Muscarinic Modulation of Intrinsic Burst Firing in Rat Hippocampal Neurons

Intracellular recordings in rat hippocampal slices were used to examine how exogenous and endogenous cholinergic agonists modulate the firing pattern of intrinsically burst-firing pyramidal cells. About 24% of CA1 pyramidal cells generated all-or-none, high-frequency bursts of fast action potentials in response to intracellular injection of long positive current pulses. Application of carbachol (5 μM) converted burst firing in these neurons into regular trains of independent spikes. Acetylcholine (5 μM) exerted a similar effect, provided acetylcholine esterase activity was blocked with neostigmine (2 μM). Atropine (1 μM) reversed this cholinergic effect, indicating its mediation by muscarinic receptors. Cholinergic agonists also caused mild neuronal depolarization but the block of intrinsic burst firing was independent of this effect. Repetitive stimulation of cholinergic fibres in the presence of neostigmine (2 μM) evoked a slow cholinergic excitatory postsynaptic potential (EPSP) lasting about a minute. During the slow EPSP, burst firing could not be evoked by depolarizing pulses and the neurons fired in regular mode. These effects were prevented by pretreatment with atropine (1 μM). Exogenously applied cholinergic agonists and endogenously released acetylcholine also reduced spike frequency accommodation and suppressed the long-duration afterhyperpolarization in burst-firing pyramidal cells in an atropine-sensitive manner. A membrane-permeable cAMP analogue (8-bromo-cAMP; 1 mM) also reduced frequency accommodation and blocked the long-duration afterhyperpolarization, but did not affect intrinsic burst firing at all. Taken together, the data show that muscarinic receptor stimulation transforms the stereotyped, phasic response of burst-firing neurons into stimulus-graded, tonic discharge.     

Frequency-Dependent Synaptic Dynamics Differentially Tune CA1 and CA2 Pyramidal Neuron Responses to Cortical Input

Entorhinal cortex neurons make monosynaptic connections onto distal apical dendrites of CA1 and CA2 pyramidal neurons through the perforant path (PP) projection. Previous studies show that differences in dendritic properties and synaptic input density enable the PP inputs to produce a much stronger excitation of CA2 compared with CA1 pyramidal neurons. Here, using mice of both sexes, we report that the difference in PP efficacy varies substantially as a function of presynaptic firing rate. Although a single PP stimulus evokes a 5- to 6-fold greater EPSP in CA2 compared with CA1, a brief high-frequency train of PP stimuli evokes a strongly facilitating postsynaptic response in CA1, with relatively little change in CA2. Furthermore, we demonstrate that blockade of NMDARs significantly reduces strong temporal summation in CA1 but has little impact on that in CA2. As a result of the differences in the frequency- and NMDAR-dependent temporal summation, naturalistic patterns of presynaptic activity evoke CA1 and CA2 responses with distinct dynamics, differentially tuning CA1 and CA2 responses to bursts of presynaptic firing versus single presynaptic spikes, respectively.SIGNIFICANCE STATEMENT Recent studies have demonstrated that abundant entorhinal cortical innervation and efficient dendritic propagation enable hippocampal CA2 pyramidal neurons to produce robust excitation evoked by single cortical stimuli, compared with CA1. Here we uncovered, unexpectedly, that the difference in efficacy of cortical excitation varies substantially as a function of presynaptic firing rate. A burst of stimuli evokes a strongly facilitating response in CA1, but not in CA2. As a result, the postsynaptic response of CA1 and CA2 to presynaptic naturalistic firing displays contrasting temporal dynamics, which depends on the activation of NMDARs. Thus, whereas CA2 responds to single stimuli, CA1 is selectively recruited by bursts of cortical input.     

Tetanic stimulation of schaffer collaterals induces rhythmic bursts via NMDA receptor activation in rat CA1 pyramidal neurons

Exploring the principles that regulate rhythmic membrane potential (Vm) oscillations and bursts in hippocampal CA1 pyramidal neurons is essential to understanding the theta rhythm (theta). Recordings were performed in vitro in hippocampal slices from young rats, and a group of the recorded CA1 pyramidal cells were dye-filled with carboxifluorescein and immunolabeled for the R1 subunit of the NMDA receptor. Tetanic stimulation of Schaffer collaterals (SCs) and iontophoresis of glutamate evoked rhythmic Vm oscillations and bursts (approximately 10 mV, approximately 7 Hz, 2-5 spikes per burst) in cells (31%) placed close to the midline ("medial cells"). Rhythmic bursts remained under picrotoxin (10 microM) and Vm oscillations persisted with tetrodotoxin (1.5 microM), but bursts were blocked by AP5 (25 microM) and Mg2+-free solutions. Depolarization and AMPA never induced rhythmic bursts. The rest of the neurons (69%), recorded closer to the CA3 region ("lateral cells"), discharged rhythmically single repetitive spikes under SC stimulation and glutamate in control conditions, but fired rhythmic bursts under similar stimulation, both when NMDA was applied and when non-NMDA receptors were blocked with CNQX (20 microM). Medial cells exhibited a larger NMDA current component and a higher NMDAR1 density at the apical dendritic shafts than lateral cells, suggesting that these differences underlie the dissimilar responses of both cell groups. We conclude that the "theta-like" rhythmic oscillations and bursts induced by glutamate and SC stimulation relied on the activation of NMDA receptors at the apical dendrites of medial cells. These results suggest a role of CA3 pyramidal neurons in the generation of CA1 theta via the activation of NMDA receptors of CA1 pyramidal neurons.     

Feed-forward and feed-back activation of the dentate gyrus in vivo during dentate spikes and sharp wave bursts

Intermittently occurring field events, dentate spikes (DS), and sharp waves (SPW) in the hippocampus reflect population synchrony of principal cells and interneurons along the entorhinal cortex-hippocampus axis. We have investigated the cellular-synaptic generation of DSs and SPWs by intracellular recording from granule cells, pyramidal cells, and interneurons in anesthetized rats. The recorded neurons were anatomically identified by intracellular injection of biocytin. Extracellular recording electrodes were placed in the hilus to record field DSs and multiple units and in the CA1 pyramidal cell layer to monitor SPW-associated fast field oscillations (ripples) and unit activity. DSs were associated with large depolarizing potentials in granule cells, but they rarely discharged action potentials. When they were depolarized slightly with intracellular current injection, bursts of action potentials occurred concurrently with extracellularly recorded DSs. Two interneurons in the hilar region were also found to discharge preferentially with DSs. In contrast, CA1 pyramidal cells, recorded extracellularly and intracellularly, were suppressed during DSs. In association with field SPWs, extracellular recordings from the CA1 pyramidal layer and the hilar region revealed synchronous bursting of these cell populations. Intracellular recordings from CA3 and CA1 pyramidal cells, granule cells, and from a single CA3 region interneuron revealed SPW-concurrent depolarizing potentials and action potentials. These findings suggest that granule cells may be discharged anterogradely by entorhinal input or retrogradely by the CA3-mossy cell feedback pathway during DSs and SPWs, respectively. Although both of these intermittent population patterns can activate granule cells, the impact of DSs and SPWs is diametrically opposite on the rest of the hippocampal circuitry. Entorhinal cortex activation of the granule cells during DSs induces a transient decrease in the hippocampal output, whereas during SPW bursts every principal cell population of the hippocampal formation may be recruited into the population event. Hippocampus 7:437–450, 1997. © 1997 Wiley-Liss, Inc.     

Membrane properties and discharge characteristics of guinea pig dorsal cochlear nucleus neurons studied in vitro

Intracellular recordings were made from neurons of the guinea pig dorsal cochlear nucleus in an in vitro brain slice preparation. The membrane properties of the cells were studied, and the membrane potentials were manipulated by current injection to determine how intrinsic conductances might alter the cell discharge patterns. Eleven cells were marked with Lucifer yellow. Ten of these cells were identified as the large pyramidal cells of layer 2 of this nucleus, and 1 cell was identified as a "vertical" cell in layer 3. Two kinds of action potentials were observed: simple spikes and complex spikes. This report discusses only cells with simple spikes. Simple spiking cells (60/72 recorded cells; all stained cells were simple spiking cells) discharged in a regular fashion with depolarization, and had linear frequency-current relationships up to 2 nA with a mean slope of 116 Hz/nA. The discharge rate was approximately constant throughout the current pulse. Responses of simple spiking cells to depolarizing current steps superimposed on a steady-state membrane hyperpolarization were studied. When the membrane has been held hyperpolarized, small current pulses produce a long-latency regular train of action potentials. Larger current pulses superimposed on membrane hyperpolarization can produce a short-latency action potential followed by a long silent interval (i.e., a long first interspike interval), and finally a regular train of spikes. It is concluded that the membrane conductances of DCN pyramidal cells are capable of generating at least 3 discharge patterns (regular firing, long first spike latency, and long first interspike interval) depending on the state of the membrane potential prior to a depolarizing current step. These responses are similar to the "chopper," "buildup," and "pauser" discharge patterns reported for these cells in vivo in response to tone bursts. The modulation of the intrinsic membrane conductances by membrane polarization and the possible contribution of these conductances to the generation of DCN discharge patterns provide new insights into the mechanisms underlying the responses of DCN cells to acoustic stimuli.     

Competitive NMDA receptor antagonists differentially affect dopamine cell firing pattern

Alterations in the firing pattern of mesencephalic dopamine (DA) neurons appear to constitute a physiological mechanism through which these cells modify their effects on target neurons. Several lines of evidence suggest that the activity patterns exhibited by DA cells in vivo are contingent on tonic activation of N-methyl-D-aspartate (NMDA) receptors. In the present series of experiments, extracellular single unit recording techniques were used to assess the effects of the centrally acting, competitive NMDA receptor antagonists CGS-19755, (±)-CPP, NPC-12626 and NPC-17742 on the firing properties of nigral DA neurons in the chloral hydrate-anesthetized rat. Each of the drugs tested produced a modest increase in firing rate accompanied by a significant regularization of neuronal firing pattern. Although the number of bursts and the percentage of spikes in bursts were reduced, the proportion of cells operationally defined as bursting was not appreciably altered. This appeared to be due to the ability of these drugs to reduce the number of spike doublets without affecting the incidence of longer bursts. Although generally consistent with the notion that NMDA receptors modulate DA neuronal firing pattern, the present data do not support the contention that tonic activation of these receptors is solely responsible for the expression of bursting activity in vivo. Synapse 25:234–242, 1997. © 1997 Wiley-Liss, Inc.     

Electrical properties of neurons in the intact rat major pelvic ganglion

The aim of this investigation was to characterize the electrical properties of neurons in the rat major pelvic ganglia (MPG) using intracellular recording techniques. MPG were dissected from male rats euthanized by isoflurane and thoracotomy. Neurons were classified as "phasic" or "tonic" according to their rate of accommodation during a 500-ms depolarizing current pulse. Phasic cells were further subdivided into rapidly or slowly adapting. The firing pattern of tonic cells was divided into regular high frequency, low frequency or irregular firing. In tonic cells, onset spikes showed TTX-resistant discharges; whereas sustained spikes were TTX sensitive. Changing the current pulse amplitude or the stimulation interval could alter the firing pattern in both types of neurons. Subthreshold membrane potential oscillations (SMPOs) were primarily observed when neurons were depolarized. SMPOs were Na(+) dependent and TTX sensitive. The majority of tonic and phasic neurons generated rebound spikes, most of which were partially Na(+) dependent. A small percentage (<6%) of neurons exhibited spontaneous activity. Taken together these findings are consistent with the concept that neurons in the MPG exhibit heterogeneous electrical properties.     

Electrophysiological and morphological properties of rat motor cortex neurons in vivo.

This paper describes results obtained from intracellular recordings and stainings of motor cortex neurons in the rat in vivo. Rats were anesthetized with phenobarbital. Neurons were intracellularly recorded with micropipettes filled with K+-methylsulphate + 4% HRP in phosphate buffer (pH 7.4). Successful recordings and stainings were obtained from 31 neurons. Intracellular recordings were distinguished as either intrasomatic or intradendritic. Action potentials (APs) recorded from somata were distinguished by their fast hyperpolarizing afterpotential from those recorded within dendrites. Dendritic APs were broader and often followed by an afterdepolarization. The firing patterns elicited by depolarizing current pulses allowed to distinguish 3 groups of neurons. (a) Group A neurons with a moderate firing-rate of up to 17 APs during a 100 ms depolarizing current pulse of 3.5 nA comprised small and large pyramidal cells and one aspiny multipolar neuron, probably a large basket neuron. (b) Group B neurons generated bursts, which either occurred spontaneously or during low intensity current injection. These neurons were classified as small pyramidal neurons and spiny star cells. (c) Group C neurons had a firing rate 3 times as high as group A neurons. These neurons were small aspiny cells with radial dendritic fields, which were classified as local interneurons. Intradendritic recordings were characterized by the occurrence of broad APs, most likely generated within the dendritic tree. Intracellular current injections produced burst-like potentials consisting of several APs with different amplitude and duration. In 3 penetrations of one apical dendrite up to 4 neurons were stained. In these recordings APs activated by intracellular current injection were particularly broad (up to 40 ms). The results suggest that neuronal firing patterns observed in in-vitro neocortical slices are also observed in in-vivo conditions.     

Schaffer-specific local field potentials reflect discrete excitatory events at gamma frequency that may fire postsynaptic hippocampal CA1 units

Information processing and exchange between brain nuclei are made through spike series sent by individual neurons in highly irregular temporal patterns. Synchronization in cell assemblies, proposed as a network language for internal neural representations, still has little experimental support. We use a novel technique to extract pathway-specific local field potentials (LFPs) in the hippocampus to explore the ongoing temporal structure of a single presynaptic input, the CA3 Schaffer pathway, and its contribution to the spontaneous output of CA1 units in anesthetized rat. We found that Schaffer-specific LFPs are composed of a regular succession of pulse-like excitatory packages initiated by spontaneous clustered firing of CA3 pyramidal cells to which individual units contribute variably. A fraction of these packages readily induce firing of CA1 pyramidal cells and interneurons, the so-called Schaffer-driven spikes, revealing the presynaptic origin in the output code of single CA1 units. The output of 70% of CA1 pyramidal neurons contains up to 10% of such spikes. Our results suggest a hierarchical internal operation of the CA3 region based on sequential oscillatory activation of pyramidal cell assemblies whose activity partly gets in the output code at the next station. We conclude that CA1 output may directly reflect the activity of specific ensembles of CA3 neurons. Thus, the fine temporal structure of pathway-specific LFPs, as an accurate readout of the activity of a presynaptic population, is useful in searching for hidden presynaptic code in irregular spikes series of individual neurons and assemblies.     

Action and location of neuropeptide tyrosine (Y) on hippocampal neurons of the rat in slice preparations

The action of bath applied NPY (1-1,000 nM) was investigated on hippocampal slices of the rat with extra- and intracellular recording. Neuropeptide Y (NPY) at 10-1,000 nM caused a concentration-dependent, long-lasting reduction of excitatory postsynaptic potentials (EPSPs) in the hippocampal subfield CA1 and the area dentata, and an even stronger reduction of population spikes. Paired pulse experiments with low intensity, stimulation-evoked PSPs showed a marked increase in facilitation in the presence of NPY, indicating a presynaptic action. Spontaneous burst firing of CA1 pyramidal cells in low calcium, high magnesium medium was reduced, indicating a partially postsynaptic inhibitory action of NPY on their dendrites. Intracellular recording from CA1 somata during NPY administration revealed a reduction of the amplitudes of excitatory-inhibitory postsynaptic potential (EPSP-IPSP) sequences in the absence of changes in membrane potential and conductance. Accommodation of firing during long depolarizing pulses and afterhyperpolarizations were unchanged. The innervation pattern of NPY immunoreactive fibers in the same regions was studied in slices adjacent to the ones used for electrophysiology by using antisera against NPY and light and electron microscopy. There is a dense innervation of CA1 by NPY-immunoreactive axons and terminals, particularly in the stratum moleculare. NPY-immunoreactive neurons are present in the stratum oriens and pyramidale. The NPY labeled axons of the stratum moleculare participate in numerous synaptic contacts with the smaller dendritic elements in this layer, many of which belong to pyramidal neurons. These observations provide evidence for a dendritic NPY-immunoreactive innervation of CA1 neurons, which is in keeping with the electrophysiological effects of NPY on pyramidal neurons.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neurochemical identification of stereotypic burst-firing neurons in the rat dorsal raphe nucleus using juxtacellular labelling methods

Recent electrophysiological studies have discovered evidence of heterogeneity of 5-hydroxytryptamine (5-HT) neurons in the mesencephalic raphe nuclei. Of particular interest is a subpopulation of putative 5-HT neurons that display many of the electrophysiological properties of presumed 5-HT-containing neurons (regular and slow firing of single spikes with a broad waveform) but fire spikes in short, stereotyped bursts. In the present study we investigated the chemical identity of these neurons in rats utilizing in vivo juxtacellular labelling methods. Of ten dorsal raphe nucleus (DRN) neurons firing short stereotyped bursts within an otherwise regular firing pattern, all exhibited immunoreactivity for either 5-HT (n = 6) or the 5-HT synthesizing enzyme, tryptophan hydroxylase (TRH; n = 2) or both (n = 2). Supporting pharmacological experiments demonstrated that the burst firing DRN neurons demonstrated equal sensitivity to 5-HT(1A) agonism and alpha(1)-adrenoceptor antagonism to single spiking DRN neurons that we have previously identified as 5-HT-containing. Collectively these data provide direct evidence that DRN neurons that exhibit stereotyped burst firing activity are 5-HT containing. The presence of multiple types of electrophysiologically distinct midbrain 5-HT neurons is discussed.     

Early exposure to alcohol leads to permanent impairment of dendritic excitability in neocortical pyramidal neurons

Exposure to alcohol in utero is a well known cause of mental retardation in humans. Using experimental models of fetal alcohol spectrum disorder, it has been demonstrated that cortical pyramidal neurons and their projections are profoundly and permanently impaired. Yet, how the functional features of these cells are modified and how such modifications impact cognitive processes is still unknown. To address this, we studied the intrinsic electrophysiological properties of pyramidal neurons in young adult rats (P30-P60) exposed to ethanol inhalation during the first week of postnatal life (P2-P6). Dual whole-cell recordings from the soma and distal apical dendrites were performed and, following the injection of depolarizing current into the dendrites, layer 5 neurons from ethanol-treated (Et) animals displayed a lower number and a shorter duration of dendritic spikes, attributable to a downregulation of calcium electrogenesis. As a consequence, the mean number of action potentials recorded at the soma after dendritic current injection was also lower in Et animals. No significant differences between Et and controls were observed in the firing pattern elicited in layer 5 neurons by steps of depolarizing somatic current, even though the firing rate was significantly lower in Et animals. The firing pattern and the firing rate of layer 2/3 neurons were not affected by alcohol exposure.     

Synchronization of GABAergic interneuronal networks during seizure-like activity in the rat horizontal hippocampal slice

We studied the contribution of GABAergic (gamma-aminobutyric acid) neurotransmission to epileptiform activity using the horizontal hippocampal rat brain slice. Seizure-like (ictal) activity was evoked in the CA1 area by applying high-frequency trains (80 Hz for 2 s) to the Schaffer collaterals. Whole-cell recordings from stratum oriens-alveus interneurons revealed burst firing with superimposed high-frequency spiking which was synchronous with field events and pyramidal cell firing during ictal activity. On the other hand, interictal interneuronal bursts were synchronous with large-amplitude inhibitory postsynaptic potentials (IPSPs) in pyramidal cells. Excitatory and inhibitory postsynaptic potentials were simultaneously received by pyramidal neurons during the ictal afterdischarge, and were synchronous with interneuronal bursting and field potential ictal events. The GABAA receptor antagonist bicuculline greatly reduced the duration of the ictal activity in the CA1 layer, and evoked rhythmic interictal synchronous bursting of interneurons and pyramidal cells. With intact GABAergic transmission, interictal field potential events were synchronous with large amplitude IPSPs (9.8 +/- 2.4 mV) in CA1 pyramidal cells, and with interneuronal bursting. Simultaneous dual recordings revealed synchronous IPSPs received by widely separated pyramidal neurons during ictal and interictal periods, indicative of widespread interneuronal firing synchrony throughout the hippocampus. CA3 pyramidal neurons fired in synchrony with interictal field potential events recorded in the CA1 layer, and glutamate receptor antagonists abolished interictal interneuronal firing and synchronous large amplitude IPSPs received by CA1 pyramidal cells. These observations provide evidence that the interneuronal network may be entrained in hyperexcitable states by GABAergic and glutamatergic mechanisms.     

The control of firing pattern in nigral dopamine neurons: single spike firing

Dopamine (DA) neurons have been recorded in vivo in four states of activity: hyperpolarized, nonfiring; single spike firing; burst firing; and depolarization inactivation. Nonfiring DA neurons can be made to fire by iontophoretic application of the excitatory substances glutamate and cholecystokinin, or by depolarizing current injection. Spontaneously active DA cells typically fire in a slow (3 to 8 Hz) irregular pattern. In vivo intracellular recordings revealed that this pattern is sustained by the alternation of two currents: a spontaneously occurring slow depolarization (13 +/- 3 mV amplitude, 78 +/- 40 msec duration) which brings the membrane potential of the DA cell to spike threshold (-42 mV), and an afterhyperpolarization mediated by a calcium-activated potassium conductance (IK(Ca)). The slow depolarization is a pacemaker-like conductance, with a rate of rise proportional to the membrane potential. The regular pacemaker pattern of the spontaneously occurring slow depolarization is interrupted by the IK(Ca) which appears to be triggered by calcium entry during the action potential. Thus, intracellular injection of the calcium chelator EGTA will cause DA cells to fire in a regular, pacemaker pattern. The IK(Ca) is observed after single spikes and trains of spikes with the amplitude of the afterhyperpolarization being proportional to the number of spikes in a train. Both the afterhyperpolarization and the firing accommodation observed during depolarizing current injection can be blocked by intracellular injection of the calcium chelator EGTA.     

Background potassium concentrations and epileptiform discharges. I. Electrophysiological characteristics of neuronal activity

Intra- and extracellular recording techniques were used to study the epileptiform activity generated by guinea pig hippocampal slices perfused with free-magnesium artificial cerebrospinal fluid in the presence of physiologic (4 mM), reduced (2 mM) or elevated (8 mM) extracellular potassium concentrations ([K(+)](o)). Extracellular field potentials along with intracellular recordings were recorded in CA1 or CA3 region. Reduction of [K(+)](o) significantly increased the latency of epileptiform field potential (EFP) appearance as well as burst discharge duration and decreased EFP repetition rate. Depending on different background [K(+)](o), epileptiform burst discharges appeared in different patterns including varied types of paroxysmal depolarisation shifts and burst activity in CA1 and CA3 subfields. Comparison with physiological and increased [K(+)](o,) reduction of [K(+)](o) significantly increased the mean duration of bursts, mean amplitude of depolarisation, mean after-hyperpolarisation duration, and inter-spike intervals in both CA1 and CA3 areas. Three distinct patterns were distinguished on the basis of their evoked firing pattern in response to application of depolarising current pulses in the interval of epileptiform burst discharges. Neurons superfused with 2 mM [K(+)](o) presented fast adapting pattern while cells washed with 4 or 8 mM [K(+)](o) exhibited intrinsically bursting or slow adapting patterns. Comparing the groups with different background [K(+)](o), there is a more severe form of discharges in low K(+) and a subtle difference between 4 and 8 mM K(+). The data indicate the importance of background [K(+)](o) on epileptiform burst discharge pattern and characteristics.     

Histamine modulates reactivity of hippocampal CA3 neurons to afferent stimulation in vitro

Intracellular activity was recorded from hippocampal CA3 pyramidal cells maintained in vitro. Histamine (HA) produced a slow depolarization associated with minimal conductance changes. In addition, there was an increase in action potential discharge rates and the emergence of bursting firing patterns. EPSP size increased by about 50% and spontaneous dendritic spikes were observed. These effects were markedly reduced by retrodotoxin. Extracellular recording of population spikes revealed a marked difference between CA1 and CA3 regions; in the former HA produced an increase in population spike size whereas in the latter this increase was larger and was associated with the appearance of secondary and tertiary population spikes. It is suggested that HA produces its effects by enhancing release of neurotransmitters from excitatory synapses on the recorded neurons.     

Electrophysiology of morphologically identified mossy cells of the dentate hilus recorded in guinea pig hippocampal slices

A specific population of cells located in the hilus of the hippocampal fascia dentata was studied in guinea pig hippocampal slices using standard intracellular recording techniques. Twenty-one such cells were characterized using electrophysiological techniques and were identified morphologically as mossy cells following intracellular injection of the fluorescent dye Lucifer yellow. These cells had a resting membrane potential (mean, -64.6 mV), action potential amplitude (mean, 78.6 mV), action potential duration (mean, 2.2 msec), and time constant (mean, 24.2 msec) similar to those of hippocampal pyramidal cells of area CA3. Rectification seen in their I-V curves, and their ability to fire action potentials in accommodating trains or bursts in response to injected current pulses, were also similar to those of area CA3 pyramidal cells. However, these cells could be distinguished from area CA3 pyramidal cells by their higher input resistance (mean, 97.4 M omega) and higher level of spontaneous activity. The synaptic responses of mossy cells were also different from those of CA3 pyramidal cells. First, mossy cells responded to low levels of stimulation in all areas of the hippocampal slice that were tested, even areas as remote as area CA1. Second, the responses of mossy cells to stimulation consisted primarily of EPSPs. Hyperpolarizing IPSP-like events followed EPSPs in some cells, but the hyperpolarizations were small and monophasic, even after the cell was depolarized with current injection. This response contrasts with the smaller EPSP and the prominent, biphasic IPSP elicited by afferent stimulation of area CA3 pyramidal cells. The physiological and morphological characteristics of these cells suggest that they could play an important role in the integration of electrical activity in the hippocampus.     

Intrinsic firing patterns of diverse neocortical neurons.

Neurons of the neocortex differ dramatically in the patterns of action potentials they generate in response to current steps. Regular-spiking cells adapt strongly during maintained stimuli, whereas fast-spiking cells can sustain very high firing frequencies with little or no adaptation. Intrinsically bursting cells generate clusters of spikes (bursts), either singly or repetitively. These physiological distinctions have morphological correlates. RS and IB cells can be either pyramidal neurons or spiny stellate cells, and thus constitute the excitatory cells of the cortex. FS cells are smooth or sparsely spiny non-pyramidal cells, and are likely to be GABAergic inhibitory interneurons. The different firing properties of neurons in neocortex contribute significantly to its network behavior.     

Time-course of changes in firing rates and firing patterns of subthalamic nucleus neuronal activity after 6-OHDA-induced dopamine depletion in rats

The subthalamic nucleus (STN) plays a key role in motor control. Disorganization of its neuronal activity is implicated in the manifestation of parkinsonian motor symptoms. The aim of the present work was to study the time-course of changes in the firing activity of STN neurons in a rat model of parkinsonism. Electrophysiological recordings were done in normal rats and four groups of rats at different time points after 6-hydroxydopamine (6-OHDA) microinjection into the pars compacta of substantia nigra (SNc). Results showed a significant decrease in firing rate during the first and second weeks post lesion (5.53+/-0.56 and 7.66+/-0.73 spikes/s, respectively) compared to normal rats (11.13+/-0.59 spikes/s). From the 3rd week after 6-OHDA injection the firing rates returned toward baseline, with an average of 9.71+/-0.51 spikes/s during the 3rd week and 11.13+/-0.71 spikes/s during the 4th week. With regard to firing pattern, the majority of STN cells (90%) discharged regularly or slightly irregularly in normal animals. Only 4% exhibited burst activity and 6% had mixed firing patterns. After SNc-lesion, the percentage of cells exhibiting burst and mixed patterns increased progressively from 35% during the first week to 56% at week 4 post-lesion. In sum, these experiments revealed that the firing rate of STN neurons was altered only transiently following nigral lesions, whereas a progressive and stable change in the firing pattern was observed up to 4 weeks post lesion, suggesting that the persistence of bursts firing more closely relates to the motor pathologies of this rat model of parkinsonism.     

Antidromic and orthodromic responses by subicular neurons in rat brain slices

The subiculum forms part of the region of transition between hippocampus and entorhinal cortex and is one of the primary output structures of the hippocampal formation. Intracellular recordings from subicular bursting and non-bursting cell types and field potential recordings were taken in horizontal slices from rat brains. The inputs and outputs of the two cell types were studied for the purpose of reinforcing or refuting the dichotomy proposed on the basis of membrane properties. Some bursting cells were antidromically activated by stimuli applied to the superficial or deep layers of presubiculum, but never by stimuli applied to deep layers of medial entorhinal cortex (dMEC). Some non-bursting subicular neurons were antidromically activated by stimuli applied to dMEC, but never by stimuli applied to presubiculum. Antidromic population events in subiculum were single spikes when deep MEC was stimulated, but were bursts when presubiculum was stimulated, even in the presence of glutamate receptor antagonists. Population bursts consist of 2 or more population spikes with peak to peak intervals of 5 ms. That population bursts occur in slices where excitatory transmission is blocked suggests that such population bursts reflect coincident bursts by individual neurons. Short-latency (<5 ms) excitatory postsynaptic potentials (EPSPs) were evoked in both subicular cell types in response to single entorhinal, presubicular and CA1 stimuli. Long-latency (>10 ms) EPSPs were seen in both cell types in response to presubicular, but not entorhinal or CA1 stimulation. Bursting cells responded to brief trains of orthodromic stimuli (2–10 pulses, 5–10 ms interstimulus interval) with a burst of action potentials even when the cell was previously depolarized out of bursting range by current injection. Non-bursting cells responded to brief trains of orthodromic stimuli with repetitive firing (≤1 spike/stimulus) at all holding potentials. Spike intervals could reach those seen in bursts by bursting cells. It is concluded that: (1) the distinction between bursting and non-bursting subicular neurons is a dichotomy and cells do not change their identity when activated antidromically or orthodromically; (2) the outputs of the two cell types may be different: bursting cells projected to presubiculum and non-bursting cells projected to entorhinal cortex; and (3) non-bursting cells can, when repetitively stimulated, fire repetitive spikes with interspike intervals in the range of intervals seen in bursts.