Cholinergic mechanisms in the caudate nucleus

Modulatory action of acetylcholine on striatal neurons: microiontophoretic study in awake, unrestrained rats

Cholinergic interneurons innervate virtually all medium spiny striatal cells, but the relevance of this input in regulating the activity and afferent responsiveness of these cells remains unclear. Studies in anaesthetized animals and slice preparations have shown that iontophoretic acetylcholine (ACh) either weakly excites or inhibits striatal neurons. These differential responses may reflect cholinergic receptor heterogeneity but may be also related to the different activity states of recorded units and different afferent inputs specific in each preparation. Single-unit recording was combined with iontophoresis in awake, unrestrained rats to examine the effects of ACh and selective muscarinic (oxotremorine M or Oxo-M) and nicotinic agonists (nicotine or NIC) on dorsal and ventral striatal neurons. These effects were tested on naturally silent, spontaneously active and glutamate-stimulated units. We found that iontophoretic ACh primarily inhibited spontaneously active and glutamate-stimulated units; the direction of the ACh response, however, was dependent on the firing rate. The effects of ACh were generally mimicked by Oxo-M and, surprisingly, by NIC, which is known to excite units in most central structures, including striatal neurons in anaesthetized preparation. Given that NIC receptors are absent on striatal cells but located primarily on dopamine terminals, we assessed the effects of NIC after complete blockade of dopamine receptors induced by systemic administration of a mixture of D1 and D2 antagonists. During dopamine receptor blockade the number of NIC-induced inhibitions dramatically decreased and NIC had mainly excitatory effects on striatal neurons. Thus, our data suggest that under physiologically relevant conditions ACh acts as a state-dependent neuromodulator, and its action involves not only postsynaptic but also presynaptic cholinoreceptors located on dopamine- and glutamate-containing terminals.

Postsynaptic integration of cholinergic and dopaminergic signals on medium-sized GABAergic projection neurons in the neostriatum

The effects of cholinergic drugs and the interaction between cholinergic and dopaminergic compounds were studied on electrically evoked [3H]gamma-aminobutyric acid (GABA) overflow in slices of the rat neostriatum. Slices were prepared and loaded with [3H]GABA in the presence of beta-alanine and then superfused with Krebs-bicarbonate buffer containing aminooxyacetic acid and nipecotic acid to inhibit GABA uptake and metabolism, respectively. The nonselective muscarinic agonist oxotremorine (0.1-10 microM) increased the release of [3H]GABA and the selective M1 receptor agonist McN-A-343 (0.1-10 microM) exerted similar effect. The stimulatory effect of oxotremorine (10 microM) on [3H][GABA overflow was antagonized by the nonselective muscarinic antagonist atropine (1 microM) and the selective M1 receptor antagonist pirenzepine (0.1-1.0 microM). The M2 receptor antagonist methoctramine (1.0 microM) did not alter the stimulatory effect of oxotremorine. Of the muscarinic receptor antagonists atropine, pirenzepine, and methoctramine (1.0 microM) failed to affect [3H]GABA overflow. The M3 receptor antagonist p-F-HHSiD (1 microM) increased [3H]GABA overflow and p-F-HHSiD and oxotremorine were found to be additive in increasing this effect. The D2 dopamine receptor antagonist sulpiride (10 microM) increased the electrical stimulation-induced [3H]GABA overflow, and this stimulation was counteracted by concomitant administration of atropine (1 microM). McN-A-343 and sulpiride also increased the KCl-induced [3H]GABA overflow from superfused neostriatal slices and tetrodotoxin (1 microM) did not affect these stimulations. These data indicate that the release of GABA in the neostriatum is under the control of M1 stimulatory and M3 inhibitory muscarinic receptors. Dopamine, which exerts inhibition on GABA release via D2 receptors, may counteract the M1 facilitation, and M1 and D2 receptors involved in the cholinergic-dopaminergic interaction may be located postsynaptically on medium-sized spiny GABAergic projection neurons.

Neocortical damage alters synaptic responses of neostriatal neurons in vitro

The present experiments were designed to investigate the physiological impact of a partial decortication upon neostriatal synaptic responses using intracellular recording techniques in the in vitro brain slice preparation. In the intact rat, the locally evoked neostriatal synaptic response is primarily mediated by excitatory amino acid receptor activation. Following neocortex damage, the contributions of both N-methyl-D-aspartate and non-N-methyl-D-aspartate receptor activation were significantly diminished, although responses remained robust in amplitude and duration. Components of the locally evoked synaptic response mediated by activation of GABAA receptors were relatively unchanged, while presynaptic inhibition mediated by activation of GABAB receptors was markedly reduced. Furthermore, the normally minimal acetylcholine contribution to the synaptic response was significantly increased after neocortical damage. This enhanced cholinergic role in the generation of the synaptic response appeared to be mediated primarily by activation of nicotinic receptors. Thus, neocortical damage leads to novel physiological relationships between intrinsic neostriatal cholinergic interneurons and the GABAergic projection neurons. One possibility is that cholinergic interneurons have the potential for substituting for the loss of excitation created by the absence of neocortical glutamatergic input.

Modulatory action of dopamine on acetylcholine-responsive striatal and accumbal neurons in awake, unrestrained rats

In ambulant rats, iontophoresis of low concentrations of dopamine (DA) enhances the response of neurons in striatum and nucleus accumbens to iontophoretic glutamate. In an extension of this line of investigation, we tested the effects of acetylcholine (ACh), a presumed modulator of neuronal function in these same brain regions, and assessed possible DA-ACh interactions. Data were obtained from spontaneously active neurons known to respond to ACh (5-30 nA) when the animals rested quietly with no overt movement. ACh iontophoresis either excited or inhibited striatal and accumbal activity but excitatory effects predominated in both areas. With multiple applications of ACh, especially at the lowest currents tested, either response often was interspersed with instances of no change in firing rate. Responsiveness to ACh also diminished during periods of spontaneous movement when basal firing showed phasic increases in activity. In fact, neurons with the highest rates of basal activity showed the smallest magnitude response to ACh. Prolonged applications (120-180 s) of DA attenuated basal firing as well as the iontophoretic effects of ACh both during the DA application itself and for up to 1 min after DA ejection offset. The result of these inhibitory effects was no net change in the relative magnitude of the ACh response. Thus, although ACh can modulate striatal and accumbal neuronal activity, DA does not regulate this effect in the same way that it regulates the neuronal responsiveness to glutamate.

Neural dynamics in cortex-striatum co-cultures--II. Spatiotemporal characteristics of neuronal activity

Neural dynamics in organotypic cortex-striatum co-cultures grown for three to six weeks under conditions of dopamine deficiency are described. Single neuron activities were recorded intra- and extracellularly, and spatiotemporal spreading of population activity was mapped using voltage-sensitive dyes. The temporal properties of spike firing were characterized by interspike interval histograms, autocorrelation and crosscorrelation. Cortical pyramidal neurons (n = 40) showed irregular firing with a weak tendency to burst or to oscillate. Crosscorrelations revealed strong near-coincident firing and synaptic interactions. Disinhibition was a notable feature in a strongly firing cortical interneuron. Cortical activity spread in the co-culture, thus inducing an overall, homogeneous depolarization in the striatal part. Striatal cells were divided into principal cells and type I and II secondary cells. Principal cells (n = 40) were similar to those reported previously in vivo. Spiking activity ranged from irregular spiking at very low rates to episodic bursting, with an average burst duration of 1 s. Interspike intervals were single-peaked. Intracellular recordings revealed characteristic, long-lasting subthreshold depolarizations ("enabled state") that were shortened by local muscarinic receptor blockade. During prolonged time periods in the "enabled state", locally applied bicuculline induced strong firing in most principal neurons. Striatal secondary type I neurons (n = 25) showed high spiking rates, single- and double-peaked interval histograms and low-threshold, short-lasting stereotyped bursting activity and occasional rhythmic bursting. The firing of these neurons was increased by bicuculline. Crosscorrelations showed synchronization of these cells with principal cell activity. Secondary type II neurons (n = 15) revealed tonic, irregular firing patterns similar to cortical neurons, except with occasional firing in doublet spikes. We conclude that under conditions of dopamine deficiency in corticostriatal co-cultures (i) the cortex induces the "enabled" state and typical bursting mode in striatal principal neurons; (ii) principal neurons are strongly inhibited during the "enabled" state; (iii) muscarinic activity, presumably from tonically active striatal cholinergic interneurons, stabilizes the "enabled" state; (iv) striatal GABAergic interneurons receives synaptic inhibition and take part in synchronized activity among striatal principal cells. Our results favor the view of the striatum as a lateral inhibition network.

Kinetic analysis of 3-quinuclidinyl 4-[125I]iodobenzilate transport and specific binding to muscarinic acetylcholine receptor in rat brain in vivo: implications for human studies

Radioiodinated R- and S-Quinuclidinyl derivatives of RS-benzilate (R- and S-125IQNB) have been synthesized for quantitative evaluation of muscarinic acetylcholine receptor binding in vivo. Two sets of experiments were performed in rats. The first involved determining the metabolite-corrected blood concentration and tissue distribution of tracer R-IQNB (active enantiomer) and S-IQNB (inactive enantiomer) in brain 1 min to 26 h after intravenous injection. The second involved the measurement of brain tissue washout over a 2-min period after loading the brain by an intracarotid artery injection of the ligands. Various pharmacokinetic models were tested, which included transport across the blood-brain barrier (BBB), nonspecific binding, low-affinity binding, and high-affinity binding. Our analysis demonstrated that the assumptions of rapid equilibrium across the BBB and rapid nonspecific binding are incorrect and result in erroneous estimates of the forward rate constant for binding at the high-affinity receptor sites (k3). The estimated values for influx across the BBB (K1), the steady-state accumulation rate in cerebrum (K), and the dissociation rate constant at the high-affinity site (k4) of R-IQNB were independent of the specific compartmental model used to analyze these data (K1 approximately 0.23 ml/min/g, K approximately 0.13 ml/min/g, and k4 approximately 0.0019 min-1 for caudate). In contrast, the estimated values of k3 and the efflux rate constant (k2) varied over a 10-fold range between different compartmental models (k3 approximately 2.3-22 min-1 and k2 approximately 1.6-16 min-1 in caudate), but their ratios were constant (k3/k2 approximately 1.4). Our analysis demonstrates that the estimates of k3 (and derived values such as the binding potential) are model dependent, that the rate of R-IQNB accumulation in cerebrum depends on transport across the BBB as well as the rate of binding, and that uptake in cerebrum is essentially irreversible during the first 360 min after intravenous administration. Graphical analysis was consistent with compartmental analysis of the data and indicated that steady-state uptake of R-IQNB in cerebrum is established within 1-5 min after intravenous injection. We propose a new approach to the analysis of R-IQNB time-activity data that yields reliable quantitative estimates of k3, k4, and the nonspecific binding equilibrium constant (Keq) by either compartmental or graphical analysis. The approach is based on determining the free unbound fraction of radiolabeled ligand in blood and an estimate of K1.(ABSTRACT TRUNCATED AT 400 WORDS)

Retrograde amnesia produced by intrastriatal atropine and its reversal by choline

A number of studies have shown that cholinergic blockade of the striatum produces amnesia. In the present experiment it was predicted that by increasing the synthesis of striatal acetylcholine such amnesic state would be prevented. Atropine was injected into the striatum of rats before training of passive avoidance; some of these rats were also injected, intrastriatally, with choline before testing the retention of the task. Atropine alone produced amnesia while the combination of treatments reversed this effect.

Cholinergic synaptic input to different parts of spiny striatonigral neurons in the rat

The postsynaptic targets of cholinergic boutons in the rat neostriatum were assessed by examination in the electron microscope of boutons that were immunoreactive for choline acetyltransferase, the synthetic enzyme for acetylcholine. These boutons formed symmetrical synaptic specializations with neostriatal neurons. Of 209 immunoreactive synaptic boutons observed in random searches of the neostriatum, 45% made contact with dendritic shafts, 34% with dendritic spines, and 20% with neuronal perikarya. Many of the postsynaptic structures had ultrastructural characteristics of the most common type of striatal neuron, the medium-size densely spiny neuron. This was confirmed by the examination in the electron microscope of Golgi-impregnated medium-size spiny neurons from sections that had also been immunostained for choline acetyltransferase. Immunoreactive boutons formed symmetrical synaptic specializations with all parts of the neurons examined, i.e., perikarya, proximal and distal dendritic shafts, and dendritic spines. Two of the Golgi-impregnated medium-size spiny neurons that received input from the cholinergic boutons were also retrogradely labelled with horseradish peroxidase that had been injected into the substantia nigra, they were thus further characterized as striatonigral neurons. Similarly, seven retrogradely labelled perikarya of striatonigral neurons were found to receive input from the cholinergic boutons. It is concluded that cholinergic boutons in the neostriatum form synaptic specializations and that one of their major targets is the medium-size densely spiny neuron that projects to the substantia nigra. The topography of the cholinergic afferents of these cells is distinctly different from that of other boutons derived from local neurons and from boutons that form asymmetrical synaptic specializations, but it is similar to that of the dopaminergic boutons originating from neurons in the substantia nigra.

A method for concurrent local intracranial drug infusion and electrophysiological recording

A method employing a cannula-guidetube system with attached electrodes is described that permits infusions into discrete brain areas and simultaneous recording of multiunits or single units. This method can be used to determine the immediate local effects of drug infusion, and also to acquire electrophysiological feedback information in the process of placement and identification of cell populations at the injection site.

Muscarinic slow excitation and muscarinic inhibition of synaptic transmission in the rat neostriatum

Intracellular recording from neurones in rat neostriatal slices was used to compare the muscarinic effects of endogenous acetylcholine (ACh) released from cholinergic neostriatal synapses with the action of exogenously applied muscarinic agonists. Repetitive electrical stimulation in the neostriatum evoked a series of fast excitatory post-synaptic potentials (e.p.s.p.s) followed by a short, variable period of input resistance decrease. In the presence of the acetylcholinesterase (AChE) inhibitor, physostigmine, these potentials were followed by a slow e.p.s.p. which lasted about 60 s. Higher stimulus intensities were needed to elicit the slow e.p.s.p. than the fast e.p.s.p. The slow e.p.s.p. could not be observed after a single stimulus. Its amplitude was graded and increased with stimulus strength. The slow e.p.s.p. was blocked by the muscarinic antagonist atropine (10 microM) and by Ba2+ (100 microM). Input resistance increased during the slow e.p.s.p. Depolarization of the cell increased the size of the slow e.p.s.p. and hyperpolarization decreased it. Simultaneously, resting input resistance increased with membrane depolarization and decreased with membrane hyperpolarization. Repetitive intrastriatal stimulation was followed by a hyperpolarization instead of the depolarization at membrane potentials negative to -75 mV. Input resistance increased during this hyperpolarization as it did during the slow e.p.s.p. The slow e.p.s.p. persisted at membrane potentials of -70 to -80 mV if K+ concentration in the saline was reduced from 5 to 2 mM. In 10 mM-K+, the repetitive stimulation was followed by a hyperpolarization even at membrane potentials as low as -60 to -50 mV. Bath perfusion of high concentrations (100 microM) of muscarine or carbachol induced a sustained increase in the input resistance. The muscarinic agonists also reduced the amplitude of intrastriatally evoked fast e.p.s.p.s; however, this effect was transient and compensated by the increase in input resistance. The effects of the muscarinic agonists on input resistance and e.p.s.p. amplitude were antagonized by atropine (10 microM). Sustained decreases of e.p.s.p. amplitude were induced by the bath application of low doses (0.5-10 microM) of muscarine or carbachol. Input resistance was not altered. Atropine (1-10 microM) antagonized this effect. A sustained reduction of fast e.p.s.p. amplitude resulted also from inhibition of AChE by application of physostigmine (1-100 microM). Input resistance and neuronal excitability were not affected by AChE blockade.(ABSTRACT TRUNCATED AT 400 WORDS)

A dose response study of aggressive behavioral effects of intracerebroventricular injections of carbachol in cats

In this investigation, quantitative characteristics of vocalization, fighting, biting and convulsions elicited by carbachol injected into the cerebral ventricle of unanesthetized cats have been studied. Fighting, biting and convulsions were dose-dependent and long-lasting, their ED50 values being 0.008 mg, 0.018 mg and 0.047 mg respectively. The value of ED50 for vocalization is less than 0.005 mg. When using small doses the entire aggressive behavior pattern could be divided into its elements (vocalization, fighting, biting); however with larger doses it was not possible to obtain a separation of effects. These results support the view that there are central cholinoceptors of different sensitivity subserving aggressive behavior and convulsions. The fact that carbachol produces long-lasting aggressive behavioral effects further supports the view that the mechanisms activated by this cholinomimetic agent differ from conventional synaptic transmission. It follows then that cholinoceptive neurones activated by carbachol subserve physiological functions or pathological changes of long duration.

Possible involvement of opioid peptides of caudate nucleus in acupuncture analgesia

Rabbits chronically implanted with permanent cannulae were used in brain perfusion and microinjection experiments. Potassium iontophoresis applied to the rabbits' ear skin served as a noxious stimulus and the electric current used to elicit the defense response was taken as the pain threshold. The brain perfusate was analysed by radioreceptor assay and the level of endogenous opioid peptides (EOP) was expressed as competition rate. Electroacupuncture (EA) elicited an increase in pain threshold and a rise in EOP level in the perfusate from the anterior part of the head of the caudate nucleus (n = 10, P less than 0.002) but not from the posterior part. The pain threshold raising effect of EA could readily be reversed by microinjection of naloxone into the anterodorsal part of the head of the caudate (n = 12, P less than 0.01). With the techniques of multimicropipettes and microiontophoresis, caudate neuronal activity was recorded and examined in acute animals anesthetized with chloralose and urethane. It was found that microiontophoresed etorphine produced a strong, naloxone reversible inhibition of the spontaneous activity of the caudate neurons (61/162). Most etorphine sensitive neurons were identified in the dorsal part of the head of the caudate (P less than 0.01). EA produced inhibition of some etorphine sensitive neurons (16/35) and the inhibition could also be reversed by microiontophoresis of naloxone (4/8). The results indicate the participation of intracaudate opioid peptides in acupuncture analgesia.

The pharmacology of cholinergic excitatory responses in hippocampal pyramidal cells

The pharmacology of excitatory cholinergic responses in CA1 pyramidal cells was examined in detail using intracellular recording from the hippocampal slice preparation. Acetylcholine (ACh), carbachol, muscarine and pilocarpine depolarized the membrane potential with an associated increase in input resistance. In addition, these agonists increased cell firing and depressed the afterhyperpolarization (AHP) that is due to a calcium-activated potassium conductance. The weak effects of ACh (20-200 microM) were considerably enhanced by addition of eserine (1-10 microM). All excitatory effects were completely antagonized by atropine (0.1-1 microM) but unaffected by dihydro-beta-erythroidine (DHBE) and gallamine (1-50 microM). In contrast to the muscarinic agonists, the nicotinic agonists nicotine and dimethylphenylpiperazinium (DMPP) had no excitatory effects on CA1 pyramidal cells. Phenyltrimethylammonium (PTMA), at high concentrations did depolarize cells and depress the AHP but these effects were antagonized by atropine and not DHBE or gallamine. The action of the analogue of cyclic GMP, 8-bromo-cyclic GMP, although variable, mimicked the membrane effects of ACh in some cells and depressed the AHP in most cells. Intracellular injection of cyclic GMP routinely depressed the AHP. In summary, we have demonstrated two cholinergic responses of hippocampal pyramidal cells that are mediated purely by muscarinic receptors. We could find no evidence to support a mixed-type receptor or the involvement of nicotinic receptors in the excitation of hippocampal pyramidal cells to cholinergic agents.

Presynaptic muscarinic modulation of nicotinic excitation in the rat neostriatum

In rat neostriatal slices, cholinergic agents were tested for their effects on endogenous ACh release and on electrical activity. ACh release was evoked by 25 mM K+ during two 5-min periods between which a slice was allowed to rest for 20 min; drugs were present during the second stimulation period. In the absence of a cholinesterase inhibitor, only Ch outflow was monitored. For the recording of electrical activity, intrastriatal stimulation evoked field potentials which were monitored in the absence and presence of drugs in the perfusate. Atropine (1-100 microM) increased endogenous ACh release by 32-91% and effective doses were 10-fold lower in the presence of a cholinesterase inhibitor. Atropine also increased the amplitudes of synaptic population spikes in the field potentials. The muscarinic agonists muscarine (100 microM) and oxotremorine (25 and 100 microM) decreased endogenous ACh release. Atropine (10 microM) blocked the depressant effect of muscarine (100 microM). Muscarine (100 microM-1 mM) and oxotremorine (10-100 microM) decreased the electrically evoked excitation in the rat neostriatal slices, and their effects were reversed by atropine. Only higher concentrations of nicotine (1 and 5 mM) decreased the synaptic population spikes, but potassium-stimulated Ch outflow was not affected. It is concluded that in the neostriatum presynaptic muscarinic receptors modulate nicotinic excitation since potassium-stimulated ACh release and intrinsically evoked synaptic excitation are influenced by muscarinic drugs in the same way.

Caudate unit activity and somal diameters in intact and nigral lesioned cats

In a search for morphofunctional relationships in the head of the caudate nucleus (CN), we recorded extracellular unit activity in intact cats and in cats that had received bilateral injections of 6-OHDA into the substantia nigra (SN) 30 days previously. Only units firing spontaneously and continuously for 2 min were studied. In dorsal regions, potentials were small and iterative at almost constant intervals; the somal diameters were relatively small. In the ventrolateral region, potentials were bigger and appeared in bursts; somal diameters were significantly larger (p less than 0.05). For the centromedial region a histogram of numbers of neurons as a function of diameters revealed a Gaussian distribution extending from small to large neurons. Most dorsal neurons increased their firing rate to radial nerve, visual, SN, and/or nucleus centralis medialis (NCM) stimulation. Ventral neurons usually responded with excitation followed by long lasting inhibition, particularly to SN and NCM stimulation. A few neurons responded to all four inputs and some showed long-lasting potentiation in response to low frequency stimulation, suggesting a more general function. Greatest convergence (65%) was found for NCM and SN inputs. In lesioned cats, there was no SN driving, NCM's inhibitory actions almost disappeared, and the excitatory action of the other stimuli was reduced.

Effects of excitatory amino acids and their antagonists on membrane and action potentials of cat caudate neurones

The electrical activity of caudate neurones was recorded with intracellular electrodes in halothane anaesthetized cats. Agonists and antagonists of excitatory amino acid receptors were applied by micro-ionophoresis and their effects on membrane- and action potentials and on cortically evoked synaptic potentials evaluated. The agonists, L-aspartate (asp), L-glutamate (glu), N-methyl-DL-aspartate (NMA), quinolinate and quisqualate all depolarized the membrane, caused repetitive firing, reduced the apparent amplitude of the cortically evoked excitatory post-synaptic potentials (e.p.s.p.s) and increased the amplitude of the associated inhibitory post-synaptic potential. Two of the agonists, NMA and quinolinate, additionally caused the appearance of up to 500 ms long depolarizations (plateaus) on the falling phase of action potentials. These plateaus were seen in about two-thirds of the cells in this sample while in the other third the excitatory effects of NMA and quinolinate were indistinguishable from those of glu and quisqualate. The N-methyl-D-aspartate (NMDA) receptor antagonist D-alpha-aminoadipate (DAA) reversibly inhibited the effects of NMA and quinolinate but only on those cells where these two agents evoked action potential plateaus while on the same cells the effects of asp, glu and quisqualate were either only weakly antagonized or not affected. On cells not displaying plateaus to NMA or quinolinate none of the effects of the agonists could be antagonized by DAA. DAA applications that completely antagonized the effects of NMA never reduced the amplitudes of cortically evoked e.p.s.p.s. Cis-2,3-piperidine dicarboxylate also blocked the effects of NMA and asp at low application currents while at higher currents it enhanced the effects of glu or asp although still retaining its NMA antagonistic activity. High-frequency stimulation of the cortico-caudate pathway resulted in long-lasting depolarizations and repetitive firing, but plateaus of the type caused by NMA or quinolinate were not seen.

Scanning-integrating cytophotometric analyses of brain neuronal RNA and acetylcholinesterase in acute soman toxicated rats

Cytophotometric analyses of RNA and acetylcholinesterase responses of caudate and cerebrocortical neurons of soman toxicated rats were conducted to characterize impairments in regulatory aspects of neuronal metabolism occurring in the acute phase of cholinesterase impairment. There was a severe and dose-dependent suppression (20-60%) in neuronal acetylcholinesterase activity in both a.m. and p.m.-treated rats; no diurnal differences were apparent in control acetylcholinesterase levels or neuronal acetylcholinesterase responsiveness to soman toxication. RNA levels, however, were markedly higher in p.m. than in a.m. saline-treated controls. Soman depressed caudate neuron RNA contents in the afternoon, but not in the morning. Cerebrocortical neuron RNA levels were suppressed in both a.m. and p.m.-toxicated rats, although this RNA depletion was more severe in the afternoon. These results indicate that soman can elicit marked alterations in neuronal transcriptional-translational capabilities and that there are diurnal variations in cellular metabolic responsiveness to soman toxication. Although functional relationships between soman-induced cholinesterase inhibition and RNA depletion remain to be elucidated, depressed RNA metabolism appears to be a maladaptive response preventing rapid regeneration of cholinesterase following poisoning.

Release of dopamine and 5-hydroxytryptamine from rat striatal slices following activation of nicotinic cholinergic receptors

1. The administration of the nicotinic cholinergic agonists dimethylphenylpiperazinium iodide (DMPP) or nicotine caused a concentration dependent release of [3H] dopamine, [3H]5-hydroxytryptamine as well as endogenous dopamine and 5-hydroxytryptamine from superfused slices of rat striatum. 2. Release of both labelled and non-labelled transmitter was antagonized by the nicotinic antagonist, hexamethonium but not the muscarinic antagonist, atropine. 3. The present study provides additional evidence that nicotinic-cholinergic receptors are present in the mammalian central nervous system. 4. Activation of these nicotinic-cholinergic receptors in the striatum results in the release of both dopamine and 5-hydroxytryptamine.

Unit study in cat claustrum of the effects of iontophoretic neurotransmitters and correlations with the effects of activation of some afferent pathways

Glutamate (Glut), acetylcholine (ACh) and dopamine (DA) were iontophoretically applied on cat claustral neurons. Glut did not affect all the neurons; ACh had both excitatory and inhibitory effects, while DA was prevalently inhibitory. An analysis was made of the time-course of excitatory and inhibitory responses on the basis of the mean firing rate variations during and after ACh and DA release. Three types of responses are described for each drug: short lasting inhibition, long lasting inhibition and long lasting excitation. The experimental data were statistically elaborated. The effects of ACh and of DA were compared with those of activation obtained by sensorial peripheric and thalamic stimulations. ACh could be supposed to be the transmitter of most of the inhibitory terminals of these sensitive afferences to the claustrum.

Cholinergic excitation of mammalian hippocampal pyramidal cells

Responses of CA1 pyramidal neurons to ACh were recorded with intracellular microelectrodes utilizing the in vitro guinea pig hippocampal slice preparation. ACh was delivered by drop or iontophoretic application to stratum oriens or stratum radiatum. Threshold dose for drop application was 1 mM. An initial hyperpolarization of 3.1 +/- 1.8 (S.D.) mV associated with a decrease in membrane input resistance (RN) of 21 +/- 9% (S.D.) occurred in about half the cells. This result is consistent with a presynaptic action of ACh mediated through excitation of inhibitory interneurons. This interpretation was supported by recordings of cholinergic excitatory responses from presumed interneurons, and repetitive spontaneous IPSPs from pyramidal neurons during the hyperpolarization. ACh evoked a slow depolarization (14.3 +/- 10.8 (S.D.) mV) accompanied by a peak increase in apparent input resistance (Ra) of about 60% in the majority of cells. Large increases in spike frequency were associated with these events but action potential shape was unchanged. Plots of Ra versus membrane potential following ACh application revealed that Ra increases were proportionately higher at depolarized membrane potential levels (less than or equal to -70 mV) in some neurons. In these cells Ra was increased significantly at -60 mV (28%), but only 6% at -75 mV. These results are consistent with the conclusion that ACh reduces a voltage-dependent gK, distinct from delayed rectification. ACh also induced a non-voltage-dependent increase in Ra in some cells. ACh-evoked changes in Ra were long-lasting and gave rise to alterations in firing mode, with development of burst generation. ACh also transiently blocked after hyperpolarizations which followed spike trains in pyramidal neurons and presumed interneurons, an action which may be related to effects on a Ca2+-activated gK.

Bilateral asymmetrical changes in the nigral release of [3H]GABA induced by unilateral application of acetylcholine in the cat caudate nucleus

In halothane anaesthetized cats, a push-pull cannula was implanted into the right caudate nucleus (CN) and in each substantia nigra (SN). The release of [3H]GABA continuously formed from [3H]glutamine was estimated in each structure. Acetylcholine (ACh, 5 x 10(-5) M) added in presence of eserine (5 x 10(-5) M) for 50 min in the right caudate nucleus 2 h after the onset of superfusion with [3H]glutamine, stimulated the [3H]GABA release locally. The effect was biphasic when ACh application was made in the median two-thirds of the structure and it was monophasic and transient when the ACh application was restricted to the lateral part. ACh application in the right caudate nucleus also induced changes in [3H]GABA released in the anterior (pars reticulata) and posterior (pars compacta) parts of both SN. While [3H]GABA release was enhanced in the ipsilateral anterior SN, it was reduced in the contralateral anterior SN. Respective opposite effects were observed in the posterior parts of the ipsi- and contralateral SN. These bilateral asymmetrical changes in [3H]GABA release were not dependent on the site of ACh application in the right caudate nucleus. These results indicate that the facilitation of cholinergic transmission in one caudate nucleus influences in an opposite way the striato-nigral GABA neurones on both sides of the brain.

Sites and mechanisms for nicotine's action in the brain

A variety of pharmacologic, behavioral, and receptor-binding studies were performed in an effort to determine the mechanism and site of action of nicotine on the rat brain. When nicotine was given into the lateral or fourth ventricles or directly into the lateral vestibular nuclei of rats, it produced a characteristic prostration often accompanied by tonic seizures and body rotation along a longitudinal axis. Of a variety of brain areas studied, the prostration response could only be elicited from the lateral and, to a lesser extent, medial vestibular nuclei. The response could not be produced by a variety of cholinergic agonists or antagonized with nicotinic cholinergic antagonists, with the possible exception of mecamylamine. A good correlation was observed between the ability of nicotine analogues to antagonize the nicotine-induced prostration and their ability to compete with 3H-nicotine binding to rat brain membranes. 3H-nicotine binding had a high affinity, was stereoselective and concentrated in nerve endings and such brain regions as the thalamus, cerebrum, and hippocampus. When nicotine was administered intraventricularly to rats, it significantly elevated the threshold to an aversive shock. It was concluded that many of the central actions of nicotine could not be explained on the basis of traditional nicotinic cholinergic mechanisms.

Striatal cholinergic receptors and dyskinetic motor activity in the rat

An injection of D-tubocurarine into the rat striatum produces a complex motor syndrome resembling in part that induced by picrotoxin. The destruction of the dopaminergic terminals by 6-hydroxydopamine does not prevent these effects of D-tubocurarine on motor activity. Hence neither dopamine release nor the presynaptic acetylcholine receptors are responsible for the D-tubocurarine-induced movements. On the other hand, lesion of the striatum by kainic acid abolishes the motor abnormalities due to D-tubocurarine but not those due to picrotoxin injection. Therefore, the effects of picrotoxin might be attributable to an action on GABA receptors still present in the kainic acid-treated striatum, whereas the effects of D-tubocurarine might be due to its action on striatal postsynaptic acetylcholine receptors.

Anterograde and transsynaptic degeneration 'en cascade' in basal ganglia induced by intrastriatal injection of kainic acid: an animal analogue of Huntington's disease

Damage of striatal neurons by kainic acid (KA) induces an anterograde and transsynaptic degeneration 'en cascade' in the globus pallidus (GP) and substantia nigra (SN). By causing only degeneration of projections arising from KA-sensitive striatal neurons while sparing the connections of KA-resistant striatal neurons, the lesion-induced alterations of the basal ganglia show a characteristic pattern which bears a close resemblance with the neuropathological changes occurring in Huntington's disease: (1) severe degeneration of small and medium-sized striatal neurons, of pallidal neurons and the neurons of the pars reticulata of the SN, and (2) sparing of large striatal neurons, 'peripallidal' (nucleus basalis) neurons and neurons of the pars compacta of the SN. The probable interconnections of both the degenerated and the spared neuronal groups are discussed with respect to the present concept of the neuronal organization and biochemical neuroanatomy of the basal ganglia.

Intrinsic cholinergic excitation in the rat neostriatum: nicotinic and muscarinic receptors

An in vitro slice technique was employed to study the receptors involved in intrinsic cholinergic excitation in the rat neostriatum. The locally evoked synaptic potentials were suppressed by antinicotinic agents, mecamylamine (10 muM), d-tubocurarine (3 muM) or hexamethonium (100 muM), but not by the antimuscarinic agent atropine (100 muM). If the slices were exposed to an acetylcholinesterase (AChE)-inhibitor (paraoxon 1--20 muM, physostigmine 0.1--0.5 muM), the synaptic potentials were potentiated. The amplitude of the orthodromic population spike increased, and it was further facilitated when the stimulus frequencies were raised from 1--3 Hz to 10--30 Hz. The frequency facilitation following exposure to an AChE-inhibitor was blocked by atropine (1--100 muM). Intracellular recording indicated that a slow depolarizing potential caused the frequency potentiation of the orthodromic discharges. Apparently rat neostriatum is similar to cholinergic systems in sympathetic ganglia and spinal Renshaw cells, in that nicotinic receptors mediate fast excitation and muscarinic receptors mediate slow excitation.

Effects of iontophoretic 5-hydroxytryptamine on the unitary discharge frequency of caudate nucleus neurons in the rat

Microiontophoretic application of 5-hydroxytryptamine (5-HT) on rat caudate nucleus neurons has both facilitatory and inhibitory effects on the discharge frequency of the neurons; in many cases 5-HT has a two-phase action. An analysis was made of the behaviour of facilitatory and inhibitory responses in time considering the mean firing rate variations during and after 5-HT iontophoretic release. The experimental results were statistically elaborated.

The development of histochemically demonstrable cholinesterases in the rat neostriatum in vivo and in vitro

The development of acetylcholinesterase (AChE) and non-specific cholinesterase (NsChE) activity was studied in the rat neostriatum by the light and electron microscope using three thiocholine methods. The AChE activity was first demonstrable only in the lateral parts of the nucleus, and during the early postnatal development the most intense activity was in the cell bodies, whilst the typical intense staining of the neuropil of adult animals was seen in two-week-old rats. Two types of AChE-containing cells were observed in the neostriatum of rats younger than two weeks and in cultures of newborn rat neostriatal cells. The neuropil of the cultures showed weak activity in the membranes of thin preterminal processes. In the neuropil of old rats, NsChE activity was present in the membranes of nerve cell processes. The capillary endothelial cells of newborn rats contained both AChE and NsChE. During subsequent development, the AChE activity disappeared, whilst for NsChE no change was seen in the distribution of activity seen in newborn or young adult rats less than three months old.

Muscarinic receptors in the central nervous system of the rat. I. Technique for autoradiographic localization of the binding of [3H]propylbenzilylcholine mustard and its distribution in the forebrain

[3H]Propylbenzilylcholine mustard ([3H]PrBCM) is a synthetic, potent muscarinic antagonist, which binds specifically and irreversibly by means of a covalent linkage to muscarinic receptors. Ten micrometer coronal cryostat sections taken through unfixed rat brain at the level of the maximum extent of the caudate nucleus were mounted on glass slides and incubated with 2.4 nM [3H]PrBCM at 30 degrees C for 25 min. They showed a total binding of 3250 pmol/g protein, of which 2130 pmol/g protein was sensitive to pretreatment with 10-6 M atropine. The specific (atropine-sensitive) binding was saturable. Saturation was reached at 15 min, with a rate constant of 1.3 x 106 M-1 sec-1. Binding was unaffected by drugs acting at nicotinic receptors (D-tubocurarine, hexamethonium), or by physostigmine, but was inhibited by muscarinic drugs (pilocarpine, oxotremorine, 3-quinuclidinylbenzilate). Postfixation for 15 min in Carnoy's fixative reduced the specific binding by 10% and the non-specific by 50%. Prefixation (i.e. before incubation with [3H]PrBCM) with any fixatives containing formaldehyde largely prevented specific binding, but a range of concentrations of glutaraldehyde (2% to 0.05%) caused only small reductions in specific binding (e.g. 0.1% glutaraldehyde caused only a 6% reduction). Clear, regionally specific patterns of localization of specific label in light microscope autoradiographs could be obtained from cryostat sections prefixed with 0.1% glutaraldehyde, incubated with 2.4 nM [3H]PrBCM for 15 min at 30 degrees C, and postfixed for 15 min in Carnoy's solution. Of the 105 forebrain areas studied 12 had grain counts between 6 and 9 times the non-specific level and a further 30 had counts 4 to 6 times non-specific. The higher grain counts were in the external plexiform layer of the olfactory bulb, anterior olfactory nucleus, olfactory tubercle, pyriform cortex, stratum radiatum of the hippocampus, stratum moleculare of the dentate gyrus, lateral amygdaloid nucleus, cortico-amygdaloid transition zone, anteroventral thalamic nucleus, hypothalamic supraoptic nucleus, caudate-putamen, nucleus accumbens, and in laminae 3 and 6 of the neocortex (parietal region). There were high grain densities over the choroid plexus the lateral but not the third or fourth ventricles.

Improvement of learned behavior through cholinergic stimulation of the caudate nucleus

To test the hypothesis that cholinergic activity of the head of the caudate nucleus (CN) is involved in the processes underlying instrumental performance, the effects of microinjections of several doses of choline into this structure on lever pressing behavior were assessed. A dose-dependent modification of performance was found: small doses improve and large doses impair level pressing, while choline applications into the parietal cortex were without effect. The facilitatory effects were reproduced by microinjections of acetylcholine into the CN. These data further support our working hypothesis.

Biochemical evidence for the presence of presynaptic receptors on dopaminergic nerve terminals

Two compartments of striatal synaptosome dopamine were identified by differential labelling with the isotopic presursors, L-tyrosine and Dopa, and from specific radioactivity measurement. Either, endogenous or exogenous L-tyrosine could provide a source for the dopamine pool synthesised and released in response to K+ depolarization, whereas external DOPA did not enter this pool. Acetylcholine (0.1 mM) in the presence of neostigmine (0.1 mg/ml) increased dopamine turnover as shown by increased formation of [14C] dopamine and [14C] DOPAC from [14C] DOPA. Haloperidol (0.65 mM) did not affect the size of dopamine pools but increased the conversion of [14C] DOPA to [14C] dopamine and the formation of [14C] DOPAC. Acetylcholine stimulated the release of dopamine from synaptosomes, which effect could be modified by both muscarinic and nicotinic antagonists. In the presence of the muscarinic antagonist, atropine, acetylcholine stimulated dopamine release, whereas in the presence of the nicotinic antagonists, hexamethonium (0.2 mM) or alpha-bungaro-toxin (0.188 muM), acetylcholine inhibited dopamine release. This showed that presynaptic cholinergic receptors were operational, excitatory nicotinic receptors in the former case and inhibitory muscarinic in the latter. The nicotinic receptor was shown to be saturable and to bind specifically 11.2 fmoles of [3H] alpha-bungarotoxin per mg. protein which could be prevented by hexamethonium or D-tubocurarine.

Cholinergic mechanisms involved in head-shaking of infant rats

Central cholinergic mechanisms involved in D-amphetamine induced head-shaking (H-S) were explored in 9-day-old albino rats using anticholinergic, anticholinesterase and cholinomimetic drugs. Scopolamine (5 mg/kg, IP) blocks both spontaneous and D-amphetamine induced H-S. Physostigmine (0.10 mg/kg, IP), but not neostigmine, increases D-amphetamine induced H-S up to 400%. Pilocarpine (1-10 mg/kg, IP) per se induces H-S and strongly potentiates the amphetamine H-S effect. Cholinergic--catecholaminergic interactions in the CNS are discussed in relation to the expression of this motor item.