Magdolna Szente

Long-lasting potentiation of synaptic transmission requires postnaptic modifications in the neocortex

The mechanisms of associative long-lasting potentiation (LLP) of excitatory postsynaptic potentials (EPSPs) were studied in the motor cortex of anesthetized cats. Mono- and oligosynaptic EPSPs were evoked by stimulations of thalamic VL nucleus, pyramidal tract, callosal and somatosensory system and paired with orthodromic, antidromic or current-induced action potentials. EPSP-spike stimulus pairs with 0.1-0.2 Hz frequency and 0-200 ms interstimulus intervals induced increases in the amplitudes and durations of EPSPs for 40-60 min or longer after 20-50 pairings. The LLP was prevented when postsynaptic firing was blocked by intracellular current injection or by juxtasomatic application of gamma-aminobutyric acid. LLP was also prevented when the level of intracellular free calcium was lowered by the intracellular injection of the calcium chelator EGTA or when neuronal transport was blocked by the intracellular injection of colchicine. Neither EGTA nor colchicine blocked postsynaptic firing. Thus, these findings show that LLP in the neocortex is a postsynaptic phenomenon which requires conjunctive pre- and postsynaptic activity, adequate levels of intracellular free calcium, and functional intracellular transport.

Involvement of Gap Junctions in the Manifestation and Control of the Duration of Seizures in Rats In Vivo

Summary:  Purpose: The possible role of gap junctions in the manifestation and control of the duration of seizures was tested on the 4‐aminopyridine–induced epilepsy model in rats in vivo, by using electrophysiologic, pharmacologic, and molecular biologic techniques.

Properties of associative long-lasting potentiation induced by cellular conditioning in the motor cortex of conscious cats

Mechanisms of long-lasting potentiation of synaptic responses induced in the thalamocortical and recurrent collateral pathways of the pyramidal tract were studied in intracellular recordings from the motor cortex of unanesthetized, chronically implanted cats. The observations provide the first description of long-lasting potentiation in the unanesthetized neocortex in vivo. Monosynaptic excitatory postsynaptic potentials of 2-5 mV in amplitude were evoked as test responses by stimulation of the pyramidal tract and thalamic ventrolateral nucleus at 0.1-0.5 Hz frequency. Pressure microinjections of drugs and ions were also performed during intracellular recordings. In the first series of experiments, test synaptic responses were paired with intracellular current injection-induced action potentials at an interstimulus interval set between 0-200 ms and 0.1-0.5 Hz frequency. Pairings (30-100 x) induced long-lasting potentiation of the test responses in 58% of cells. The increased synaptic responses typically initiated action potentials and their potentiation usually lasted over the period of recordings. Increases in amplitude of synaptic responses were not correlated with statistically significant changes in electrical membrane properties (resting potential, input resistance, time constant, spike threshold) or parameters of action potentials and their afterpotentials. The failure to induce increases in synaptic efficacy by unpaired stimuli (pseudoconditioning) demonstrated the associative property of the long-lasting potentiation. In a second series of experiments, differential cell conditioning was employed. This paradigm induced long-lasting potentiation of the explicitly paired synaptic response without noticeable modification of unpaired or pseudorandomly paired synaptic responses tested conjointly in the same neuron. These observations demonstrated the input-specificity of long-lasting potentiation. In a third series of experiments, subthreshold depolarizing current pulses were summated with synaptic responses to induce firing in the recorded neuron during pairing. Long-lasting potentiation occurred in 55% of the summated synaptic inputs. Pseudoconditioning did not induce synaptic potentiation in these cells. In a fourth series of experiments, conditioning was employed in neurons in which firing activity was suppressed by an intracellularly injected lidocaine derivative. Long-lasting potentiation was induced in 50% of the attempts when synaptic responses were paired with current-induced depolarizations greater than 30 mV. These results suggest that postsynaptic induction of long-lasting synaptic potentiation can be successful in the absence of postsynaptic sodium spikes in neurons of the motor cortex in vivo. In a fifth series of experiments, homosynaptic high-frequency tetanization (80-200 Hz for 5-15 s) was applied to the thalamocortical and recurrent pyramidal afferents.(ABSTRACT TRUNCATED AT 400 WORDS)

Involvement of electrical coupling in the in vivo ictal epileptiform activity induced by 4-aminopyridine in the neocortex.

In the present study we have investigated the possible role of gap junctions in the induction and manifestation of 4-aminopyridine-induced acute seizure activity both at the primary focus and at the mirror focus in anaesthetized rats by combining electrophysiological, pharmacological and molecular biological techniques. In the course of the intracellular recordings, unusual firing patterns that are assumed to be mediated by electrical coupling and appearing either randomly or in close time-locked manner with the ictal discharges were observed. In another series of experiments, a significant decrease in the intensity of seizure activity of the already active epileptic foci was detected when electrical synaptic transmission was blocked by carbenoxolone either at the primary focus or at the mirror focus. When electrical synaptic transmission was depressed relative to the initial baseline prior to the induction of epileptic focus, only a mild influence on the induction of seizure discharges occurred. The role of the gap junctional communication in the epileptiform activity was further investigated by following the expression pattern of two connexin genes. Both, connexin-32 and connexin-43 mRNA levels were significantly elevated at the primary focus as well as at the mirror focus, after 60 min of repeated ictal discharges. We conclude that gap junction communication probably became a part of the neuronal synchronization both in the primary and in the secondarily-induced acute epileptiform activity in the neocortex in vivo. These results, together with earlier observations, indicate a direction for the development of new drugs targeting gap junctions for therapeutic intervention.

Quinine, a Blocker of Neuronal Cx36 Channels, Suppresses Seizure Activity in Rat Neocortex In Vivo

Summary:  Purpose: The selective contribution of neuronal gap junction (GJ) communication via connexin 36 (Cx36) channels to epileptogenesis and to the maintenance and propagation of seizures was investigated in both the primary focus and the mirror focus by using pharmacologic approaches with the 4‐aminopyridine in vivo epilepsy model.

Mechanism of aminopyridine-induced ictal seizure activity in the cat neocortex

Intracellular recordings were obtained from neurons in the motor cortex of anesthetized cats in order to examine membrane and synaptic processes involved in aminopyridine (AP)-induced ictal seizure activity. Depolarizing and hyperpolarizing membrane potential sequences which behaved as large, synchronized excitatory and inhibitory postsynaptic potentials, were found to accompany the ictal seizure potentials. After several repetitions of the seizure attack, partial responses, bursts and depolarizing plateaus with spike inactivation occurred. In layers IV and V we found non-pyramidal tract neurons showing endogenous bursting ability activated by AP. These neurons seemed to be the initiators of the rhythmic synchronous activity of the epileptic neuron population. Our results suggest that AP-induced epileptogenesis represents an adequate model of ictal events in the neocortex.

The Functional Significance of Gap Junction Channels in the Epileptogenicity and Seizure Susceptibility of Juvenile Rats

Summary:  Purpose: The functional significance of gap‐junction (GJ) channels in seizure susceptibility and induction and maintenance of seizures in the developing rat brain was investigated on the 4‐aminopyridine (4‐AP) in vivo epilepsy model.

Aminopyridine--induced seizure activity.

Typical seizure activity can be induced by applying 3-aminopyridine to the surface of the cat cortex. The well known characteristics of epileptiform discharges were readily observed by simultaneous recording from both the surface and deeper layers.

Seizure, neurotransmitter release, and gene expression are closely related in the striatum of 4-aminopyridine-treated rats

The present experiments aimed to compare the length of seizure activity with the time-related increase of transmitter release and the induction of c-fos gene expression in the striatum of the rat. Anesthetized Wistar rats were intraperitoneally treated with 7 mg/kg 4-aminopyridine, and the transmitter levels in the striatum were measured by means of in vivo microdialysis, 30, 60, 90, 120, and 150 min following the treatment. Striatal and neocortical electric activity was monitored with depth and surface electrodes, respectively. The expression level of the c-fos gene was estimated by counting the striatal c-fos-immunostained cell nuclei at the time intervals of the microdialysis. 4-aminopyridine elicited high-frequency seizure discharges in the EEG and significantly increased glutamate, aspartate, GABA, serotonin, noradrenaline, and dopamine levels in the extracellular dialysates. The number of c-fos-stained cell nuclei in the striatum displayed a prolonged increase, showing significantly elevated numbers throughout the experiment. The increase of c-fos expression in time correlated best with the increase of glutamate release, which was also significantly elevated at every sampling time. The GABA release, culminating at 60 min after the seizure onset, correlated best with the cessation of the electrographic seizure. Aspartate, norepinephrine, serotonin, and dopamine displayed transient but significant elevations. We conclude that glutamate plays the essential role (most probably through ionotropic and metabotropic receptors) in the extracellular signaling, which eventually leads to intracellular cascades and c-fos gene expression in the striatum during convulsions.

Cellular mechanisms of neocortical secondary epileptogenesis

Firing activity, membrane parameters and postsynaptic responses were studied by recording intracellularly from different types of neurons during the development of a secondary neocortical epileptiform focus (mirror focus, Mf) contralateral to the site of an aminopyridine-induced focus (primary focus, Pf) in anesthetized rats. Three different stages in the development of secondary epileptogenesis were observed. (i) in the Pf stage epileptiform discharges appeared only in the ECoG recorded from the Pf, but neurons in the Mf showed reduced firing activity; (ii) in the Pf + Mf stage, synchronous ictal epileptiform activity occurred in the Pf and Mf. Changes in the balance between inhibition and excitation, appearance of novel electrophysiological phenomena (e.g. antidromic like action potentials, PDS (paroxysmal depolarization shift) potentials, rebound bursts), enhanced intrinsic bursting, and a transition from regular spiking to bursting were observed at the cellular level; (iii) in the Pf/Mf stage in 10% of the animals, the surface epileptic discharges were in synchrony with cellular activity in the Mf but were temporally independent of Pf activity, suggesting that during secondary epileptogenesis the Pf and the Mf can have underlying epileptogenic mechanisms which are different in origin.