The actions of motilin, luteinizing hormone releasing hormone, cholecystokinin, somatostatin, vasoactive intestinal peptide, and other peptides on rat cerebral cortical neurons

The effects of a number of neuronally localized peptides have been ascertained on corticospinal and other unidentified neurons in the rat cerebral cortex. Motilin, somatostatin, and luteinizing hormone releasing hormone excited most of the corticospinal neurons on which they were tested. Cholecystokinin. Met-enkephalin, vasoactive intestinal peptide, and neurotensin also excited some corticospinal neurons. Many nonidentified neurons were excited by all of these peptides. Met-enkephalin had a depressant action on some (14%) corticospinal neurons. Leu-enkaphalin depressed many identified and nonidentified neurons and had an excitatory action on a few neurons. Both excitatory and inhibitory actions of the enkephalins were antagonized by naloxone. Thyrotropin-releasing hormone had predominantly depressant actions on the spontaneous firing of corticospinal and nonidentified neurons but did excite some unidentified cortical neurons. Secretin had no effect on the firing of most of the neurons tested.     

Effects of adenosine and adenine nucleotides on synaptic transmission in the cerebral cortex.

Adenosine and the adenine nucleotides have a potent depressant action on cerebral cortical neurons, including identified corticospinal cells. Other purine and pyrimidine nucleotides were either weakly depressant (inosine and guanosine derivatives) or largely inactive (xanthine, cytidine, thymidine, uridine derivatives). The 5'-triphosphates and to a lesser extent the 5'-diphosphates of all the purine and pyrimidines tested had excitant actions on cortical neurons. Adenosine transport blockers and deaminase inhibitors depressed the firing of cortical neurons and potentiated the depressant actions of adenosine and the adenine nucleotides. Methylxanthines (theophylline, caffeine, and isobutylmethylxanthine) antagonized the depressant effects of adenosine and the adenine nucleotides and enhanced the spontaneous firing rate of cerebral cortical neurons. Intracellular recordings showed that adenosine 5'-monophosphate hyperpolarizes cerebral cortical neurons and suppresses spontaneous and evoked excitatory postsynaptic potentials in the absence of any pronounced alterations in membrane resistance or of the threshold for action potential generation. It is suggested that adenosine depresses spontaneous and evoked activity by inhibiting the release of transmitter from presynaptic nerve terminals. Furthermore, the depressant effects of potentiators and excitant effects of antagonists of adenosine on neuronal firing are consistent with the hypothesis that cortical neurons are subject to control by endogenously released purines.     

Interactions between adenosine and nifedipine in the rat cerebral cortex

Nifedipine inhibits the uptake of [³H]adenosine into rat cerebral cortical synaptosomes with an IC₅₀ value of 1.1 μM. When applied by iontophoresis onto rat cerebral cortical neurons it potentiated the depressant effects of adenosine on spontaneous firing. Some of the calcium-antagonist actions of nifedipine may be mediated by adenosine.     

Effects of adenosine analogs on rat cerebral cortical neurons

Adenosine and the adenosine 5'-phosphates (5'-AMP, 5'-ADP and 5'-ATP) depress the spontaneous firing of cerebral cortical neurons. In this study adenosine analogs, adenosine transport blockers and adenosine deaminase inhibitors have been used to gain further insight into the nature of the adenosine receptor and the likely routes of metabolism of extracellularly released adenosine. The firing rate of cortical neurons, including identified corticospinal neurons, was depressed by 2-substituted derivatives of adenosine. 2-Halogenated derivatives of adenosine were potent depressors while 2-aminoadenosine and 2-hydroxyadenosine (crotonoside) were slightly less potent than adenosine. The α,β-methylene isosteres of 5'-ADP and 5'-ATP were almost devoid of agonist activity while the β,γ-methylene analog was an active agonist. This suggests that ADP and ATP must be converted to AMP or possibly adenosine before they can activate the adenosine receptor. 2'-, 3'- and 5'- deoxyadenosine depressed spontaneous firing without antagonizing the effect of adenosine. Adenosine deaminase inhibitors, deoxycoformycin and $\text{erythro}$-9-(2-hydroxy-3-nonyl) adenine had potent, long lasting depressant actions on the spontaneous firing of cortical neurons and concurrently potentiated the actions of adenosine or 5'-AMP. Inhibitors of adenosine transport, papaverine and 2-hydroxy-5-nitrobenzylthioguanosine, prolonged the duration of action of adenosine and 5'-AMP. Intracellular recordings show that 5'-AMP hyperpolarizes cerebral cortical neurons and suppresses spontaneous and evoked excitatory postsynaptic potentials, in the absense of any pronounced alterations in membrane resistance.     

On the specificity of histamine H2-receptor antagonists in the rat cerebral cortex.

The effects of iontophoretically applied histamine H2-receptor antagonists and their antagonism of various amines, acetylcholine (ACh), and adenosine 5'-monophosphate (5'-AMP) were studied on spontaneously active rat cerebral cortical neurons. Metiamide selectively blocked the depressant actions of histamine. Burimamide, in amounts necessary for histamine antagonism, also antagonized the depressant effects of noradrenaline, dopamine, and 5-hydroxytryptamine. Neither antagonist affected 5'-AMP-induced depressions, but both reduced or blocked the excitatory actions of ACh. It is concluded that metiamide may be useful as a reliable antagonist of H2 receptors on cerebral cortical neurons.     

Diazepam potentiation of purinergic depression of central neurons.

Intravenously or iontophoretically applied diazepam potentiated the depressant action of iontophoretically applied 5'-AMP on the spontaneous firing of rat cerebral cortical neurons. This potentiation of purinergic depression may be a result of the previously reported inhibition by diazepam of uptake of adenosine into brain tissues.     

Electrophysiological actions of VIP in rat somatosensory cortex.

Electrophysiological and biochemical studies suggest that VIP may exert a facilitating action in the neocortical local circuitry. In the present study, we examined the actions of VIP and VIP + norepinephrine (NE) on somatosensory cortical neuron responses to direct application of the putative transmitters acetylcholine (ACh) and gamma-aminobutyric acid (GABA). Spontaneous and transmitter-induced discharges of cortical neurons from halothane-anesthetized rats were monitored before, during and after VIP, NE and VIP + NE iontophoresis. In 57 VIP-sensitive cells tested, VIP application (5-70 nA) increased (n = 18), decreased (n = 36) or had biphasic actions (n = 3) on background firing rate. In a group of 20 neurons tested for NE + VIP, the combined effect of both peptide and bioamine was predominantly (70%) inhibitory. On the other hand, inhibitory and excitatory responses of cortical neurons to GABA (11 of 15 cases) and ACh (10 of 18 cases), respectively, were enhanced during VIP iontophoresis. Concomitant application of VIP and NE produced additive (n = 2) or more than additive (n = 3) enhancing effects on GABA inhibition. NE administration reversed or enhanced further VIP modulatory actions on ACh-induced excitation. These findings provide electrophysiological evidence that NE and VIP afferents may exert convergent influences on cortical neuronal responses to afferent synaptic inputs such that modulatory actions are anatomically focused within the cortex.     

Vasoactive intestinal polypeptide excitation of central neurons.

Vasoactive intestinal polypeptide (VIP) was tested on neurons in the rat sensory motor cerebral cortex and on the isolated hemisected toad spinal cord. Iontophoretically applied VIP excited deep, spontaneously active cortical neurons, including identified corticospinal neurons. The excitation had a latency of onset varying from several seconds to over 1 min and often lasted for a minute or longer after cessation of the application. Desensitization of the effect occurred with repeated applications. VIP caused a depolarization of motoneurons and dorsal root terminals in the isolated amphibian spinal cord. Threshold for this effect was about 10(-6) M. The effects of VIP on both preparations were comparable with those of another peptide, substance P.     

Tryptamine and 5-hydroxytryptamine: actions and interactions of cortical neurones in the rat

The actions of iontophoretically applied tryptamine (T) and 5-hydroxytryptamine (5-HT) were compared on single neurones in the rat somatosensory cortex. The firing rate of the vast majority of neurones tested was depressed by T. However, 5-HT excited and depressed approximately equal numbers of neurones. Depressant effects of 5-HT could be profoundly enhanced by a very weak concurrent application of T (0–10 nA) which itself did not alter the baseline cell firing rate. Excitatory responses to 5-HT were consistently reversed into depressant responses during weak applications of T. These observations could support a modulatory role for endogenous T in 5-HT-mediated transmission in the central nervous system (CNS).     

Modulatory effects of catecholamines on neurons of the rat visual cortex: single-cell iontophoretic studies

The catecholamines noradrenaline and dopamine have been proposed as neuromodulators of cortical neuron excitability, and such a regulation could be mediated by specific adrenergic and dopaminergic receptors. We characterized electrophysiologically some of the types of responses to the iontophoretic application of adrenergic and dopaminergic agonists and antagonists on single cells in the rat visual cortex (areas occipital 1 monocular or Oc1M and occipital 1 binocular or Oc1B). For the majority of spontaneously active and visual cortical cells, noradrenaline and dopamine decreased the firing frequency. In the case of visually driven (synaptically activated) neurons, background firing was the main component of the response to be inhibited by the administration of noradrenaline, clonidine, and oxymetazoline, leading to an enhancement of the signal-to-noise ratio. Since these effects could be reduced or blocked by a previous ejection of the specific alpha 2-antagonist idazoxan, the findings support a role for alpha 2-adrenergic receptors in the transmission of sensory inputs to the visual cortex. These effects were not found with the mixed alpha-adrenergic agonist phenylephrine nor with the beta-agonist isoproterenol. Finally, the use of the inhibitory amino acid GABA rules out a simple hyperpolarizing response as the mechanism underlying noradrenaline modulatory effects in the cerebral cortex.     

Perisomatic GABA release and thalamocortical integration onto neocortical excitatory cells are regulated by neuromodulators

Neuromodulators such as acetylcholine, serotonin, and noradrenaline are powerful regulators of neocortical activity. Although it is well established that cortical inhibition is the target of these modulations, little is known about their effects on GABA release from specific interneuron types. This knowledge is necessary to gain a mechanistic understanding of the actions of neuromodulators because different interneuron classes control specific aspects of excitatory cell function. Here, we report that GABA release from fast-spiking (FS) cells, the most prevalent interneuron subtype in neocortex, is robustly inhibited following activation of muscarinic, serotonin, adenosine, and GABA(B) receptors--an effect that regulates FS cell control of excitatory neuron firing. The potent muscarinic inhibition of GABA release from FS cells suppresses thalamocortical feedforward inhibition. This is supplemented by the muscarinic-mediated depolarization of thalamo-recipient excitatory neurons and the nicotinic enhancement of thalamic input onto these neurons to promote thalamocortical excitation.     

Calcitonin and calcitonin gene-related peptide alter the excitability of neurons in rat forebrain

Individual neurons in the hypothalamus, thalamus, cortex, and other forebrain areas of urethane-anesthetized, male rats were iontophoretically tested for their membrane sensitivity to salmon calcitonin (CT), human CT, and CT gene-related peptide (CGRP). Extracellular recording of unit activity revealed that depression of neuronal firing was the predominant effect of iontophoretically applied salmon CT (35 of 74 cells tested). Few neurons responded to salmon CT with an increase in firing rate (N = 3). When CGRP was iontophoretically applied a pattern of response resembling that of salmon CT was observed. CGRP was predominantly inhibitory and excited those neurons whose firing rate was increased by salmon CT. Inhibition was also the predominant effect of human CT. However, no neurons were excited by human CT. The results clearly demonstrate that a subpopulation of neurons with membrane sensitivity to salmon CT, human CT, and CGRP are present in the rat forebrain. This finding suggests that modulation of neuronal activity may underlie the behavioral and biochemical effects of these peptides when administered centrally. Endogenous CGRP and CT-like peptides in rat brain may be capable of regulating these events as neurotransmitters or neuromodulators.     

Biochemical and electropharmaceutical studies with tricyclic antidepressants in rat and guinea-pig cerebral cortex.

Chopped guinea pig cerebral cortex was incubated with a series of antidepressant drugs which produced increases in the cyclic AMP content of the tissue. These effects were partially or wholly blocked by theophylline, suggesting that they were mediated by endogenous production, release and action of adenosine. A similar series of drugs was iontophoretically ejected on rat cerebral cortical neurons where augmentation of concurrently ejected adenosine was observed as slowing of the rate of cell firing. Pharmacological correlations between the two sets of data suggest a common mechanism of action.     

Cortical and septal responses to dorsal raphe nucleus stimulation in the rat: long-term clomipramine actions.

In cerebral cortex and lateral septal nuclei different serotonergic receptor subtypes coexist, thus a different action on neuronal firing may be expected depending on the receptor activated. Dorsal raphe nucleus stimulation produced an increased rate of firing in cortical layer V, and in lateral septal nuclei. However, firing rate in cortical layer VI remained unchanged after stimulating the dorsal raphe nucleus. Clomipramine is a tricyclic which exerts its main actions on serotonergic receptors, and long-term treatment with this antidepressant produced a selective increased firing rate in lateral septal neurons, but not in cortical neurons. From an electrophysiological point of view, it is concluded that the excitatory actions on firing rate elicited by dorsal raphe nucleus stimulation or clomipramine treatment are mediated by 5-HT2 receptor subtype activation which is likely to be acting as a 5-HT1A modulator in such places where both receptor subtypes coexist.     

An iontophoretic survey of opioid peptide actions in the rat limbic system: in search of opiate epileptogenic mechanisms

Iontophoretic and micropressure drug application and lesion techniques were used to investigate the cellular source of rat limbic system epileptiform responses to opioid peptides [19]. Iontophoretically applied morphine, methionine enkephalin or beta-endorphin inhibited the spontaneous or glutamate-activated firing of the great majority of single neurons in medial and lateral septum, amygdala and cingulate cortex. These inhibitions in firing were antagonized by iontophoresis of naloxone. In contrast to inhibitory effects in other limbic areas, morphine and the opioid peptides predominantly excited CA1 and CA3 pyramidal neurons in a naloxone-sensitive manner, as previously reported [36]. On rare occasions, iontophoretically applied beta-endorphin evoked repetitive waveforms similar to interictal population EPSPs or spikes. Micropressure application of opiates and peptides also excited hippocampal neurons indicating such responses were not current-induced artefacts. The possible role of the excitatory cholinergic septal hippocampal pathway in the facilitatory response of hippocampal units to the opiates was tested with iontophoretically applied atropine and scopolamine, or lesions of septal nuclei. None of these manipulations reduced the opioid-induced excitations; rather, septal lesions enhanced excitatory and epileptiform responses to the opiates. These results support the hypothesis that opiate-evoked epileptiform activity in the limbic system arises from enhanced pyramidal cell activity in the hippocampal formation, probably by a non-cholinergic mechanism.     

Various effects of angiotensin II on amygdaloid neuronal activity in normotensive control and hypertensive transgenic [TGR(mREN-2)27] rats.

The effects of iontophoretically ejected angiotensin II (Ang II) on the firing rate of neurons in the basolateral complex and the central and cortical amygdala were investigated in two strains of urethane anesthetized rats. In normotensive Sprague-Dawley rats, Ang II induced a significant increase in the discharge rate of responsive amygdaloid neurons. In contrast, in the hypertensive transgenic [TGR(mREN-2)27] rats with higher brain Ang II level, Ang II more often caused inhibitory effects on the amygdaloid firing rate in comparison with controls. The distribution of nonresponsive, excited, and inhibited neurons differed significantly in the two rat strains. Moreover, the responsiveness of amygdaloid neurons was significantly higher in transgenic rats in comparison with controls. Both the increase and the decrease in the firing rate caused by Ang II could be blocked either by angiotensin AT(1) or by AT(2) receptor-specific antagonists. In many cases, the Ang II-induced decrease in the firing rate was antagonized by bicuculline, a gamma-aminobutyric acid (GABA(A)) antagonist. The higher responsiveness of amygdaloid neurons in transgenic rats as well as the predominance of inhibitory effects, presumedly mediated by GABAergic interneurons, could change the output of the amygdala and its influence on thirst, kidney, and cardiovascular function or on processes of learning and anxiety.     

Noradrenergic effects on rat visual cortex: single-cell microiontophoretic studies of alpha-2 adrenergic receptors

The catecholamine noradrenaline has been proposed to modulate the excitability of cortical neurons, and such a regulation may be mediated by specific adrenergic receptors. We characterized, using electrophysiological recordings, the types of responses of single cells in the rat visual cortex (areas 17 and 18) to the iontophoretic application of adrenergic agents. For the majority of spontaneous and visually-driven cells sampled, noradrenaline decreased the firing frequency, and in some cases of visually-driven cells could increase the signal/noise ratio. These effects were also documented after the application of the alpha-2 adrenergic agonists clonidine and oxymetazoline, and could be reduced or blocked by a previous ejection of the specific alpha-2 antagonist idazoxan. The present study supports a role for alpha-2 adrenoceptors in the modulation of sensory inputs to the visual cortex.     

Theophylline antagonizes flurazepam-induced depression of cerebral cortical neurons.

Intravenously administered theophylline (50--100 mg/kg) antagonized the depressant actions of adenosine and flurazepam on rat cerebral cortical neurons. When assessed in conjunction with recent reports that theophylline competes with diazepam for binding sites in brain tissue, this finding suggests that one action of the benzodiazepines may be exerted at a purinergic receptor associated with central neurons.     

Effect of vasoactive intestinal polypeptide on the cyclic adenosine monophosphate generating system in rat kidney glomeruli and cortical tubules

The effect of in vitro addition of vasoactive intestinal polypeptide (VIP) on the 3'-5'-cyclic adenosine monophosphate (cAMP) generating system in rat kidney glomeruli and cortical tubules was studied. VIP did not stimulate cAMP accumulation in glomeruli; but VIP did stimulate, specifically and in a dose-dependent manner, cAMP concentrations in tubular membranes with the addition of GTP. These results are consistent with the existence of a functionally active VIP receptor coupled to adenylate cyclase in rat kidney cortical tubules.     

Evidence for an ascending inhibitory histaminergic pathway to the cerebral cortex.

Previous observations from our laboratory indicate that metiamide is a specific histamine antagonist in rat cerebral cortex. In view of the recent finding that histamine levels and L-histidine decarboxylase (EC 4.1.1.22) activity in cerebral cortex decrease following disruption of the ipsilateral medial forebrain bundle (MFB), the present investigation was undertaken to examine whether iontophoretically applied metiamide antagonizes the inhibition of deep cerebral cortical neurones produced by stimulation of the MFB. In rats anaesthetized with a mixture of methoxyflurane, nitrous oxide and oxygen, stimulation of the ipsilateral MFB or the cortical surface with iontophoretically applied histamine depressed the firing of cortical neurones. Metiamide antagonized the histamine-induced depression and reduced the duration of inhibition produced by MFB stimulation. However, it did not alter the inhibition induced by the cortical surface stimulation. These results indicate that a histaminergic pathway ascending through the MFB may inhibit rat cerebral cortical neurones.