity in the intermediate lobe of the pituitary, furthermore, might reflect a stress component in the effects of this drug. Since the dorsal raphe nucleus and the region of the central gray pons have been implicated in both analgesia and pain processes a supraspinal site of antinociceptive action of U-50,488H, in addition to a spinal site of action, must be considered.

Serotonin and depression: old problems and new data

1. Several lines of evidence implicating some dysfunction or alteration to brain serotonergic systems in depressive states are summarized. 2. Some aspects of the interactions between the 5-HT and catecholamine pathways in the action of antidepressant drugs are examined. 3. Finally, the important role of NA modulation of serotonergic activity in the action of antidepressants is suggested.

Is dopamine involved in the hyperactivity produced by injections of muscimol into the median raphe nucleus?

Many studies have shown that experimental manipulations of the median raphe nucleus are able to produce profound effects on locomotor activity. Other data indicate that the raphe nuclei may exert an inhibitory influence over dopamine systems projecting to the forebrain. These results raise the possibility that the median raphe's influence over locomotion may be mediated through alterations in forebrain dopamine release. We examined this possibility in the current report by studying the role of dopamine in the hyperactivity produced by microinjections of the GABA agonist muscimol into the median raphe. Muscimol injections resulted in pronounced hyperactivity which was accompanied by a decrease in serotonin metabolism within the hippocampus and an increase in dopamine metabolism within the nucleus accumbens. Systemic injections of high doses of the dopamine antagonist haloperidol, however, were not able to attenuate muscimol's effect on activity. These results suggest that dopaminergic mechanisms do not play an essential role in mediating the effects of intraraphe muscimol on locomotor activity.

Stimulation of ingestive behaviors following injections of excitatory amino acid antagonists into the median raphe nucleus

Anatomical and pharmacological evidence suggests that excitatory amino acids (EAA's) may function as neurotransmitters within the median raphe nucleus (MR). Previous studies have shown that injections of EAA antagonists into the MR result in marked hyperactivity. The current report extends these findings by demonstrating that intra-raphe injections of two EAA antagonists, kynurenic acid and 2-amino-5-phosphonovaleric acid, result in dose-dependent increases in food and water intake in nondeprived rats. These results suggest that EAA's within the MR may play a role in the control of appetitively motivated behaviors.