Duration of trace processes in the neocortex of rabbits

Changes of pyramidal tract (PT) response after short tetanization, similar to natural stimulation conditions, were analysed in unanaesthetized and nonimmobilized rabbits. PT response recording revealed a long-term (1 h and more) potentiation of monosynaptic neocortical reactions. Predominant better expressed and more preserved increase of synaptic (N) component provides evidence to the conjecture that the basic mechanism of the long-term potentiation consists in the rise of efficiency of excitatory synaptic connections. Less protracted and differently directed changes of D-component permit to consider that excitability change of neurones may be only an additional mechanism of the long-term potentiation. Such features of neocortical long-term potentiation were revealed as its low-frequency depression (at test stimuli repetition) and its spontaneous restoration after depression.     

Raised excitability produced in cortical neurons by reinforced stimulation of the lateral hypothalamus

Response was recorded in the pyramidal tract (PT) under three experimental situations modelling the shaping of conditioned reflex (CR) during experiments on unrestrained but unanesthetized rabbits. The first paradigm consisted of direct stimulation of two points on the sensorimotor cortex, the second of the same stimuli combine with electrical stimulation (used as additional reinforcement) of the lateral hypothalamus (LH), and the third of LH stimulation in response to a rise occurring in PT response to above control level (modelling instrumental CR). An overall increase in the monosynaptic wave indicative of altered efficacy of synaptic connections was most commonly observed under all these conditions. Increase in the component directly reflecting pyramidal neuronal excitation appeared significantly more pronounced in the second and third than in the first experimental paradigm. The data obtained would point to reinforced efficacy of excitatory synaptic connections as the principal mechanism of CR, while the changed quality of electrical excitability at the membrane of cortical neurons reflects mechanisms underlying the contribution of reinforcement triggered by LH activation in cortical reordering of the motivational/emotional component of reinforcement.Higher Nervous Activity and Neurophysiology Research Institute, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 21, No. 6, pp. 805–811, November–December, 1989.     

Functional significance of the serotoninergic influence on neuronal activity of the somatosensory cortex in 12-day-old kittens

Monoamines, which participate in synaptic transmission as transmitters, also accomplish the modulation of neuronal activity. The role of serotonin (5-hydroxytryptamine--5-HT) was investigated in 8 to 14-day-old kittens by means of iontophoretic application onto neurones of the somatosensory cerebral cortex. The most typical response was the inhibition of neuronal activity. Another type of reaction was generated by inhibitory interneurones. After the microiontophoretic application of 5-HT, the tonic response of cortical neurones to the stimulation of the sciatic nerve changed into a phasic response. It is being suggested that the application of 5-HT to cortical neurones increases the excitability of inhibitory neurones. Hence, the serotoninergic regulation of neuronal activity in the somatosensory cortex may be operational from the 11th to the 12th day of postnatal life in cats.     

Reflection of the plastic properties of very simple neuronal assemblies in the statistical characteristics of the spike activity of their elements. Monosynaptically connected neurons

Changes of cross-correlation histograms (CCH) of impulse trains and of mean interspike intervals (ISI) of monosynaptically connected neurones under changes of interneuronal connection efficiency, neuronal excitability and action on these neurones of independent irregular afferent synaptic inflows, were studied by methods of mathematical and biomathematical modelling of synaptic neuronal interaction (computer-controlled experiment on mollusc neurones). It was shown that statistical of increase of efficiency of monosynaptic excitatory or inhibitory interneuronal connection (amplitude enhancement of corresponding postsynaptic potential) is an increase of the main peak or trough of normalized CCH of impulse trains accompanied by a decrease of mean ISIs of both neurones.     

Effect of serotonin on the activity of the neurons involved in the realization of the avoidance reflex of the snail

Bath application of 10(-5) mol/l of serotonin (5-HT) elicited a 50% increase of summary EPSPs recorded in command neurones for avoidance behaviour. No significant changes of rest potential and input resistance were seen in these cells. 5-HT evoked an increase of spontaneous level of firing in motoneurones involved in the same reflex, as well as an increase in the number of spikes which paralleled increase of EPSPs to the same stimulus in command neurones. In sensory cells, presynaptic to the command neurones, application of 5-HT evoked a significant increase of excitability and of input resistance. Monosynaptic EPSPs recorded in the command neurones showed a 40% increase after serotonin application. It is concluded that the major locus of plastic changes evoked by 5-HT application in the neuronal chain underlying avoidance reflex is the synaptic contact between sensory and command neurones.     

Reflection of the plastic properties of monosynaptically interconnected neurons in the statistical characteristics of their spike activity

By mathematical and biomathematical methods of neuronal interaction modelling, changes were studied of cross-correlation histograms (CCH) of impulse flows and of average interimpulse intervals of monosynaptically interconnected neurones, at changes of efficiency of forward and backward connections, of excitability of neurones and of summate action on them of independent random afferent synaptic inflows. It is shown, that a single sign of efficiency increase of monosynaptic excitatory or inhibitory connection between neurones (amplitude increase of the corresponding postsynaptic potential) consists in amplitude increase of the main peak or trough the rated CCH of their impulse flows, followed by a decrease of average interspike intervals of both neurones.     

Reflection of the plastic properties of the simplest neuronal associations in statistical characteristics of the spike activity of their elements. Polysynaptically linked neurons

Changes of crosscorrelation histograms of trains of action potentials and mean interspike intervals of polysynaptically connected neurones were studied by means of mathematical modelling of synaptic neuronal interaction at changes of efficiency of interneuronal monosynaptic connections, at changes of neuronal excitability, and at changes of total action on them of independent disorderly afferent synaptic inflows. Increase of amplitude of the main maximum (minimum) of the normalized crosscorrelation histogram of trains of action potentials accompanied by reduction of mean interspike intervals of both neurones, was shown to be a unsignificant indication of an increase of efficiency of polysynaptic excitatory (inhibitory) connections between the neurones (due to modification of synapses or to a change of the functional state of interneurones).     

The active electrogenesis of the command neurons in the defensive behavior of the mollusk during conditioning]

In the paper changes of active electrogenesis of the command neurones of defensive closure of snail pneumostome at elaboration, extinction and repeated elaboration of classic conditioned defensive reflex to tactile stimulus was described; the tactile stimulation of other point of the body served as a differentiating stimulus. During the increase of biological significance of conditioned stimulus as a result of learning the stimulation of the command neurones in response to this stimulus was raised. At the same time the neurones showed decreased excitability in response to differentiating stimulus. Possible mechanisms of quick reconstruction of neurones excitability and functional value of PA generation threshold changes were discussed.     

The functional role of enhanced cellular excitability and synaptic efficiency in the neocortex during learning]

In experiments with noncurarized and unanaesthetized rabbits was recorded pyramidal tract response in the course of conditioning of direct stimulations of the two points of the cortical surface. The data obtained point to temporary specificity in manifestation of the membrane and synaptic plasticity, to participation of these mechanisms in the processes proceeding in both cortical representations of paired stimuli, and to predominantly undirected changes of a degree of their involvement in both cortical areas. At the early stage of conditioning were demonstrated all the characteristics of the dominant state developing at this stage, and at the late one those of differential conditioning. A conclusion is drown that the reinforcement through the membrane plasticity leads to initial dominant increase of cellular excitability. On the background of the latter by means of summation mechanism the conditions are created for excitation transmission from the sensory link of a new bond to its motor output. Underlined by the mechanisms of synaptic plasticity gradual reorganization of the excitatory and inhibitory connections to the output elements of conditioned response determines and consolidates specialized character of the elaborated reaction.     

Effect of ginseng preparations on the activity of identified neurons of Heliz lucorum snails

It has been demonstrated that the effects of aqueous extracts from the native ginseng and extracts of genseng tissue culture on the activity of identified neurones are identical. Neuronal excitability, tested intracellularly, significantly increases to the 60th minute of drug application, whereas gradually developing depolarization simultaneously disappears. Rhythmic orthodromic stimulation revealed the increase in neuronal responses during ginseng perfusion, the synaptic efficiency remaining constant. It is suggested that changes in transmembrane potential level evoked by administration of ginseng preparations are not related to changes in the excitability. Changes in the adaptive capacities of the neurones in invertebrate animals are due to nonspecific endoneuronal shifts in cellular metabolism induced by ginseng administation.     

Effect of endothelin-1 on the excitability of rat cortical and hippocampal slices in vitro

Endothelin-1 (ET-1) is a neuroactive protein produced in most brain cell types and participates in regulation of cerebral blood flow and blood pressure. In addition to its vascular effects, ET-1 affects synaptic and nonsynaptic neuronal and glial functions. Direct application of ET-1 to the hippocampus of immature rats results in cerebral ischemia, acute seizures, and epileptogenesis. Here, we investigated whether ET-1 itself modifies the excitability of hippocampal and cortical circuitry and whether acute seizures observed in vivo are due to nonvascular actions of ET-1. We used acute hippocampal and cortical slices that were preincubated with ET-1 (20 μM) for electrophysiological recordings. None of the slices preincubated with ET-1 exhibited spontaneous epileptic activity. The slope of the stimulus intensity-evoked response (input-output) curve and shape of the evoked response did not differ between ET-1-pretreated and control groups, suggesting no changes in excitability after ET-1 treatment. The threshold for eliciting an evoked response was not significantly increased in either hippocampal or cortical regions when pretreated with ET-1. Our data suggest that acute seizures after intrahippocampal application of ET-1 in rats are likely caused by ischemia rather than by a direct action of ET-1 on brain tissue.     

Phorbol esters that activate protein kinase C induce long-term changes of membrane excitability and postsynaptic currents in neocortical neurons

Intracellularly injected tumor promoter phorbol esters (PhEs) that activate protein kinase C (PKC) increased the excitability and altered the postsynaptic responses of neurons of the motor cortex of awake cats. PhEs increased the amplitude and duration of EPSPs and decreased the amplitude and durations of IPSPs. No consistent changes in resting membrane parameters that would account for these modifications were found. Corresponding changes in peak excitatory and inhibitory postsynaptic currents (EPSCs, IPSCs) were measured directly with the single electrode voltage clamp technique. The changes lasted for 50 min or longer. Quantitative analysis of EPSCs in response to ventrolateral thalamic stimulation and IPSCs in response to pyramidal tract stimulation made in a subgroup of fast PT cells suggested that PhE acted within the injected neuron rather than presynaptically to alter the synaptic currents. PhE also reduced a voltage-dependent, 3-aminopyridine sensitive fast outward current (IA) and an apamin and EGTA sensitive slow outward current (IK(Ca]. Control injections of a phorbol ester that did not activate PKC failed to induce changes in synaptic responses or resting membrane properties. These observations provide the first evidence that activation of PKC, in vivo, can induce long-lasting changes in synaptic responses of neocortical neurons by direct modification of postsynaptic ion channel conductivities.     

Long-term changes in synaptic efficiency and cellular excitability during learning

Temporal analysis of changes of pyramidal tract response on the model of prolonged potentiation revealed the significant role of the mechanism of increase of the cell general excitability at the initial stage of trace processes formation ("dominant" analogue) what probably contributes to better consolidation of basic CR mechanism--the increase of synaptic links efficiency. During the elaboration of CR to stimulation of two cortical points the increase of cellular excitability was more expressed in those experiments where the reinforcement was supplemented by stimulation of the lateral hypothalamus eliciting alimentary reaction. These data allow to consider the membrane plasticity to be a cortical mechanism of motivational reinforcement component determining dominant properties of CR generalization stage.     

Dynamic defensive and feeding reactions to the acquisition of sensitization in edible snails]

In snails changes of defensive and alimentary behaviour and of reactions of command and modulator neurones of these kinds of behaviour were studied during elaboration of sensitization. After a single action of 50% chinine solution on mollusc's head, a short-term (during 50-70 min) and long-term (hours or days) facilitation was found of animals defensive reactions and responses of command neurones of defensive behaviour to tactile and chemical sensory stimuli. Alimentary behaviour of the snails and reactions of modulator neurones of alimentary behaviour to carrot juice presentation were inhibited in sensitized animals. Dynamics differences of defensive responses to tactile and chemical stimuli in the same sensitized animals were observed. Short-term responses facilitation under sensitization correlated chiefly with depolarization of the membrane potential of defensive behaviour neurones and with an increase of plasmatic membrane excitability. Prolonged facilitation of responses was due mainly to a change of effectiveness of synaptic transmission. The described model of sensitization elaboration can be a base for studying of molecular-cellular mechanisms, underlying the learning.     

Reactions of cat motor cortex neurons to stimulation of the pyramidal tract and ventroposterolateral thalamic nuclei

Responses of neurons of motor cortex evoked by stimulations of pyramidal tract (PT) and ventroposterolateral (VPL) nucleus of thalamus were studied in cats immobilized by Myorelaxin. Antidromic spikes were found in 22.6% and in 9.9% of cortical cells when PT and VPL were stimulated, respectively. Fast- and slow-conducting PT-neurones could be differentiated according to antidromic excitation latencies. PT stimulation evoked EPSPs in 46.3% of studied neurones and VPL stimulation--in 48.2% ones. Monosynaptic EPSPs were identified in responses of fast- and slow-conducting PT-units and of neurones projecting in VPL; mechanisms and functional role of such reactions are discussed. Di- and polysynaptic IPSPs were evoked in 74.5% of units by PT stimulation and in 94.4%--by VPL stimulation. Three groups of IPSPs were classified with durations to 120, 130-280 and more than 300 ms. Duration of PT-evoked IPSPs was higher in cortical neurones from surface layers and VPL-evoked ones--in units localized in deep layers.     

Cholecystokinin and cholecystokinin antagonists enhance postsynaptic excitability in the dentate gyrus

The sulfated and unsulfated octapeptide cholecystokinin (CCK) sequences and the pancreatic CCK antagonists, CR 1409 and benzotript, were applied iontophoretically in the rat dentate gyrus granular layer while the response evoked by single pulse stimulation of the perforant path was recorded. The stimulating current was varied and the resulting relationship between the slope of the response (input) against the population spike amplitude (output) was used as a measure of excitability at the granule cell synapse. All four test compounds shifted the input/output curve to the left indicating an increase in postsynaptic excitability. These results thus imply that endogenous CCK acts at the central type of CCK receptor to modulate cortical input to granule cells by reducing the threshold for synaptic excitation.     

Neuronal transmission stimulates the phosphorylation of Kv1.4 channel at Ser229 through protein kinase A1

Phosphorylation of voltage-gated K+ channels (Kv) is involved in regulation of neuronal excitability, synaptic plasticity and neuronal survival. Among Kv channels expressed in the CNS, Kv1.4 is located in the soma, dendrite and axon terminus of neurones in most regions of the brain. Here, we show that Ser229 found within the highly conserved T1 domain of Kv1.4 in cultured rat cortical neurones is phosphorylated by protein kinase A (PKA), as demonstrated by in vitro protein kinase assay and Western blotting with a polyclonal antibody specific against phosphorylated Ser229. Glutamate, high concentrations of K+ or K+ channel blockers known to increase neurotransmission all stimulated the phosphorylation of Kv1.4 at Ser229 via N-methyl-D-aspartate (NMDA), but not alpha-amino-3-hydroxy-5-methylisoxazole-4-proprionic acid (AMPA) receptor, whereas tetradotoxin (TTX), known to block neuronal transmission, and depletion of extracellular Ca2+ inhibited phosphorylation induced by tetraethylammonium (TEA), a non-selective K+ channel blocker. Mutation of Ser229 to Ala229 enhanced the current density. Taken together, elevation of the neuronal transmission stimulates the phosphorylation of Kv1.4 at Ser229 via the Ca2+ influx through NMDA receptor. Thus, it is possible that neuronal transmission regulates neuronal excitability partially through the phosphorylation of Kv1.4S229.     

Dynamics of changes in the excitability of Helix lucorum neurons in response to an analog of vasopressin

Application of desglycine-arginine-vasopressin to spontaneously nonactive command neurones of the snail's defensive reflex in the process of low-frequency (2-4 min intervals) intracellular stimulation led under certain conditions to an increase of excitability that was expressed in the shortening of latency of action potential generation, increase of the number of action potentials in response to a stimulus of fixed value, increase of membrane resistance, lowering of critical level of membrane depolarization and amplifying of pacemaker activity. However in spite of unidirectional changes of all the recorded parameters, the increases of values, opposite to the latency, did not correlate with the increases of membrane resistance and correlated well with the changes of depolarization critical level. If desglycine arginine-vasopressin was added to the medium during worsening of the neurones' excitability was probably caused by the influence of desglycine-arginine-vasopressin on the membrane active properties.     

Effect of the microiontophoretic application of acetylcholine on the formation of conditioned reactions in motor cortex neurons

In alert rabbits the activity of the motor cortex neurones was recorded with simultaneous application of acetylcholine to them in the process of defensive conditioning. Conditioned reorganization, mainly of activation type, were found in 60% of neurones. In most cases conditionally reacting cells were sensitive to acetylcholine. Ionophoretic application of the transmitter promoted the formation of conditioned neuronal responses and increased them in comparison with conditioned reactions evoked in absence of acetylcholine. It is supposed that the influence of acetylcholine on conditioned cellular process is realized due to its action on the state of excitability of the cortical neurones.     

The analysis of the impulse activity of 2 neurons monosynaptically excitable by a 3rd using cross-correlation histograms and Cox's method. The potential for detecting neuronal and synaptic plasticity

By a method of mathematical modelling exogenic stationary random single impulse activity was reproduced of two neurones (N1 and N2), monosynaptically excited by a third one (N3). Value P12, defined from cross-correlation histogram and Cox coefficient beta 12 were used to evaluate the degree of dependence of N1 and N2 impulse trains. Dynamics of P12, beta 12 and of values of P1*, P2* and P3* proportional to corresponding mean interimpulse intervals of N1, N2 and N3, was studied under changes of efficiency of interneuronal connections, neurones excitability and summate action on them of independent random afferent synaptic inflows. It has been shown that the increase (decrease) of P12 or beta 12 accompanied by decrease (increase) of P1* and P2* is a sign of plastic change or N3 discharges frequency, or a sign of plastic changes of the amplitude of excited postsynaptic potentials elicited by these discharges.