The effects of acetylcholine and of synaptic stimulation on the sensorimotor cortex of cats. II. Comparison of the neuronal responses to reticular and other stimuli

The influence of acetylcholine and atropine on the temporary connection in neuronal populations of the motor cortex

The activity of neurons of the sensorimotor cortex during the paired combination of stimulations of brain structures (the medial lemniscus, the reticular nucleus of the midbrain tegmentum, and the pyramidal tract), with an interstimulus interval of 1.2 sec, was investigated in awake nonimmobilized rabbits. During the omission of the reinforcing stimulus at a place of its expected delivery, a complicated complex of reorganizations of the impulse activity of the neurons develops, consisting of the reproduction of responses and changes in impulse activity which differ in configuration from them, and which usually appear at later periods. The direct application of acetylcholine to the cortex facilitates the manifestation of both types of reorganizations of the neuronal activity. The application, on the other hand, of atropine suppresses primarily the second type of reorganizations. In addition, acetylcholine increases the total duration of these electrical indices of the temporary connection of the developed reactions, while atropine decreases it.

Pharmacological analysis of conditioning in sensorimotor cortex neurons in a model

In awake mobile rabbits, with electrodes implanted in the medial lemniscus, midbrain tegmental reticular nucleus, and pyramidal tract, combined stimulation of two brain of two brain structures resulted in elaboration of conditional connections in sensorimotor cortex neuronal populations. The main criterion of the conditioning was the appearance of changes in the neuronal activity on omission of the second stimulus. These changes represented a complex of electrical events, some of which were similar to and others different from the evoked responses to the second stimulus. Application of atropine, sulfate, chlorpromazine hydrochloride, serotonin creatinine sulfate, and gamma-aminobutyric acid (GABA) to the cortex at the site of the recording exerted a modulating effect on the conditional neuronal activity patterns. Of the above substances, GABA and atropine had the most pronounced effect. The GABA removed the short-latency components of the conditional changes which were similar to evoked responses. The atropine abolished the long-latency changes which differed from evoked responses.

Muscarinic agonists modulate spontaneous and evoked unit discharge in auditory cortex of cat

The present experiments studied the effects of cholinergic agonists and antagonists on the spontaneous and acoustic-evoked discharge of auditory cortical neurons and examined whether these effects were mediated by muscarinic cholinergic receptors. A primary focus of this report is the analysis of specific effects of these agents on the spontaneous and tone-evoked discharge and on different temporal components of the evoked discharge. Single neurons were recorded in the auditory cortex of chronically prepared, awake cats with multibarrel micropipette electrodes. The responses to acoustic stimuli were obtained before, during, and following continuous ejection of cholinergic agonist or antagonists by micropressure. The mean rate of discharge of the neurons was analyzed quantitatively for spontaneous discharge and for different peaks of the tone-evoked PSTH corresponding to tone "on," "through," and "off" responses. Acetylcholine (ACh) and acetyl-beta-methacholine (MCh) produced significant effects on spontaneous activity in 72% and 68% of neurons tested, respectively. Tone-evoked responses were effected in 92% and 82% of cells tested, respectively. The ability of these agonists to modify spontaneous or evoked activity was dose-dependent. Agonist effects on spontaneous and evoked activity were often different in the same cell; however, effects on spontaneous activity did predict effects on "through" responses. The most common effect of ACh or MCh on evoked activity was facilitation of the tone "on" response. For neurons with multicomponent discharge patterns in response to tones, the agonists had nonuniform effects on different response components. However, the effects of ACh on the "on" and "off" responses covaried. Hence cholinergic agonists produce heterogeneous, selective effects on different components of the responses of auditory cortical neurons rather than simple increases or decreases in discharge level. The effects of cholinergic agonists were modified in the presence of atropine. The effects of MCh were blocked by atropine in a higher proportion of cases than those of ACh.

The role of the anterior intralaminar nuclei and N-methyl D-aspartate receptors in the generation of spontaneous bursts in rat neocortical neurones

The nature of spontaneous unitary activity of rat neocortex was investigated during slow wave sleep and urethane anaesthesia. Neurones in layer IV and V locations fired in a burst-pause pattern at a low burst repetition rate (0.5-4 per second) during both stage 3/4 sleep and urethane anaesthesia. Occasionally an alternative mode of firing (spindle clusters), associated with focal spindle wave activity, was also found to occur in both states. Using dual microelectrode implants it was found that the onset times of bursts (but not spindle clusters), coincided in the same and opposing cortices, whether in functionally similar or disparate areas. The highest probability was that burst onsets occurred simultaneously (resolution = 2.56 ms, interquartile range = 40 ms). Spontaneous unitary activity was investigated in the thalamus for temporal correlation with spontaneous unitary activity in neocortex under urethane anaesthesia. Neurones of the anterior intralaminar group (aIL) consistently fired in a burst-pause pattern such that each aIL burst showed a strong tendency to precede a cortical burst. Unilateral electrical stimulation of the aIL nuclei evoked widespread bilateral entrainment of cortical bursts. In contrast stimulation of VPl, or cutaneous sites, evoked only short duration spike responses together with burst abolition in the appropriate restricted Sml area. Ionophoresis of NMDA (N-Methyl D-Aspartate) onto Sm1 neurones increased the probability of cortical burst responses to aIL stimulation in addition to decreasing the latency by 20-40 ms (n = 11). Ionophoresis of 2APV (2-amino 5-phosphono valeric acid) caused simultaneous abolition of spontaneous cortical bursts and bursts evoked by aIL stimulation. Short latency responses to cutaneous and VPl stimulation were unaffected by ionophoresis of 2APV sufficient to cause burst elimination, suggesting that this pathway does not operate via a 2APV sensitive receptor mechanism. Anatomical features of the aIL nuclei and their overall cortical projection pattern are discussed in relationship to these findings. The activation of cortical NMDA/APV sensitive receptors by aIL afferents in the "spontaneous" generation of bursts in cortical cells is discussed.

Development of cholinergic markers in mouse forebrain. I. Choline acetyltransferase enzyme activity and acetylcholinesterase histochemistry

Measurements of choline acetyltransferase (ChAT) activity were made during the development of the neocortical cholinergic innervation, and correlated with the development of the acetylcholinesterase (AChE) staining pattern in mouse cerebral cortex and several other areas of the forebrain between the time of initial onset and maturity ChAT activity can first be measured on postnatal day 6 (P6). The enzyme reaches 40% of adult activity by P18 and adult values by 7 weeks postnatal. The onset of AChE staining varies for different regions of the forebrain and for various areas within the cerebral cortex. The earliest appearance of AChE is seen in several basal forebrain nuclei including the striatum, the ventromedial region of the globus pallidus and the hypothalamus on embryonic day 18 (E18). In neocortex and olfactory cortex, AChE-stained axons are seen in the white matter before birth, but do not enter cingulate cortex and hippocampus until P2. By P2. almost all areas of the basal forebrain and diencephalon have acquired some AChE staining pattern. The adult distribution of AChE staining is reached by 3 weeks postnatal in all areas of the forebrain. Adult cerebral cortex shows a characteristic pattern of alternating AChE dense and AChE sparse bands which vary in depth depending on the cortical area. The cortical banding pattern develops in an 'inside-out' fashion, starting in layer VI and gradually entering more superficial layers. In parallel with the AChE pattern of development in cortex, transient AChE staining can be observed in some thalamic nuclei and in some forebrain fiber systems. In the neostriatum patches of intense AChE staining first develop along the ventrolateral border, then spread throughout the whole nucleus and finally coalesce to a uniform high density over the entire neostriatum. We discuss the close spatial and temporal correspondence between AChE pattern development and reported data on synapse formation, and speculate on the role of the cortical cholinergic system in development.

Excitatory effect of acetylcholine on different types of neurons in the first somatosensory neocortex of the rat: laminar distribution and pharmacological characteristics

In rats anaesthetized with either urethane, pentobarbital or fluothane the effects of acetylcholine, cholinergic agonists and antagonists (applied by iontophoresis) were studied on single cortical neurons of first somatosensory region. The laminar distribution of the neurons excited by acetylcholine was determined by the reconstruction of each electrode track based on a dye-deposit made at the last recording site. Neurons were identified using antidromic stimulation of the pyramidal tract, the ventrobasal thalamus and the corpus callosum. Neurons excited by acetylcholine could be segregated into two groups: one encompassing layer Vb and the upper part of layer VI, the other more deeply located at the limit between the cerebral cortex and the subjacent white matter. Neuronal responses to glutamate and nicotine, unlike those to actylcholine were evenly distributed in the cortex. Pyramidal tract neurons had corticothalamic neurons were frequently excited by acetylcholine and were shown to be located with the first group of acetylcholine sensitive neurons. Commissural neurons were rarely excited by acetylcholine and were not restricted to either group. The analysis of neuronal responses to acetylcholine and various agonists (carbachol, nicotine, acetyl-beta-methylcholine, carbamyl-beta-methylcholine, butyrylcholine) and antagonists (atropine, mecamylamine) revealed a prominent but not exclusive muscarine character. It is included (i) that cortical neurons of first somatosensory cortex which are excited by acetylcholine belong to two populations, one consisting, at least in part, of projection neurons (upper group) and the other of interneurons (lower group); (ii) that cortical acetylcholine receptors are of a 'mixed' type strongly weighted toward the muscarinic side.

Effects of acetylcholine and cyclic GMP on input resistance of cortical neurons in awake cats

The effects on input resistance (Rm) of extracellular iontophoresis of acetylcholine (ACh) and of intracellular iontophoresis of cyclic GMP (cGMP) were studied in neurons of the coronal-pericruciate cortex of awake cats. Control studies were also conducted including iontophoresis of saline extracellularly and 5'-GMP intracellularly. (1) Substantial increases in Rm occurred in approximately half the neurons given ACh or cGMP. (2) In the absence of associated repetitive spike discharge induced by intracellular injection of depolarizing current pulses during iontophoretic applications, the increases in Rm were transient occurring in less than 30 sec and lasting 4--5 min. (3) With associated current-induced spike discharge, the increases in Rm persisted for as long as the neurons could be held -- up to 1.5 h maximally. (4) Rm was not increased if saline was substituted for ACh, if 5'-GMP was substituted for cGMP, or if the neuron was only discharged repeatedly. (5) The magnitude and time course of both transient and persistent increases in Rm were comparable between cells given ACh or cGMP and whether action potentials and resting potentials were greater than or equal to 40 mV (average 47 mV)* or were less.

Localization of calcium channels in Paramecium caudatum

1. Electrical recordings from Paramecium caudatum were made after removal of the cilia with chloral hydrate and during ciliary regrowth to study the electrical properties of that portion of the surface membrane enclosing the ciliary axoneme. 2. Removal of the somatic cilia (a 50% reduction in membrane surface area) results in an almost complete elimination of the regenerative Ca response, all-or-none Ba2+ spike, and delayed rectification. 3. A twofold increase in input resistance resulted from the 50% reduction in membrane surface area. 4. The electrical properties remained unchanged, despite prolonged exposure to the chloral hydrate, until the cilia were mechanically removed. 5. Restoration of the Ca response accompanied ciliary regrowth, so that complete excitability returns when the cilia regain their original lengths. 6. It is concluded that the voltage-sensitive Ca channels are localized to that portion of surface membrane surrounding the cilia. 7. Measurements of membrane constants before and after deciliation and estimations of the cable constants of a single cilium suggest that the cilia of Paramecium may be fully isopotential along their length and with the major cell compartment.

Brain stem stimulation and the acetylcholine-evoked inhibition of neurones in the feline nucleus reticularis thalami

1. In cats anaesthetized with halothane and nitrous oxide, the responses to iontophoretically applied acetylcholine (ACh) and to high-frequency stimulation of the mid-brain reticular formation (MRF) were tested on spontaneously active neurones in the nucleus reticularis thalami and underlying ventrobasal complex.2. The initial response to MRF stimulation of 90% of the ACh-inhibited neurones found in the region of the dorsolateral nucleus reticularis was an inhibition. Conversely, the initial response of 82% of the ACh-excited neurones in the ventrobasal complex was an excitation. Neurones in the rostral pole of the nucleus reticularis were inhibited by both ACh and RMF stimulation.3. The mean latency (and s.e. of mean) for the MRF-evoked inhibition was 13.7 +/- 3.2 ms (n = 42) and that for the MRF-evoked excitation, 44.1 +/- 4.2 ms (n = 35).4. The ACh-evoked inhibitions were blocked by iontophoretic atropine, in doses that did not block amino acid-evoked inhibition. In twenty-four ACh-inhibited neurones the effect of iontophoretic atropine was tested on MRF-evoked inhibition. In all twenty-four neurones atropine had no effect on the early phase of MRF-evoked inhibition but weakly antagonized the late phase of inhibition in nine of fourteen neurones.5. Interspike-interval histograms showed that the firing pattern of neurones in the nucleus reticularis was characterized by periods of prolonged, high-frequency bursting. Both the ACh-evoked inhibitions and the late phase of MRF-evoked inhibitions were accompanied by an increased burst activity. In contrast, iontophoretic atropine tended to suppress burst activity.6. The possibility is discussed that electrical stimulation of the MRF activates an inhibitory cholinergic projection to the nucleus reticularis. Since neurones of the nucleus reticularis have been shown to inhibit thalamic relay cells, activation of this inhibitory pathway may play a role in MRF-evoked facilitation of thalamo-cortical relay transmission and the associated electrocortical desynchronization.