Interactions of norepinephrine with Purkinje cell responses to putative amino acid neurotransmitters applied by microiontophoresis

Involvement of spot 35 protein, a cerebellar protein, in modulation of Purkinje cell activity of the rat cerebellum

Spot 35 protein, applied iontophoretically, produced inhibition of spontaneous Purkinje cell activity in most cells and augmented the NE- or 5-HT-induced inhibition of spontaneous discharges whereas it hardly affected the inhibitory response of Purkinje cells to GABA, taurine, and beta-alanine, and the excitatory response to glutamate. It is suggested that spot 35 protein may be involved in normal physiological operation of the cerebellum through modulation of the NE or 5-HT system.

Dopamine attenuates the effects of GABA on single unit activity in the globus pallidus

Studies were conducted to assess whether stimulation of dopamine receptors located in the globus pallidus might play a role in mediating the enhanced pallidal activity seen after systemic administration of dopamine agonists or D-amphetamine. Dopamine, applied iontophoretically, had modest effects on the activity of pallidal neurons; the baseline firing rates of 32% of cells recorded increased by an average of 23 +/- 2%, 18% decreased in rate and the remaining cells showed no significant rate change. More significantly, dopamine consistently attenuated the inhibitory actions of gamma-aminobutyric acid (GABA) in the globus pallidus. When dopamine was simultaneously iontophoresed with GABA, GABA's effectiveness at inhibiting pallidal activity was reduced by an average of 50%. Norepinephrine or acetylcholine, applied iontophoretically at equimolar concentrations and ejected at the same current as dopamine, caused no consistent attenuation of pallidal responses to GABA's rate effects. To determine whether the attenuation of GABA's inhibitory action by iontophoresed dopamine could be mimicked by systemic drug administration, apomorphine, 80 micrograms/kg, or D-amphetamine, 0.8 mg/kg, was given i.v. while GABA was iontophoresed. Apomorphine markedly decreased pallidal responses to the inhibitory effects of GABA in 75% of the cells by an average of 50%; haloperidol reversed this effect. Modulatory interactions between GABA and D-amphetamine were also observed in 5 of the 11 pallidal cells tested; GABA's inhibitory effect on pallidal cell activity was reduced by an average of 66% on these neurons. These results suggest that one way in which dopamine and dopamine agonists may affect basal ganglia function is by modulating GABAergic transmission in the globus pallidus.

Alterations in cerebellar glutamic acid decarboxylase (GAD) activity in a genetic model of torsion dystonia (rat)

Glutamic acid decarboxylase (GAD) activity was studied in specific brain regions of a newly identified genetic (rat) model of human torsion dystonia. GAD activity was found to be significantly increased in the deep cerebellar nuclei of dystonic rats at 16, 20, and 24 days of age. GAD activity in the other regions examined (vermis, cerebellar hemispheres, caudate nucleus, and globus pallidus) did not differ from that of age-matched normal littermate controls. Diazepam treatment significantly reduced the frequency of dystonic movements in the mutant.

Norepinephrine elicits both excitatory and inhibitory responses from Purkinje cells in the in vitro rat cerebellar slice

Superfusion of Purkinje neurons in the in vitro rat cerebellar slice with norepinephrine caused increases and decreases of spontaneous Purkinje cell firing. Excitations were evoked by low concentrations of norepinephrine (0.5-10 microM) and by the beta receptor agonist isoproterenol (0.1-5 microM). These excitations were reduced by timolol (1-2 microM), a beta receptor antagonist. Perfusion with higher concentrations of norepinephrine (greater than 16 microM), caused a depression of Purkinje neuron spontaneous activity. This inhibitory response was blocked by the alpha receptor antagonist phentolamine. The alpha 1 selective agonist phenylephrine had no effect on spontaneous activity at concentrations up to 100 microM, but the alpha 2 selective agonist clonidine (1-50 microM) elicited decreases in firing rate. These responses appeared to be due to a direct action on Purkinje cells, because neither the excitation nor the depression of Purkinje neuron activity elicited by norepinephrine was substantially altered when tested in a medium which substantially blocked synaptic transmission within the slice. Under these in vitro conditions, norepinephrine appears to increase the firing rate of Purkinje neurons via an interaction with beta adrenergic receptors, while norepinephrine induced depressions may be linked to alpha adrenergic receptor interactions; both receptors appear to be located directly on the Purkinje neurons.

Ethanol-GABA interactions at the rat Purkinje cell

Single unit cerebellar Purkinje cell activity was recorded extracellularly in urethane-anaesthetised rats. An inhibition of these cells, believed to be GABA-mediated, which is produced by local surface stimulation of the cerebellar cortex was antagonized by the local, micropressure application of ethanol. The inhibition of cerebellar Purkinje cells produced by local micropressure application of GABA was similarly antagonized by a slow i.v. infusion of ethanol (1.5 g/kg over 10 min). When both ethanol and GABA were applied to the Purkinje cells by local micropressure the results were difficult to interpret due to an ethanol-induced decrease in the baseline firing rate. There was a decrease in the absolute GABA-mediated inhibition but no change in the relative inhibition. In general, it appears that ethanol produces an antagonism of GABA-mediated inhibition of cerebellar Purkinje cells.

Noradrenergic actions of Purkinje and locus coeruleus neurons in culture

Explant cultures prepared from neonatal mice were used to study the actions of iontophoretically applied noradrenaline (NA) on Purkinje and locus coeruleus neurons, with extracellular and intracellular recording respectively. NA depressed spontaneous activity of Purkinje neurons and enhanced excitatory responses to glutamate in 14/16 cells. In cultures older than 26 days, NA hyperpolarized LC neurons but had no effect on or depressed depolarizing responses to glutamate. The hyperpolarizations were blocked by the selective alpha 2 antagonist yohimbine. Enhancement of glutamate responses is not a ubiquitous characteristic of NA action and appears not to be associated with alpha 2 adrenergic receptors.

Noradrenergic action in the developing rat cerebellum: interaction between norepinephrine and gamma-aminobutyric acid applied microiontophoretically to immature Purkinje cells

In this study, we examined the action of norepinephrine (NE) on developing cerebellar Purkinje cells. Responses of immature Purkinje cells to microiontophoretically applied NE were assessed both in terms of the direct depressant effect of the catecholamine as well as its ability to interact synergistically with gamma-aminobutyric acid (GABA). Sensitivity for NE, GABA, taurine and beta-alanine was found to be present by postnatal day 3. In addition, NE enhanced inhibitory responses of Purkinje cells to GABA but not those to beta-alanine by at least postnatal day 5, before periods of extensive morphological differentiation and synaptic investment. The modulation by NE persisted into adulthood with no qualitative changes in characteristics. The results of this study support and extend the hypothesis that 'chemosensitivity' antedates synaptogenesis' to include responsiveness of developing Purkinje cells to interactions between putative cerebellar neurotransmitters.

Effects of dopamine on spontaneous and evoked activity of caudate neurons

This study examined the effects of dopamine (DA), pressure ejected from multi-barrelled micropipettes, on the spontaneous and evoked activity of caudate neurons, recorded extracellularly in rats anesthetized with urethane. Neurons were categorized according to their discharge latencies in response to supramaximal cortical stimulation: neurons which fired with latencies less than 13 msec were classified "short-latency-discharge neurons", while neurons with latencies greater than or equal to 13 msec were classified "long-latency-discharge neurons". This procedure also allowed the detection of neurons with low levels of spontaneous activity. The predominant effect of DA on both neuronal types was inhibition of spontaneous activity. However, DA exerted a modulatory effect in that spontaneous activity was inhibited at "doses" which did not affect activity evoked by cortical stimulation. Although DA-induced excitation was infrequent, it was significantly more prevalent among long-latency neurons than among short-latency-discharge neurons. Long-latency-discharge neurons were also significantly more spontaneously active than were short-latency neurons. In rats depleted of endogenous DA by treatment with reserpine, caudate neurons had significantly increased rates of spontaneous and evoked activity, shorter duration of stimulus-evoked inhibition, and longer latency for evoked discharges than in control rats. These results suggest that DA exerts modulatory effects on caudate neuronal activity. Furthermore, these results suggest that short- and long-latency-discharge neuronal groups may consist of pharmacologically, as well as physiologically, distinct neuronal types.

Locus coeruleus stimulation potentiates local inhibitory processes in rat cerebellum

We previously reported that a low threshold action of norepinephrine (NE) on the cerebellar circuitry is expressed as an amplification of the inhibitory action of gamma aminobutyric acid (GABA) on Purkinje cell activity. Here we examined the effects of locus coeruleus (LC) stimulation on "off-beam" inhibitions of Purkinje cell firing induced by activation of local basket and stellate cell interneurons to determine whether endogenous NE, released from synaptic terminals, could induce a comparable enhancement of GABA-mediated synaptic input to these neurons. Stimulation of LC, at current intensities which by themselves were subthreshold for directly affecting background activity of Purkinje neurons, markedly increased off-beam inhibitory neuronal responses. Iontophoretic application of the beta-adrenergic blocker sotalol reversibly antagonized this enhancement of synaptic inhibition. In comparison, the potentiative effects observed with LC stimulation were increased by iontophoresis of the alpha-adrenergic blocker phentolamine. LC -induced increases in off-beam inhibition were not observed after destruction of cerebellar noradrenergic terminals by 6-hydroxydopamine. These results suggest that noradrenergic input from the LC can augment the efficacy of conventional GABA-mediated inputs synapsing on the Purkinje cell.

Dopamine modulation of the effects of gamma-aminobutyric acid on substantia nigra pars reticulata neurons

Studies were conducted to assess whether basal ganglia output neurons originating in the substantia nigra pars reticulata might be affected by dopamine released from dendrites of neighboring substantia nigra pars compacta neurons. Dopamine applied by iontophoresis increased the baseline firing rates of approximately half of the substantia nigra pars reticulata cells tested. The more significant finding, unrelated to the increase in firing, was the ability of dopamine to attenuate the inhibitory responses of these cells to iontophoretically applied gamma-aminobutyric acid. These findings suggest a role for dopamine as a neuromodulator and further suggest that it can act at sites beyond the striatum to modify transmission from the basal ganglia to motor nuclei.

Cultured cerebellar neurons: endogenous and exogenous components of Purkinje cell activity and membrane response to putative transmitters

Modified explant cultures of fetal rat cerebellum were developed for electrophysiological and pharmacological studies, at the membrane level, of Purkinje neurons. The goals of the present series of experiments were to identify possible endogenous and exogenous components to the electrical activity of Purkinje neurons, to assess the sensitivity of these neurons to putative excitatory and inhibitory neurotransmitters, and to characterize the membrane response to the transmitters. Intracellular recordings were made from Purkinje neurons, identified on a morphological basis, using conventional electrophysiological techniques. Virtually all Purkinje neurons displayed spontaneous activity. A contribution of both endogenous and exogenous components to the spontaneous activity was indicated by alterations in the pattern and amount of activity when the membrane potential was varied and by the characteristics of the individual potentials themselves. Several types of activity were considered to be endogenous: the most common type consisted of pacemaker-like potentials which generated a pattern of firing similar to that characterized as simple spike activity in previous in vivo studies; another type of endogenous activity consisted of large membrane depolarizations that evoked one or two spikes. These depolarizing responses were similar to the membrane response generated by climbing fiber input to Purkinje cells in vivo. The exogenous components to the spontaneous activity consisted of synaptic potentials including excitatory (EPSPs) and inhibitory (IPSPs) synaptic potentials and biphasic EPSP/IPSPs. Several putative transmitters thought to mediate these synaptic potentials were tested by focal micropressure application to determine if they could mimic the action of the endogenous transmitters. The putative transmitter glutamate depolarized the cultured Purkinje neurons and evoked action potentials, characteristics which were displayed by the excitatory synaptic potentials. The putative inhibitory transmitter GABA hyperpolarized the cultured Purkinje neurons and depressed activity, characteristics which were displayed by the inhibitory synaptic potentials. The putative inhibitory transmitters glycine and taurine were ineffective. Norepinephrine, the transmitter mediating the inhibitory input from the locus coeruleus to Purkinje neurons, was also tested. When applied in the microM range, NE effects were variable. When applied in the mM range, NE depressed the spontaneous activity in a manner suggestive of a presynaptic action.

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.

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.

Cerebellar pathology in schizophrenia--cause or consequence?

Atrophy of the cerebellar vermal cortex has been reported to occur in 10% or more of patients with schizophrenia. Data from studies on experimental animals indicate that a functional relationship between the cerebellum and parts of the forebrain involved in emotion exists, and that the cerebellum may influence some types of behavior. Cerebellar abnormality in schizophrenic patients, although of uncertain cause, could contribute to the symptomatology of the disease.

Behavior during hippocampal microinfusions. IV. Transmitter interactions

The interaction between noradrenergic, cholinergic, and GABAergic receptor stimulation in the dentate gyrus of the rat was investigated at the behavioral level. Awake, unrestrained rats in a holeboard/activity apparatus received continuous 40-min infusions into the dentate hilus of combined solutions of norepinephrine, the cholinergic agonist carbachol, and the GABA antagonist picrotoxin. Infusions into the dentate gyrus of either carbachol or picrotoxin have been found to produce a comparable locomotor activation of rats that is probably due to the excitation of dentate granule cells. Low dose hippocampal infusions of norepinephrine have been shown to significantly affect the quality but not the quantity of the locomotor activity or rats. Co-infusion of norepinephrine potentiated the effects of picrotoxin and blocked the effects of carbachol. It is hypothesized that the noradrenergic input to the area dentata increases the efficacy of extrinsic afferents while also facilitating recurrent granule cell inhibition mediated by GABAergic interneurons.

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.

Locus coeruleus stimulation potentiates Purkinje cell responses to afferent input: the climbing fiber system

In cerebellum, the evoked responses of the Purkinje cell to both excitatory and inhibitory afferent input have previously been shown to be enhanced by local iontophoresis of norepinephrine (NE). The influence of locus coeruleus (LC) conditioning stimulation on Purkinje cell responses to climbing fiber input was examined to determine whether endogenous NE, released from synaptic terminals, could exert similar potentiative effects. Stimulation of LC, at intensities which by themselves were subthreshold for directly affecting background activity, markedly enhanced complex spike excitation of Purkinje cells elicited by activation of climbing fiber inputs from sensorimotor cortex. Depressant responses observed after complex spike excitation were also augmented by the LC conditioning. Iontophoretic application of sotalol, a specific beta-adrenergic receptor blocker, reversibly antagonized this facilitation of climbing fiber-evoked responses. In addition, the potentiative effects of LC stimulation were not observed after destruction of NE-containing axons and terminals in cerebellum by 6-OHDA. These results suggest that noradrenergic input from the LC can enhance the efficacy of climbing fiber synaptic action on the Purkinje cell, and are thus consistent with the hypothesis of a 'modulatory' role rather than a specific information transfer function for NE in cerebellum.

Evidence of facilitatory coerulospinal action in lumbar motoneurons of cats

Functional connectivity of the feline coerulospinal projection was delineated by utilizing the combined approaches of antidromic activation and electrical stimulation. We isolated 25 locus coeruleus (LC) neurons that were electrophysiologically identified and histologically verified and that could be driven by stimulating the spinal cord. Antidromicity of the spike potentials was confirmed by the constant latency, the high frequency (100 Hz) following, fractionation of the initial segment-somatodendritic potential, and collision between the antidromic and the spontaneous orthodromic spikes. The mean conduction speed was 20 +/- 8 m/sec (range = 7 to 32 m/sec). Intracellular studies revealed facilitatory LC actions in 22 lumbar motoneurons (MNs), In 13 MNs, LC activation alone produced slow-rising excitatory postsynaptic potentials (EPSPs) of 3 +/- 12 mV amplitude that lasted 4-30 msec. Six of the 13 MNs discharged action potentials upon LC stimulation. In the remaining 9 MNs, no observable potential change was registered after LC activation. Antecedent LC stimulation consistently potentiated the synaptic efficacy of testing dorsal root shocks. The enhancement of synaptic activation was antagonized by systemic injection of phenoxy-benzamine (3 mg/kg). These results suggest that facilitation of MNs by the LC is at least in part mediated by distal dendritic depolarization. Those MNs that exhibited augmented excitability but no demonstrable EPSPs may have been activated by norepinephrine-mediated synaptic modulation.

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.

Electrophysiologic interactions of antipsychotic drugs with central noradrenergic pathways

The pathway from the nucleus coeruleus to Purkinje neurons in rat cerebellar cortex was used to analyze effects of antipsychotic neuroleptic drugs on a central noradrenergic pathway. Fluphenazine and haloperidol produced a dose-dependent increase in Purkinje neuron spontaneous discharge. This effect was not seen in animals in which the noradrenergic input had been removed by the neurotoxin 6-hydroxydopamine. In contrast, the effects of neuroleptics were still present in animals which had received neonatal X-ray irradiation, which destroys intrinsic inhibitory and excitatory pathways in cerebellar cortex. Chlorpromazine produced the same increase in discharge rate, but was significantly less potent. alpha-Flupenthixol was equipotent with fluphenazine, but beta-flupenthixol, a behaviorally inactive stereoisomer, was without effect. The dose-response curves showed potencies similar to those in several animal behavioral paradigms. In addition, the rank order of potency was identical to that in clinical tests of antipsychotic activity. Three-week chronic administration of fluphenazine resulted in complete blockage of noradrenergic activity, with no further increase in Purkinje neurons spontaneous discharge rate by additional doses of drug. Thus, tolerance does not develop to the noradrenergic blocking effect of the neuroleptic. Taken together, this evidence suggests that antipsychotic neuroleptic drugs block noradrenergic neurotransmission in the CNS.

Histamine actions on activity of cultured hypothalamic neurons: evidence for mediation by H1- and H2-histamine receptors

Tuberal hypothalamic tissue cultures were used to investigate the actions of histaminergic agents on neuronal activity using extracellular glass micropipettes. Histamine and H1- and H2-agonists were applied locally onto single active neurons by iontophoresis, while histaminergic antagonists were perfused through the bathing medium. Peri-event histogram and ratemeter analysis showed histamine to both excite and depress unit activity. Excitations were only antagonized by putative H1- and not H2-histamine antagonists, whereas inhibitions were antagonized by H2- and H2-antagonists. Dimaprit, a specific H2-agonist, elicited inhibitions of activity, while 2-(2-pyridyl)ethylamine, a putative H1-agonist, elicited both excitations and inhibitions. Two pharmacologically distinct populations of histamine receptors may exit in the hypothalamus: excitatory H2-receptors and inhibitory H2-receptors.

Potentiation of GABA inhibitory action in cerebrllum by locus coeruleus stimulation

In cerebellum, excitatory and inhibitory responses of Purkinje cells, produced both synaptically and by microiontophoresis of putative amino acid neurotransmitters, have been shown previously to be enhanced during NE iontophoresis. The influence of locus coeruleus conditioning stimulation on Purkinje cell responses to GABA iontophoresis was examined to determine whether endogenous NE, released from synaptic terminals, could exert similar modulatory effects. Locus coeruleus stimulation at current intensities which alone elicited no direct depression of Purkinje cell spontaneous discharge potentiated the inhibition produced by GABA. Iontophoretic application of sotalol, a specific beta-adrenergic blocker, antagonized this enhancement of GABA inhibition. Repetitive activation of the classic non-adrenergic cerebellar afferents did not enhance the GABA response, despite causing a direct depression in spontaneous rate. A neuromodulatory role is suggested for tonic adrenergic input in the mammalian central nervous system.

GABA facilitation by noradrenaline shows supersensitivity in cerebellum after 6-hydroxydopamine

Alterations of cerebellar Purkinje cell responses to microiontophoretically applied noradrenaline (NA) were studied in rats after the destruction of NA-containing afferents and terminals by 6-hydroxydopamine (6-OHDA). An enhanced efficacy of NA action after 6-OHDA treatment was indicated by a significant reduction in the mean iontophoretic current required for a threshold depressant response to NA. A potentiation of gamma aminobutyric acid (GABA)-mediated inhibition by administration of NA, similar to that previously observed in control animals, was also reliably elicited in 6-OHDA pretreated rats. In addition, Purkinje cells appeared to demonstrate an increase in sensitivity to such facilitating actions of NA, defined here as "modulatory supersensitivity". In contrast to the prolonged synergistic interactions between NA and GABA observed in control animals, however, the enhancement of the amino acid response in 6-OHDA treated animals did not persist beyond the period of NA ejection and converted instead to a period of rebound insensitivity to GABA action. These results provide electrophysiological evidence for the emergence of supersensitivity to NA action in cerebellum after the loss of noradrenergic input from locus coeruleus.