Modulatory actions of norepinephrine in the central nervous system.

Early studies have shown that norepinephrine (NE) released synaptically or iontophoretically onto neurons in the central nervous system acts to depress firing by a mechanism associated with a hyperpolarization but no change or an increase in membrane resistance. This in contrast to classical transmitters, which cause hyperpolarization by a conductance increase. Recent studies designed to clarify the functional implications of these biophysical actions have revealed new phenomenons in which the major overall effect of NE on cerebellar Purkinje cells is to enhance conventional synaptic input and induce an increase in signal-to-noise ratio of evoked versus spontaneous activity. NE released iontophoretically or via stimulation of the locus coeruleus also has been found to enhance the inhibitory effects of gamma-aminobutyric acid, an endogenous cerebellar transmitter. The effects appear even at low doses of NE having no direct depressant action on spontaneous activity. Specificity tests have shown no enhancement of glycine-induced inhibition by NE and an inability of dopamine to mimic NE. The hypothesis is presented that a significant action of NE in the central nervous system is to induce a bias that alters postsynaptic responsiveness to conventional transmitter systems, which themselves may be more directly concerned with detailed information transfer.     

GABAergic mechanisms in the electrophysiological actions of ethanol on cerebellar neurons

We have found that the partial inverse benzodiazepine agonists Ro 15-4513 and FG 7142 antagonize the depressant electrophysiologial effects of locally applied ethanol in the cerebellum. Although absolute tissue concentrations are not known, dose-response curves constructed using pressure-ejection doses as previously described (31, 25) we found that FG 7142 was more efficacious, but less potent than Ro 15-4513. Our observation that ethanol and inverse benzodiazepine agonists have interactions which are not competitive might suggest that these two drugs act through separate, but interactive mechanisms in order to produce the observed ethanol antagonism. If such independent interactions were mediated at different sites on a given macromolecular complex, such as the GABA_a/Cl^– channel, then one might expect to find allosteric interactions between those sites as well as with the functional response of the complex to GABA activation. Indeed, this hypothesis is consistent with the recent finding of Harris and collaborators that ethanol potentiates the inverse agonist actions of Ro 15-4513 and FG 7142. On the other hand, we were unable to find large ethanol-induced potentiations of GABA effects on all neurons which showed depressant responses to ethanol administration in rat cerebellum. However we did find that the GABA_a antagonist, bicuculline, blocks the depressant effects of ethanol on the same neurons. We conclude that the interaction between ethanol and GABA probably does not occur directly at the GABA_a receptor site, but that the GABA_a mechanism does play a permissive role in the ethanol-induced depressions of cerebellar Purkinje neurons. Thus, although a postsynaptic GABA_a mechanism may not be the primary locus of action at which ethanol causes depressant electrophysiological responses of neurons, activation of the GABA_a receptor may be required to make cerebellar Purkinje neurons responsive to the depressant actions of ethanol. Further investigations will be required to determine the pre vs postsynaptic nature of this interaction of ethanol with the GABA mechanism of action.Special issue dedicated to Dr. Erminio Costa     

Blockade of central beta-adrenergic receptors by tazolol (1-isopropylamino-3-(2-thiazoloxy)-2-propanol).

Tazolol, a β₁-adrenergic agonist in heart, had no intrinsic β-adrenergic agonist activity with respect to cyclic AMP-generating systems in rat cerebral cortical slices or with respect to firing of rat cerebellar Purkinje cells. Instead, tazolol proved to be a relatively potent and specific β-adrenergic antagonist. The IC₅₀ for (±) tazolol in antagonizing (-) isoproterenol-elicited accumulation of cyclic AMP in rat cortical slices was 7 × 10^?7M. The IC₅₀ in antagonizing [³H] dihydroalprenolol-binding in rat cortical homogenates was 2.9 × 10^?7 M. Tazolol was about 10 fold more potent in both cases than the β-antagonist, (±) sotalol. Tazolol antagonized the inhibitory, β-adrenergically mediated effects of iontophoretically applied norepinephrine on firing of cerebellar Purkinje cells. The inhibitory effects of γ-aminobutyric acid on firing of Purkinje cells were not altered by tazolol. Tazolol appeared to lack significant local anesthetic activity as evidenced by its lack of effect on spike height in spontaneous firing Purkinje cells.     

Interaction of penicillin and pentobarbital with inhibitory synaptic mechanisms in neocortex

In this study we characterized the responses of neocortical neurons to iontophoretically applied gamma-aminobutyric acid (GABA) and examined how these GABA responses as well as the inhibitory postsynaptic potentials (IPSPs) were affected by the presence of penicillin or pentobarbital. Intracellular recordings were obtained from slices of rat neocortex maintained in vitro; injection of the dye Lucifer yellow indicated that recordings were primarily from pyramidal neurons. Orthodromically evoked responses were always depolarizing at the cell's resting membrane potential. Such depolarizing responses could easily be reversed in polarity by depolarizing the cell 10-15 mV, suggesting that the response consisted partly of an IPSP. In some cases, depolarization unmasked a small, short-latency excitatory postsynaptic potential (EPSP). Responses to iontophoretically applied GABA were also depolarizing at rest. Biphasic hyperpolarizing-depolarizing responses were occasionally observed upon depolarization of the neuron. Bath application of penicillin (1.7-3.4 mM) decreased the amplitude of the IPSPs and increased their time to peak, an effect associated with the development of epileptiform activity. Penicillin also reduced the maximum response to iontophoretically applied GABA without affecting the dose required to obtain a half-maximal response, suggesting a noncompetitive antagonism. Pentobarbital (100-200 microM) prolonged the time course and increased the amplitude of the IPSPs while producing a leftward shift in the GABA charge-response relation. These results suggest that the convulsant penicillin and the anticonvulsant pentobarbital have opposing actions on GABAergic inhibition in the neocortex.     

Synaptic formations and modulations of synaptic transmissions between identified cerebellar neurons in culture.

1. Synaptic formations between a rat cerebellar granule cell and a Purkinje cell, and also between an inferior-olivary neuron and a Purkinje cell have been accomplished in culture. 2. The synaptic transmission between an inferior-olivary neuron and a Purkinje cell was far much more potent than that between a granule cell and a Purkinje cell in the culture, and the former always induced in a Purkinje cell an action potential followed by prolonged depolarization, which resembled a climbing fiber response in vivo. 3. Synaptic potentiation was induced by repetitive stimulation (2 Hz, 20 sec) of a granule cell, and the synaptic depression was induced by repetitive conjunctive stimulation of both a granule cell and an inferior-olivary neuron as in a slice preparation. 4. When repetitive stimulation of both neurons were given while the postsynaptic Purkinje cell was voltage-clamped at -80 mV, not the depression but the potentiation took place. When repetitive stimulation of a granule cell was coupled with the postsynaptic strong depolarization induced by direct outward current injection, the depression took place. These two experiments indicate that the postsynaptic depolarization during activation of a presynaptic granule cell is both necessary and sufficient to induce the depression, and that the potentiation is induced without the postsynaptic depolarization. 5. The quantal analysis on the synaptic transmission, where fluctuations of amplitudes of synaptic currents in a Purkinje cell induced by a single granule cell were measured, indicated that the synaptic potentiation involves the enhancement of transmitter release from a presynaptic granule cell and that the depression involves changes of postsynaptic receptors on a Purkinje cell.     

Electrophysiological and microiontophoretic studies with buspirone: influence on the firing rate of central monoaminergic neurons and their responsiveness to dopamine, clonidine or GABA

The influence of an i.v. perfusion of buspirone on the firing rate of central monoaminergic neurons was studied in rats anaesthetized with chloral hydrate. Buspirone increased the firing rate of A10 dopaminergic neurons and blocked the inhibitory effect of iontophoretically applied dopamine on these neurons. A slight attenuation of the inhibitory effect of iontophoretically applied GABA was also observed. Buspirone increased the firing rate of locus coeruleus (LC) noradrenergic neurons and induced an attenuation of the inhibitory effect of iontophoretically applied clonidine. A slight attenuation of the inhibitory effect of iontophoretically applied GABA was also observed. Furthermore buspirone was a very potent inhibitor of the firing rate of dorsal raphe (DR) serotonergic neurons. It is concluded that activation of A10 neurons by buspirone is due to blockade of dopaminergic autoreceptors and that activation of LC neurons is related to blockade of alpha-2 autoreceptors. The significance of the interaction with gabaergic inhibition is unclear. The mechanisms involved in the inhibition of DR neurons remain to be investigated.     

Role of uptake inγ-aminobutyric acid (GABA)-mediated responses in guinea pig hippocampal neurons

Intracellular recordings were obtained from hippocampal pyramidal neurons maintained in vitro. Measurements were made of the conductance change induced by iontophoretically applied gamma-aminobutyric acid (GABA) and, using voltage-clamp techniques, of inhibitory postsynaptic currents resulting from activation of inhibitory pathways. Analysis of GABA iontophoretic charge-response curves indicated that there was considerable variation among neurons with respect to the slope of this relation. The placement of the GABA-containing pipette did not appear to be responsible for the observed variation, since vertical repositioning of the pipette did not alter the slope of the charge-response relationship. Steady iontophoresis of GABA from one barrel of a double-barreled pipette markedly affected the charge-response relation obtained when short pulses were applied to the other barrel. The curve was shifted to the left, and the slope was decreased. Concomitantly, the enhanced GABA-induced responses were prolonged. Similar alterations in GABA responsiveness were observed when the uptake blocker, nipecotic acid, was iontophoretically applied. Furthermore, bath application of saline containing a reduced sodium concentration (25% of control) also produced a prolongation of GABA-mediated responses. Under voltage clamp, inhibitory postsynaptic currents were observed to have biphasic decays. The initial, fast decay was prolonged by an average of 18% by nipecotic acid, whereas the later, slow phase was prolonged by 23%. The results of these studies support the hypothesis that a saturable GABA uptake system is responsible for the observed variation in the charge-response curves and, in turn, underlies the apparent sensitizing effect of excess GABA application. The results also suggest that a reduction of transmitter uptake affects the time course of inhibitory postsynaptic currents in the hippocampus.     

Responses of septal nuclei neurons to microiontophoretically administered putative neurotransmitters

In halothane anesthetized rats, neurons of the medial and lateral septal nuclei were tested with iontophoretically applied putative neurotransmitters. GABA, norepinephrine, serotonin, and acelycholine in roughly this order of potency were inhibitory with respect to spontaneous and evoked activity of both medial and lateral septal nuclei cells. No specific effects of any of the compounds were observed on septal unit responses to fornix or fimbria stimulation.     

Vasoactive intestinal polypeptide excitation of cerebral cortical neurons: lack of synergism with adenosine and noradrenaline

Vasoactive intestinal polypeptide (VIP), applied iontophoretically, excited 40% of the spontaneously firing rat cortical neurons tested. No neurons were depressed by VIP. When applied simultaneously with adenosine or noradrenaline, VIP depressed the firing of cortical neurons, but this depression could be reproduced by the passage of similar positive currents through a 50 mM NaCl-containing barrel of the multiple barrelled micropipette. VIP, therefore, excited rat cortical neurons and no depressant actions were apparent when VIP was applied together with adenosine or noradrenaline. Leakage of adenosine or noradrenaline during iontophoretic applications of the peptide may account for the reported inhibitory actions of VIP.     

Effects of the selective noradrenergic neurotoxin DSP4 on cerebellar Purkinje neuron electrophysiology

The effect of the adrenergic neurotoxin DSP4 on cerebellar electrophysiology was studied in the rat. DSP4, administered parenterally, depleted cerebellar norepinephrine by 76%. The depressant response of cerebellar Purkinje neurons to phencyclidine, a drug which acts on adrenergic presynaptic terminals to release NE, was markedly reduced after DSP4 pretreatment. In contrast with 60HDA, which increased firing rates of the Purkinje cells, DSP4 did not change the rate or pattern of Purkinje cell discharge. Taken together these results suggest that DSP4 may be a valuable tool for studying central adrenergic pathways, but that this drug has properties which differ from 60HDA.     

Mapping study of Achatina giant neurons sensitive to molluscan peptides

1. Mapping studies of the Achatina identifiable neuron types sensitive to the following 6 molluscan peptides were examined under current-clamp.2. These were Ser-Mytilus inhibitory peptide (Ser-MIP), catch-relaxing peptide (CARP), oxytocin, small cardioactive peptide_b (SCP_b), α-bag cell peptide (α-BCP) and egg-laying hormone (ELH).3. These peptides at 10⁻³ M (3 × 10⁻⁴ M for ELH), with 0.5% Fast Green, were applied locally to the neuron to be tested by pneumatic pressure ejection (2 kg/cm² and 400 msec in duration).4. Ser-MIP showed the inhibitory (hyperpolarizing) effects on the majority of neuron types tested.5. CARP also produced inhibition of the 3 neuron types out of 16 types tested.6. Oxytocin had an excitatory effect on two neuron types.7. SCP_b showed excitatory effects on 4 neuron types: the membrane conductance of 1 neuron type, d-RPeAN, measured under voltage-clamp was reduced by the peptide.8. α-BCP showed no effect.9. ELH produced slight inhibition of the 2 neuron types.     

Synchronization and sensitivity enhancement of the Hodgkin-Huxley neurons due to inhibitory inputs

Recent experimental results imply that inhibitory postsynaptic potentials can play a functional role in realizing synchronization of neuronal firing in the brain. In order to examine the relation between inhibition and synchronous firing of neurons theoretically, we analyze possible effects of synchronization and sensitivity enhancement caused by inhibitory inputs to neurons with a biologically realistic model of the Hodgkin-Huxley equations. The result shows that, after an inhibitory spike, the firing probability of a single postsynaptic neuron exposed to random excitatory background activity oscillates with time. The oscillation of the firing probability can be related to synchronous firing of neurons receiving an inhibitory spike simultaneously. Further, we show that when an inhibitory spike input precedes an excitatory spike input, the presence of such preceding inhibition raises the firing probability peak of the neuron after the excitatory input. The result indicates that an inhibitory spike input can enhance the sensitivity of the postsynaptic neuron to the following excitatory spike input. Two neural network models based on these effects on postsynaptic neurons caused by inhibitory inputs are proposed to demonstrate possible mechanisms of detecting particular spatiotemporal spike patterns. Received: 15 April 1999 /Accepted in revised form: 25 November 1999     

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.     

Contralateral input modulates the excitability of dorsal horn neurons involved in noxious signal processes. Potential role in neuronal sensitization

Wide Dynamic Range (WDR) neurons in the spinal cord receive inputs from the contralateral side that, under normal conditions, are ineffective in generating an active response. These inputs are effective when the target WDRs change their excitability conditions. To further reveal the mechanisms supporting this effectiveness shift, we investigated the weight of the excitation of the contralateral neurons on the target WDR responses. In the circuit of presynaptic (sending) and postsynaptic (receiving) neurons in crossed spinal connections the fibres that form the presynaptic neurons impinge on postsynaptic neurons can be considered the final relay of this contralateral pathway. The enhancement of the presynaptic neuron excitability may thus modify the efficacy of the contralateral input. Pairs of neurons each on a side of the spinal cord, at the L5-L6 lumbar level were simultaneously recorded in intact, anaesthetized, paralysed rats. The excitatory aminoacid NMDA and strychnine, the antagonist of the inhibitory aminoacid glycine, were iontophoretically administrated to presynaptic neurons to increase their excitability. Before and during the drug administration, spontaneous and noxious-evoked activities of the neurons were analysed. During the iontophoresis of the two substances we found that noxious stimuli applied to the receptive field of presynaptic neurons activated up to 50% of the previously unresponsive postsynaptic neurons on the opposite side. Furthermore, the neurons on both sides of the spinal cord showed significantly increased spontaneous activity and amplified responses to ipsilateral noxious stimulation. These findings indicate that the contralateral input participates in the circuit dynamics of spinal nociceptive transmission, by modulating the excitability of the postsynaptic neurons. A possible functional role of such a nociceptive transmission circuit in neuronal sensitization following unilateral nerve injury is hypothesized.     

Contralateral input modulates the excitability of dorsal horn neurons involved in noxious signal processes. Potential role in neuronal sensitization

Wide Dynamic Range (WDR) neurons in the spinal cord receive inputs from the contralateral side that, under normal conditions, are ineffective in generating an active response. These inputs are effective when the target WDRs change their excitability conditions. To further reveal the mechanisms supporting this effectiveness shift, we investigated the weight of the excitation of the contralateral neurons on the target WDR responses. In the circuit of presynaptic (sending) and postsynaptic (receiving) neurons in crossed spinal connections the fibres that form the presynaptic neurons impinge on postsynaptic neurons can be considered the final relay of this contralateral pathway. The enhancement of the presynaptic neuron excitability may thus modify the efficacy of the contralateral input. Pairs of neurons each on a side of the spinal cord, at the L5–L6 lumbar level were simultaneously recorded in intact, anaesthetized, paralysed rats. The excitatory aminoacid NMDA and strychnine, the antagonist of the inhibitory aminoacid glycine, were iontophoretically administrated to presynaptic neurons to increase their excitability. Before and during the drug administration, spontaneous and noxious-evoked activities of the neurons were analysed. During the iontophoresis of the two substances we found that noxious stimuli applied to the receptive field of presynaptic neurons activated up to 50% of the previously unresponsive postsynaptic neurons on the opposite side. Furthermore, the neurons on both sides of the spinal cord showed significantly increased spontaneous activity and amplified responses to ipsilateral noxious stimulation. These findings indicate that the contralateral input participates in the circuit dynamics of spinal nociceptive transmission, by modulating the excitability of the postsynaptic neurons. A possible functional role of such a nociceptive transmission circuit in neuronal sensitization following unilateral nerve injury is hypothesized.     

Calcium-induced modulation of synaptic transmission

Calcium (Ca²⁺) is a second messenger regulating a wide variety of intracellular processes. Using GABA-and glycinergic synapses as examples, this review analyzes two functions of this unique ion: postsynaptic Ca²⁺-dependent modulation of receptor-operated channels and Ca²⁺-induced retrograde regulation of neurotransmitter release from the presynaptic terminals. Phosphorylation, rapid Ca²⁺-induced modulation via intermediate Ca²⁺-binding proteins, and changes in the number of functional receptors represent the main pathways of short-and long-term plasticity of postsynaptic receptor-operated channel machinery. Retrograde signaling is an example of synaptic modulation triggered by stimulation of postsynaptic cells and mediated via regulation of presynaptic neurotransmitter release. This mechanism provides postsynaptic neurons with efficient tools to control the presynaptic afferents in an activity-dependent mode. Elevation of intracellular Ca²⁺ in a postsynaptic neuron triggers the synthesis of endocannabinoids (derivatives of arachidonic acid). Their retrograde diffusion through the synaptic cleft and consequent activation of presynaptic G-protein coupled to CB1 receptors inhibits the release of neurotransmitter. These mechanisms of double modulation, which include control over the function of postsynaptic ion channels and retrograde suppression of the release machinery, play an important role in Ca²⁺-dependent control of the main excitatory and inhibitory synaptic pathways in the mammalian nervous system.     

Maintenance of high-frequency transmission at purkinje to cerebellar nuclear synapses by spillover from boutons with multiple release sites

Cerebellar Purkinje neurons maintain high firing rates but their synaptic terminals depress only moderately, raising the question of how vesicle depletion is minimized. To identify mechanisms that limit synaptic depression, we evoked 100 Hz trains of GABAergic inhibitory postsynaptic currents (IPSCs) in cerebellar nuclear neurons by stimulating Purkinje axons in mouse brain slices. The paired-pulse ratio (IPSC(2)/IPSC(1)) of the total IPSC was approximately 1 and the steady-state ratio (IPSC(20)/IPSC(1)) was approximately 0.5, suggesting a high response probability of postsynaptic receptors, without an unusually high release probability. Three-dimensional electron microscopic reconstructions of Purkinje boutons revealed multiple active zones without intervening transporters, suggestive of "spillover"-mediated transmission. Simulations of boutons with 10-16 release sites, in which transmitter from any site can reach all receptors opposite the bouton, replicated multiple-pulse depression during normal, high, and low presynaptic Ca influx. These results suggest that release from multiple-site boutons limits depletion-based depression, permitting prolonged, high-frequency inhibition at corticonuclear synapses.     

Dermorphin tetrapeptide analogs as potent and long-lasting analgesics with pharmacological profiles distinct from morphine

Dermorphin (Tyr-d-Ala-Phe-Gly-Tyr-Pro-Ser-NH₂) is a heptapeptide isolated from amphibian skin. With a very high affinity and selectivity for μ-opioid receptors, dermorphin shows an extremely potent antinociceptive effect. The structure-activity relationship studies of dermorphin analogs clearly suggest that the N-terminal tetrapeptide is the minimal sequence for agonistic activity at μ-opioid receptors, and that the replacement of the d-Ala² residue with d-Arg² makes the tetrapeptides resistant to enzymatic metabolism. At present, only a handful of dermorphin N-terminal tetrapeptide analogs containing d-Arg² have been developed. The analogs show potent antinociceptive activity that is greater than that of morphine with various injection routes, and retain high affinity and selectivity for μ-opioid receptors. Interestingly, some analogs show pharmacological profiles that are distinct from the traditional μ-opioid receptor agonists morphine and [d-Ala²,NMePhe⁴,Gly-ol⁵]enkephalin (DAMGO). These analogs stimulate the release of dynorphins through the activation of μ-opioid receptors. The activation of κ-opioid receptors by dynorphins is suggested to reduce the side effects of μ-opioid receptor agonists, e.g., dependence or antinociceptive tolerance. The dermorphin N-terminal tetrapeptide analogs containing d-Arg² may provide a new target molecule for developing novel analgesics that have fewer side effects.     

Differential channeling of sensory stimuli onto a motor neuron in the leech

We studied a specific sensory-motor pathway in the isolated leech ganglia. Pressure-sensitive mechanosensory neurons were stimulated with trains of action potentials at 5–20 Hz while recording the responses of the annulus erector motorneurons that control annuli erection. The response of the annulus erector neurons was a succession of excitatory postsynaptic potentials followed by inhibitory postsynaptic potentials. The excitatory postsynaptic potentials had a brief time-course while the inhibitory postsynaptic potentials had a prolonged time-course that enabled their temporal summation. Thus, the net effect of pressure-sensitive neuron stimulation on the annulus erector neurons was inhibitory. Both phases of the response were mediated by chemical transmission; the excitatory postsynaptic potentials were transmitted via a monosynaptic pathway, and the inhibitory postsynaptic potentials via a polysynaptic one. The pattern of expression of this dual response depended on the field of innervation of the sensory neuron and it was under the influence of cell 151, a non-spiking interneuron, that could regulate the expression of the hyperpolarization. The interaction between pressure-sensitive neurons and annulus erector neuron reveals how sensory specificity, connectivity pattern and regulatory elements interplay in a specific sensory-motor network. Accepted: 6 November 1998     

Dehydrophenylalanyl analogs of bradykinin: Synthesis and biological activities

We have synthesized three analogs of the potent vasodilator peptide bradykinin, ArgProProGlyPhe SerProPheArg (BK), containing dehydrophenylalanine (Δ^zPhe) in place of the phenylalanyl residues at positions 5 and/or 8. The analogs, [Δ^zPhe⁵]BK, [Δ^zPhe⁸]BK, and [Δ^zPhe^5,8]BK, were assayed for their effects on isolated smooth muscle tissues and on the systemic arterial blood pressure of rats. In these assays [Δ^zPhe⁵]BK showed considerably high biological activities, particularly in terms of its blood pressure-lowering effects, being over 23 times more potent than BK when given intravenously. [Δ^zPhe⁸]BK was less potent than BK and [Δ^zPhe^5,8]BK had effects comparable to those of BK. All three synthetic analogs appear to be more resistant than BK to enzymic degradation during passage through the pulmonary vascular bed.