High-frequency population oscillations are predicted to occur in hippocampal pyramidal neuronal networks interconnected by axoaxonal gap junctions.

In hippocampal slices, high-frequency (125-333 Hz) synchronized oscillations have been shown to occur amongst populations of pyramidal neurons, in a manner that is independent of chemical synaptic transmission, but which is dependent upon gap junctions. At the intracellular level, high-frequency oscillations are associated with full-sized action potentials and with fast prepotentials. Using simulations of two pyramidal neurons, we previously argued that the submillisecond synchrony, and the rapid time-course of fast prepotentials, could be explained, in principle, if the requisite gap junctions were located between pyramidal cell axons. Here, we use network simulations (3072 pyramidal cells) to explore further the hypothesis that gap junctions occur between axons and could explain high-frequency oscillations. We show that, in randomly connected networks with an average of two gap junctions per cell, or less, synchronized network bursts can arise without chemical synapses, with frequencies in the experimentally observed range (spectral peaks 125-182 Hz). These bursts are associated with fast prepotentials (or partial spikes and spikelets) as observed in physiological recordings. The critical assumptions we must make for the oscillations to occur are: (i) there is a background of ectopic axonal spikes, which can occur at low frequency (one event per 25 s per axon); (ii) the gap junction resistance is small enough that a spike in one axon can induce a spike in the coupled axon at short latency (in the model, a resistance of 273 M omega works, with an associated latency of 0.25 ms). We predict that axoaxonal gap junctions, in combination with recurrent excitatory synapses, can induce the occurrence of high-frequency population spikes superimposed on epileptiform field potentials.     

Use-dependent shift from inhibitory to excitatory GABAA receptor action in SP-O interneurons in the rat hippocampal CA3 area

Cortical inhibitory interneurons set the pace of synchronous neuronal oscillations implicated in synaptic plasticity and various cognitive functions. The hyperpolarizing nature of inhibitory postsynaptic potentials (IPSPs) in interneurons has been considered crucial for the generation of oscillations at beta (15-30 Hz) and gamma (30-100 Hz) frequency. Hippocampal basket cells and axo-axonic cells in stratum pyramidale-oriens (S-PO) play a central role in the synchronization of the local interneuronal network as well as in pacing of glutamatergic principal cell firing. A lack of conventional forms of plasticity in excitatory synapses onto interneurons facilitates their function as stable neuronal oscillators. We have used gramicidin-perforated and whole cell clamp recordings to study properties of GABAAR-mediated transmission in CA3 SP-O interneurons and in CA3 pyramidal cells in rat hippocampal slices during electrical 5- to 100-Hz stimulation and during spontaneous activity. We show that GABAergic synapses onto SP-O interneurons can easily switch their mode from inhibitory to excitatory during heightened activity. This is based on a depolarizing shift in the GABAA reversal potential (EGABA-A), which is much faster and more pronounced in interneurons than in pyramidal cells. We also found that the shift in interneuronal function was frequency dependent, being most prominent at 20- to 40-Hz activation of the GABAergic synapses. After 40-Hz tetanic stimulation (100 pulses), GABAA responses remained depolarizing for approximately 45 s in the interneurons, promoting bursting in the GABAergic network. Hyperpolarizing EGABA-A was restored >60 s after the stimulus train. Similar but spontaneous GABAergic bursting was induced by application of 4-aminopyridine (100 microM) to slices. A shift to depolarizing IPSPs by the GABAAR permeant weak acid anion formate provoked interneuronal population bursting, supporting the role of GABAergic excitation in burst generation. Furthermore, depolarizing GABAergic potentials and synchronous interneuronal bursting were enhanced by pentobarbital (100 microM), a positive allosteric modulator of GABAARs, and were blocked by picrotoxin (100 microM). Intriguingly, GABAergic bursts displayed short (<1 s) oscillations at 15-40 Hz, even though only depolarizing GABAA responses were seen in the SP-O interneurons. This beta-gamma rhythmicity in the interneuron network was dependent on electrotonic coupling, and was abolished by blockade of gap junctions with carbenoxolone (200 microM). Results here implicate the rapid activity-dependent degradation of hyperpolarizing IPSPs in SP-O interneurons in setting the temporal limits for a given interneuron to participate in beta-gamma oscillations synchronized by GABAergic synapses. Furthermore, they imply that mutual GABAergic excitation provided by interneurons may be an integral part in the function of neuronal networks. We suggest that the use-dependent change in EGABA-A could represent a form of short-term plasticity in interneurons promoting coherent and sustained activation of local GABAergic networks.     

Sharp wave-like activity in the hippocampus in vitro in mice lacking the gap junction protein connexin 36

Bath application of kainate (100-300 nM) induced a persistent gamma-frequency (30-80 Hz) oscillation that could be recorded in stratum radiatum of the CA3 region in vitro. We have previously described that in knockout mice lacking the gap junction protein connexin 36 (Cx36KO), gamma-frequency oscillations are reduced but still present. We now demonstrate that in the Cx36KO mice, but not in wild-type (WT), large population field excitatory postsynaptic potentials, or sharp wave-burst discharges, also occurred during the on-going gamma-frequency oscillation. These spontaneous burst discharges were not seen in WT mice. Burst discharges in the Cx36KO mice occurred with a mean frequency of 0.23 +/- 0.11 Hz and were accompanied by a series of fast (approximately 60-115 Hz) population spikes or "ripple" oscillations in many recordings. Intracellular recordings from CA3 pyramidal cells showed that the burst discharges consisted of a depolarizing response and presumed coupling potentials (spikelets) could occasionally be seen either before or during the burst discharge. The burst discharges occurring in Cx36KO mice were sensitive to gap junctions blockers as they were fully abolished by carbenoxolone (200 microM). In control mice we made several attempts to replicate this pattern of sharp wave activity/ripples occurring with the on-going kainate-evoked gamma-frequency oscillation by manipulating synaptic and electrical signaling. Partial disruption of inhibition, in control slices, by bath application of the gamma-aminobutyric acid-A (GABA(A)) receptor antagonist bicuculline (1-4 microM) completely abolished all gamma-frequency activity before any burst discharges occurred. Increasing the number of open gap junctions in control slices by using trimethylamine (TMA; 2-10 mM), in conjunction with kainate, failed to elicit any sharp wave bursts or fast ripples. However, bath application of the potassium channel blocker 4-aminopyridine (4-AP; 20-80 microM) produced a pattern of activity in control mice (13/16 slices), consisting of burst discharges occurring in conjunction with kainate-evoked gamma-frequency oscillations, that was similar to that seen in Cx36KO mice. In a few cases (n = 9) the burst discharges were accompanied by fast ripple oscillations. Carbenoxolone also fully blocked the 4-AP-evoked burst discharges (n = 5). Our results show that disruption of electrical signaling in the interneuronal network can, in the presence of kainate, lead to the spontaneous generation of sharp wave/ripple activity similar to that observed in vivo. This suggests a complex role for electrically coupled interneurons in the generation of hippocampal network activity.     

Inhibitory role of dentate hilus neurons in guinea pig hippocampal slice

1. Current and voltage-clamp recording of CA3/CA4 pyramidal neurons, hilar neurons, and granule cells or pairs of these neurons were used to study the generation of Cl-dependent and K-dependent inhibitory postsynaptic potentials (IPSPs) in the guinea pig hippocampal slice preparation. 2. A sequence of an early Cl-dependent and a late K-dependent IPSP was evoked in CA3 neurons by electrical stimulation from the stratum moleculare of the dentate gyrus, the hilus, and the stratum oriens/alveus. Blockade of glutamatergic excitation by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10 microM) and D(-)-2-amino-5-phosphonovaleric acid (APV, 30 microM) abolished IPSPs evoked from the stratum moleculare of the dentate gyrus, but IPSPs could still be evoked from the hilus and the stratum oriens/alveus. 3. Repetitive giant IPSPs, which consisted of Cl-dependent and K-dependent components, were evoked by bath application of 4-aminopyridine (4-AP, 10-50 microM) in CA3 neurons and in granule cells. Giant IPSPs were blocked by bath-applied tetrodotoxin (TTX). In addition, 4-AP hyperpolarized CA3 neurons in a Cl-dependent and picrotoxin-sensitive way. 4. Focal application of TTX to the dentate gyrus or the hilus considerably reduced the amplitude of giant IPSPs evoked by 4-AP in CA3 neurons. In hilar neurons, 4-AP evoked repetitive bursts, eventually, but not necessarily intermingled with giant IPSPs. Bursts were observed in hilar neurons in presence as well as absence of CNQX and APV. 5. In paired recordings, bursts in hilar neurons induced by 4-AP occurred simultaneously to giant IPSPs in granule cells and CA3 neurons, and giant IPSPs in granule cells occurred simultaneously to giant IPSPs in CA3 neurons. Blockade of glutamatergic excitation by CNQX and APV did not abolish this synchrony. 6. 4-AP-evoked Cl- and K-dependent IPSPs were, unlike electrically evoked IPSPs, not strictly coupled: some 20% of large IPSPs and up to 90% of small IPSPs were either Cl or K dependent. In granule cells K-dependent components either preceded or followed Cl-dependent components. 7. K-dependent IPSPs only could be evoked in CA3 neurons by focal application of 4-AP (1 mM) to the hilus, the stratum lacunosum moleculare or the stratum pyramidale. Wash out of Ca for 15-20 min blocked the Cl-dependent but not the K-dependent component of giant IPSPs evoked by bath-applied 4-AP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Direct depolarization and antidromic action potentials transiently suppress dendritic IPSPs in hippocampal CA1 pyramidal cells

Whole-cell current-clamp recordings were made from distal dendrites of rat hippocampal CA1 pyramidal cells. Following depolarization of the dendritic membrane by direct injection of current pulses or by back-propagating action potentials elicited by antidromic stimulation, evoked gamma-aminobutyric acid-A (GABA(A)) receptor-mediated inhibitory postsynaptic potentials (IPSPs) were transiently suppressed. This suppression had properties similar to depolarization-induced suppression of inhibition (DSI): it was enhanced by carbachol, blocked by dendritic hyperpolarization sufficient to prevent action potential invasion, and reduced by 4-aminopyridine (4-AP) application. Thus DSI or a DSI-like process can be recorded in CA1 distal dendrites. Moreover, localized application of TTX to stratum pyramidale blocked somatic action potentials and somatic IPSPs, but not dendritic IPSPs or DSI induced by direct dendritic depolarization, suggesting DSI is expressed in part in the dendrites. These data extend the potential physiological roles of DSI.     

Simulations of cortical pyramidal neurons synchronized by inhibitory interneurons.

1. The interaction between inhibitory interneurons and cortical pyramidal neurons was studied by use of computer simulations to test whether inhibitory interneurons could assist in phase-locking postsynaptic cells. Two models were used: a simplified model, which included only 3 membrane channels, and a detailed 11-channel model. 2. The 11-channel model included most of the ion channels known to be present in neocortical pyramidal neurons as well as calcium diffusion and other membrane mechanisms. The kinetics for the channels were obtained from voltage-clamp studies in a variety of preparations. The parameters were then adjusted to produce repetitive bursting similar to that seen in some cortical pyramidal cells entrained during visual stimulation. 3. Phase-locking to a train of inhibitory postsynaptic potentials (IPSPs) located on or near the soma was observed in the 3-channel model cell subjected to random synaptic bombardment. In the 11-channel model, phase-locking due to multiple IPSPs was compared with phase-locking due to multiple excitatory postsynaptic potentials (EPSPs). Phase-locking began to occur when 20% of the IPSPs (20/100) or 40% of the EPSPs (4,000/10,000) were synchronized. The exact percentages differed with different 11-channel models, but either EPSPs or IPSPs would generally produce entrainment with approximately 40% synchronization. Thus 40 inhibitory boutons had an effect equivalent to 4,000 excitatory boutons in producing phase-locking. 4. Phase-locking with IPSPs in these models was possible because the IPSPs could cause either an increase or a decrease in firing rate over a limited range. The IPSPs served a modulatory role, increasing the rate of firing in some cases and decreasing it in others, depending on the state of the cell. 5. We examined frequency entrainment by IPSPs. In the 3-channel model, frequency entrainment of a postsynaptic cell was observed with a rapid train of strong (20-100 nS), brief, compound IPSPs. A 40-Hz compound IPSP train of 60 nS entrained cells having initial firing rates between 32 and 47 Hz. Below this range, cells could be partially entrained. Above the range, entrainment would fail. Frequency entrainment in the 3-channel model generally occurred on the first cycle after onset of the IPSPs. 6. Phase-locking and frequency entrainment were less robust in the 11-channel model. This was partly because bursts rather than individual spikes were being entrained. A 40-Hz, 90-nS compound IPSP train entrained a model cell upward from 34 Hz. Downward frequency entrainment also occurred.(ABSTRACT TRUNCATED AT 400 WORDS)     

Physiology and pharmacology of epileptiform activity induced by 4-aminopyridine in rat hippocampal slices.

1. Conventional intracellular and extracellular recording techniques were used to investigate the physiology and pharmacology of epileptiform bursts induced by 4-aminopyridine (4-AP, 50 microM) in the CA3 area of rat hippocampal slices maintained in vitro. 2. 4-AP-induced epileptiform bursts, consisting of a 25-to 80-ms depolarizing shift of the neuronal membrane associated with three to six fast action potentials, occurred at the frequency of 0.61 +/- 0.29 (SD)/s. The bursts were generated synchronously by CA3 neurons and were triggered by giant excitatory postsynaptic potentials (EPSPs). A second type of spontaneous activity consisting of a slow depolarization also occurred but at a lower rate (0.04 +/- 0.2/s). 3. The effects of 4-AP on EPSPs and inhibitory postsynaptic potentials (IPSPs) evoked by mossy fiber stimulation were studied on neurons impaled with a mixture of K acetate and 2(triethyl-amino)-N-(2,6-dimethylphenyl) acetamide (QX-314)-filled microelectrodes. After the addition of 4-AP, the EPSP became potentiated and was followed by the appearance of a giant EPSP. This giant EPSP completely obscured the early IPSP recorded under control conditions and inverted at -32 +/- 3.9 mV (n = 4), suggesting that both inhibitory and excitatory conductances were involved in its generation. IPSPs evoked by Schaffer collateral stimulation increased in amplitude and duration after 4-AP application. 4. The spontaneous field bursts and the stimulus-induced giant EPSP induced by 4-AP were not affected by N-methyl-D-aspartate (NMDA) receptor antagonists 3-3 (2-carboxy piperazine-4-yl) propyl-1-phosphonate (CPP) and DL-2-amino-5-phosphonovalerate (APV) but were blocked by quisqualate/kainate receptor antagonists 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) and 6,7-dinitroquinoxaline-2,3-dione (DNQX). CNQX also abolished the presence of small spontaneously occurring EPSPs, thereby disclosing the presence of bicuculline-sensitive (BMI, 20 microM) IPSPs. 5. Small, nonsynchronous EPSPs played an important role in the generation of 4-AP-induced epileptiform activity. 1) After the addition of 4-AP, small EPSPs appeared randomly on the baseline and then became clustered to produce a depolarizing envelope of irregular shape that progressively formed an epileptiform burst, 2) These small EPSPs were more numerous in the 100 ms period that preceded burst onset. 3) The frequency of occurrence of small EPSPs was positively correlated with the frequency of occurrence of synchronous bursts. 4) Small EPSPs and bursts were similarly decreased after the addition of different concentrations of CNQX (IC50 in both cases of approximately 1.2 microM).(ABSTRACT TRUNCATED AT 400 WORDS)     

Carbenoxolone depresses spontaneous epileptiform activity in the CA1 region of rat hippocampal slices

An important contributor to the generation of epileptiform activity is the synchronization of burst firing in a group of neurons. The aim of this study was to investigate whether gap junctions are involved in this synchrony using an in vitro model of epileptiform activity. Hippocampal slices (400 μm) were prepared from female Sprague–Dawley rats (120–170 g). The perfusion of slices with a medium containing no added magnesium and 4-aminopyridine (50 μM) resulted in the generation of spontaneous bursts of population spikes of a fast frequency along with less frequent negative-going bursts. The frequency of the bursts produced was consistent over a 3 h period. Carbenoxolone (100 μM), a gap junction blocker and mineralocorticoid agonist, perfused for 75 min, reduced the frequency of both types of spontaneous burst activity. Perfusion of spironolactone (1 μM), a mineralocorticosteroid antagonist, for 15 min prior to and during carbenoxolone perfusion did not alter the ability of carbenoxolone to depress the frequency of spontaneous activity. The incubation of hippocampal slices in carbenoxolone prior to recording increased the time taken for the spontaneous activity to start on change to the zero magnesium/4-aminopyridine medium and decreased the total number of spontaneous bursts over the first 60 min period.

The ability of carbenoxolone to delay induction of epileptiform activity and reduce established epileptiform activity suggests that gap junctions contribute to the synchronization of neuronal firing in this model.     

Bursts and hyperexcitability in non-myelinated axons of the rat hippocampus

Strict control over the initiation of action potentials is the primary task of a neuron. One way to lose proper spike control is to create several spikes, a burst, when only one should be initiated. We describe a new site for burst initiation in rat hippocampal CA3 neurons: the Schaffer collateral axons. These axons lack myelin, are long, extremely thin, and form synapses along their entire paths, features typical for many, if not most cortical axons in the mammalian brain. We used hippocampal slices and recorded from individual Schaffer collateral axons. We found that single action potentials were converted into bursts of two to six action potentials after blocking 4-aminopyridine (4-AP) sensitive K⁺ channels. The CA3 somata and initial part of their axons were surgically removed in these experiments, leading to the conclusion that the bursts were initiated far out in the axons. This conclusion was supported by two additional kinds of experiments. First, local application of 4-AP to one out of two stimulated axonal branches of the same neuron showed bursting only at the 4-AP exposed branch. Second, intracellular recordings from CA3 somata showed that some spontaneously occurring bursts were resistant to somatic hyperpolarization. We then investigated a hyperexcitable period that follows individual spikes in the Schaffer collaterals. With extracellular excitability testing, we showed that the time course of this hyperexcitability was compatible with that of the bursts, so this hyperexcitability could be the underlying cause of the bursts. Furthermore, the hyperexcitability was enhanced by low doses of 4-AP (20 μM), α-dendrotoxin (α-DTX) or margatoxin (MgTX). Kv1.2 containing channels may therefore dampen the hyperexcitability, but because bursting was observed only at high 4-AP concentration (1 mM), other channels may be needed to prevent axonal bursting.     

Patterns of spontaneous activity and morphology of interneuron types in organotypic cortex and thalamus-cortex cultures.

The physiological and morphological properties of interneurons in infragranular layers of rat visual cortex have been studied in organotypic cortex monocultures and thalamus-cortex co-cultures using intracellular recordings and biocytin injections. Cultures were prepared at the day of birth and maintained for up to 20 weeks. Twenty-nine interneurons of different types were characterized, in addition to 170 pyramidal neurons. The cultures developed a considerable degree of synaptically driven "spontaneous" bioelectric activity without epileptiform activity. Interneurons in cortex monocultures and thalamus-cortex co-cultures had the same physiological and morphological properties, and also pyramidal cell properties were not different in the two culture conditions. All interneurons and the majority of pyramidal cells displayed synaptically driven action potentials. The physiological group of fast-spiking interneurons included large basket cells, columnar basket cells (two cells with an arcade axon) and horizontally bitufted cells. The physiological group of slow-spiking interneurons included Martinotti cells and a "long-axon" cell. Analyses of the temporal patterns of activity revealed that fast-spiking interneurons have higher rates of spontaneous activity than slow-spiking interneurons and pyramidal cells. Furthermore, fast-spiking interneurons fired spontaneous bursts of action potentials in the gamma frequency range. We conclude from these findings that physiological and morphological properties of interneurons in organotypic mono- and co-cultures match those of interneurons characterized in vivo or in acute slice preparations, and they maintain in long-term cultures a well-balanced state of excitation and inhibition. This suggests that cortex-intrinsic or cell-autonomous mechanisms are sufficient for the expression of cell type-specific electrophysiological properties in the absence of afferents or sensory input.     

Picrotoxin- and 4-aminopyridine-induced activity in hilar neurons in the guinea pig hippocampal slice

1. Paired extra- and intracellular recording was used to study the activity of neurons in the dentate hilus and their interaction with CA3/CA4 pyramidal neurons and granule cells during picrotoxin- or 4-aminopyridine (4-AP)-induced rhythmical activity in the guinea pig hippocampal slice. 2. Picrotoxin induced synchronous repetitive population spikes in the CA3, CA4, and hilar region, but no extracellular activity in the granule cell layer. 4-AP induced rhythmically occurring positive field-potential waves in the CA3, CA4, and granular layer coincident to negative/positive field potentials in the hilus. 3. Picrotoxin-induced activity originated in the CA3 area and subsequently appeared in the CA4 and hilar region, whereas 4-AP-induced activity appeared simultaneously in all subfields. 4. Blockade of fast glutamatergic excitation by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10 microM) blocked the picrotoxin-induced activity but not the 4-AP-induced activity. 5. Focal application of tetrodotoxin (TTX) between area CA3 and CA4 blocked picrotoxin-induced activity in the CA4 and hilar region but decoupled 4-AP-induced activity in the CA3 area. 6. Under intracellular recording, picrotoxin induced bursts in CA3, CA4, and hilar neurons but K-dependent slow IPSPs in granule cells. 4-AP induced rhythmically occurring burst in hilar neurons synchronous to Cl- and K-dependent IPSPs in CA3, CA4, and granule cells. 7. Comparison of picrotoxin- and 4-AP-induced rhythmical burst activity reveals that many hilar neurons are excited by CA3/CA4 pyramidal neurons in addition to the well-known excitation by granule cells and perforant path fibers, and that, in turn, many hilar neurons inhibit CA3, CA4, and granule cells.     

Effects of low concentrations of 4-aminopyridine on CA1 pyramidal cells of the hippocampus

1. Intracellular and extracellular recording techniques were used to study the effects of bath application of 4-aminopyridine (4-AP) on pyramidal cells of the CA1 subfield of rat hippocampal slices maintained in vitro. The concentration of 4-AP used in most experiments was 50 microM. However, similar results were obtained with a concentration ranging from 5 to 100 microM. 2. Following 4-AP application, cells impaled with K-acetate-filled microelectrodes hyperpolarized by an average of 2.6 mV (from -68.7 to -71.3 mV, P less than or equal to 0.01). This change was accompanied by the appearance of high-frequency spontaneous hyperpolarizations. Conversely, when KCl-filled microelectrodes were used, an average depolarization of 5.8 mV [from -73.1 to -67.3 mV, not significant (NS)] associated with the occurrence of repetitive depolarizing potentials was observed. In both cases, these changes were concomitant with a small decrease in membrane input resistance, which was statistically significant only for cells impaled with K-acetate-filled microelectrodes. When synaptic transmission was blocked by tetrodotoxin (TTX), 4-AP induced in cells studied with K-acetate microelectrodes an average depolarization of 2.4 mV (from -62.8 to -60.4 mV, P less than or equal to 0.01) accompanied by a small increase in input resistance (from 32.0 to 35.8 M omega, P less than or equal to 0.05). High-frequency spontaneous potentials failed to occur under these conditions. During 4-AP application, the threshold and the latency of action potentials elicited by a depolarizing current pulse increased in 36% of the neurons studied (n = 14). 3. The amplitude of the stratum (s.) radiatum-induced excitatory postsynaptic potential (EPSP) was augmented by 4-AP. Both the early and late inhibitory postsynaptic potentials (IPSPs) evoked by orthodromic stimuli were also increased in amplitude and duration. In addition, a late (peak latency, 150-600 ms) and long-lasting (duration, 600-1,500 ms) depolarizing potential appeared between the early and the late IPSPs and progressively increased until it partially masked these hyperpolarizations. This long-lasting depolarization (LLD) could also be induced by antidromic stimulation, although in this case it was preceded by an additional, fast-rising, brief depolarization. 4. A similar brief depolarization preceded the orthodromically induced LLD in 69% of the neurons bathed in the presence of 4-AP. The average value of the peak latency of this potential was 62 +/- 27 (SD) ms for orthodromic and 110 +/- 70 ms for antidromic responses.(ABSTRACT TRUNCATED AT 400 WORDS)     

Kainate receptor-dependent axonal depolarization and action potential initiation in interneurons.

Kainate receptor agonists are powerful chemoconvulsants and excitotoxins. These properties are in part explained by depolarization of hippocampal principal neurons. However, kainate also depresses evoked inhibitory signals in pyramidal neurons, and promotes spontaneous GABA release from interneurons. The mechanisms underlying these phenomena are not fully understood, nor are the consequences for the inhibitory traffic among interneurons. We report that both the amplitude and the frequency of spontaneous IPSCs recorded in interneurons were enhanced by low concentrations of kainate, but action potential-independent IPSCs were unaffected. In the presence of GABA(A) receptor antagonists, kainate lowered the threshold for antidromic action potential generation, suggesting that interneuron axons are directly depolarized; this effect was mimicked by synaptically released glutamate. Kainate application also induced spontaneous antidromic action potentials. Axonal receptors are thus important in initiating the intense interneuronal activity triggered by kainate, which in turn influences inhibitory signaling to principal cells.     

Voltage-activated sodium channels amplify inhibition in neocortical pyramidal neurons

Inhibitory postsynaptic potentials (IPSPs) in neocortical pyramidal neurons are increased in duration and amplitude at depolarized membrane potentials. This effect was not due to changes in the time course of the underlying synaptic current. The role of postsynaptic voltage-activated channels was investigated by mimicking the voltage change that occurs during an IPSP with current injections. The peak and integral of these 'simulated' IPSPs increased during depolarization of the membrane potential in a tetrodotoxin-sensitive manner. This amplification presumably occurs as the hyperpolarization associated with IPSPs turns off sodium channels that are tonically active at depolarized membrane potentials. IPSP amplification increased the ability of IPSPs to inhibit action potential firing and promoted IPSP-induced action potential synchronization.     

Epileptiform burst activity induced by potassium in the hippocampus and its regulation by GABA-mediated inhibition

Intracellular and extracellular recordings were made from pyramidal neurons in hippocampal slices in order to study spontaneous paroxysmal bursting induced by raising the extracellular potassium concentration from 3.5 to 8.5 mM. Extracellular recordings from all hippocampal subfields indicated that spontaneous bursts appeared to originate in region CA3c or CA3b as judged by burst onset. Burst intensity was also greatest in regions CA3b and CA3c and became progressively less toward region CA2. Intracellular recordings indicated that in 8.5 mM potassium, large spontaneous excitatory postsynaptic potentials (EPSPs), large burst afterhyperpolarizations, and rhythmic hyperpolarizing-depolarizing waves of membrane potential were invariably present in CA3c neurons. High potassium (8.5 mM) induced a positive shift (+9 mV) in the reversal potential of GABAergic inhibitory postsynaptic potentials (IPSPs) in CA3c neurons without changing input resistance or resting potential. This resulted in a drastic reduction in amplitude of the IPSP. Reduction of IPSP amplitude occurred before the onset of spontaneous bursting and was reversible upon return to normal potassium. A new technique to quantify the relative intensity of interictal-like burst discharges is described. Pentobarbital, diazepam, and GABA uptake inhibitors, which enhance GABA-mediated synaptic inhibition, reduced the intensity of potassium-induced bursts, whereas the GABA antagonist bicuculline increased burst intensity. Diphenylhydantoin and phenobarbital, anticonvulsants that have little effect on GABAergic inhibition, were without effect on spontaneous bursts. Burst frequency was reduced by bicuculline and 4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridin-3-ol but was unaffected by other drugs. Reduction of slice temperature from 35 to 19 degrees C dramatically reduced burst intensity but did not markedly affect burst frequency. We hypothesize that high potassium induces a rise in intracellular chloride concentration, possibly by activating an inward KCl pump or by a passive Donnan effect, which results in a decreased IPSP amplitude. With inhibition suppressed, the large spontaneous EPSPs that appear in high potassium cause individual CA3c neurons to fire. A combination of synaptic and electrical interactions among CA3c cells then synchronizes discharges into interictal spike bursts.     

pH Sensitivity of non-synaptic field bursts in the dentate gyrus

Under conditions of low [Ca(2+)](o) and high [K(+)](o), the rat dentate granule cell layer in vitro develops recurrent spontaneous prolonged field bursts that resemble an in vivo phenomenon called maximal dentate activation. To understand how pH changes in vivo might affect this phenomenon, the slices were exposed to different extracellular pH environments in vitro. The field bursts were highly sensitive to extracellular pH over the range 7.0-7.6 and were suppressed at low pH and enhanced at high pH. Granule cell resting membrane potential, action potentials, and postsynaptic potentials were not significantly altered by pH changes within the range that suppressed the bursts. The pH sensitivity of the bursts was not altered by pharmacologic blockade of N-methyl-D-aspartate (NMDA), non-NMDA, and GABA(A) receptors at concentrations of these agents sufficient to eliminate both spontaneous and evoked synaptic potentials. Gap junction patency is known to be sensitive to pH, and agents that block gap junctions, including octanol, oleamide, and carbenoxolone, blocked the prolonged field bursts in a manner similar to low pH. Perfusion with gap junction blockers or acidic pH suppressed field bursts but did not block spontaneous firing of single and multiple units, including burst firing. These data suggest that the pH sensitivity of seizures and epileptiform phenomena in vivo may be mediated in large part through mechanisms other than suppression of NMDA-mediated or other excitatory synaptic transmission. Alterations in electrotonic coupling via gap junctions, affecting field synchronization, may be one such process.     

GABA(A)-dependent chloride influx modulates reversal potential of GABA(B)-mediated IPSPs in hippocampal pyramidal cells

Changes in intracellular chloride concentration, mediated by chloride influx through GABA(A) receptor-gated channels, may modulate GABA(B) receptor-mediated inhibitory postsynaptic potentials (GABA(B) IPSPs) via unknown mechanisms. Recording from CA3 pyramidal cells in hippocampal slices, we investigated the impact of chloride influx during GABA(A) receptor-mediated IPSPs (GABA(A) IPSPs) on the properties of GABA(B) IPSPs. At relatively positive membrane potentials (near -55 mV), mossy fiber--evoked GABA(B) IPSPs were reduced (compared with their magnitude at -60 mV) when preceded by GABA(A) receptor--mediated chloride influx. This effect was not associated with a correlated reduction in membrane permeability during the GABA(B) IPSP. The mossy fiber--evoked GABA(B) IPSP showed a positive shift in reversal potential (from -99 to -93 mV) when it was preceded by a GABA(A) IPSP evoked at cell membrane potential of -55 mV as compared with -60 mV. Similarly, when intracellular chloride concentration was raised via chloride diffusion from an intracellular microelectrode, there was a reduction of the pharmacologically isolated monosynaptic GABA(B) IPSP and a concurrent shift of GABA(B) IPSP reversal potential from -98 to -90 mV. We conclude that in hippocampal pyramidal cells, in which "resting" membrane potential is near action potential threshold, chloride influx via GABA(A) IPSPs shifts the reversal potential of subsequent GABA(B) receptor--mediated postsynaptic responses in a positive direction and reduces their magnitude.     

Long-term change in synaptic transmission in CA3 circuits followed by spontaneous rhythmic activity in rat hippocampal slices

The relevance of long-term potentiation (LTP) at excitatory synapses in CA3 circuits to generation of spontaneous epileptiform bursts in CA3 was investigated using rat hippocampal slices. CA3 pyramidal cells were antidromically stimulated through Schaffer collaterals. Evoked field potentials were extracellularly recorded from the stratum pyramidale and the stratum radiatum in CA3. Therefore, field potentials reflecting recurrent excitatory post-synaptic potentials (EPSPs) and inhibitory post-synaptic potentials (IPSPs) were positive at the stratum pyramidale and negative at the stratum radiatum. First, we tested how the amplitude of the evoked field potentials depends on a γ-aminobutyric acid (GABA_A) antagonist. Both of the positive and negative field potential peaks reduced in the medium containing penicillin (2 mM) or bicuculline (20 μM). This suggests that unmasked EPSPs due to suppression of IPSPs do not result in an increase in the evoked potentials. Second, CA3 pyramidal cells were antidromically stimulated by tetanic stimulation of Schaffer collaterals in order to induce LTP at synapses in CA3 circuits. Both of the positive and negative field potentials increased, suggesting that recurrent EPSPs were enhanced by tetanic stimulation. Induction of LTP at recurrent excitatory synapses was followed by spontaneous epileptiform bursts which persisted throughout experiments (1.5 h), while LTP of afferent synaptic potential evoked by hilar test stimulation was not induced. These results suggest that LTP at the afferent synapses is not necessary to spontaneous epileptiform bursts in CA3, but LTP at excitatory synapses between CA3 pyramidal cells contribute to spontaneous epileptiform bursts.     

Antidromic firing occurs spontaneously on thalamic relay neurons: triggering of ectopic action potentials by somatic intrinsic burst discharges

Possible dynamic relationships between orthodromically conducted somatic bursts and antidromic impulses arising from presynaptic endings of thalamocortical neurons were explored. Evoked or spontaneous bursts were recorded from 125 identified thalamic relay neurons in 36 anesthetized rats using extracellular microelectrodes. Evoked bursts were obtained by electrical stimulation of either the neocortex or the peripheral activation field. Spontaneous antidromic firing appeared only during periods of (or an expected) rapid somatic intrinsic burst discharge. Ectopic axonal impulses occurred either separately, or clustered in doublets or triplets having relatively long-lasting intervals; these slow bursts represented a proportion of about 12% of evoked and 20% of spontaneous whole bursts. Separate ectopic action potentials could also appear several milliseconds after rapid bursts, producing peculiar long last-interval bursts; about 15% of the whole bursts were of this long interval type. The probability that an ectopic axonal impulse will occur after a rapid burst increases with the number of its action potentials, suggesting that the duration of orthodromic burst firing might contribute to the triggering of ectopic impulses. For 52% of the neurons tested, the activation threshold of their axon terminals decreased just before or immediately after rapid somatic bursts. Since no excitability changes were observed in thalamocortical axons of the white matter, the ectopic action potential generators were probably located on presynaptic endings. During a transient deafferentation of thalamic neurons induced by intrathalamic microinjection of a magnesium solution, neither burst activity nor spontaneous antidromic firing were observed, suggesting that thalamic orthodromic burst discharges are required for presynaptic impulse generation. In conclusion, somatic intrinsic bursts traveling orthodromically along thalamocortical axons might be involved in triggering presynaptic impulses on parent and possibly on nearby thalamic cells. Since a spontaneous antidromic action potential is able to trigger a rapid burst [Pinault (1988) Eur. J. Neurosci. Suppl. P. 246; Pinault and Pumain (1989) Neuroscience 31, 625-637], it is postulated that excitatory interactions between presynaptic endings might be involved in intrinsic burst synchronization processes.     

Action-potential broadening and endogenously sustained bursting are substrates of command ability in a feeding neuron of Pleurobranchaea

1. The ventral white cells (VWC's) of the buccal ganglion of Pleurobranchaea, so named for their position and color, are a bilateral pair of neuron somata. Each sends a single axon out its contralateral stomatogastric nerve and has a dendritic field originating close to the soma. 2. The vwcs exhibit spontaneous episodes of prolonged depolarization (duration 1--4 min) accompanied by repetitive action-potential activity and separated by regular intervals of 3--30 min. Such prolonged burst episodes can be triggered by short pulses of depolarizing current. During the repetitive activity of the spontaneous bursts or that driven by imposed depolarization, the action potentials progressively broaden to 5--16 times their initial duration. 3. During spontaneous bursting or activity driven by imposed depolarization, the cyclic motor output of the feeding network is initiated or accelerated with a latency corresponding with the development of appreciable VWC spike broadening. When broadening of antidromic VWC spikes is suppressed by imposed hyperpolarization of the soma, the frequency of feeding cycles is significantly lower than when broadened spikes are allowed to develop. When trains of spikes are driven by depolarizing current, the motor output of the feeding network is not initiated until the VWC spikes have broadened to a repeatable "threshold" duration, regardless of the intensity of the depolarizing current. 4. The endogenous production of prolonged burst episodes, triggered by depolarizing current pulses, and progressive spike broadening can be demonstrated in the surgically isolated VWC soma. 5. The paired VWCs are strongly electrically coupled and display highly synchronous activity. They receive synaptic inputs from many previously identified interneurons of the feeding network and are thus reciprocally coupled within the network. 6. These results demonstrate that the capacity of this neuron to generate broadened action potentials during repetitive activity confers the ability to command coordinated motor-network output. The appropriate repetitive activity can be produced endogenously in the form of prolonged bursts of spikes.