Commissural responses of rat retrohippocampal neurons

Synaptic responses of commissurally activated rat subicular and entorhinal neurons were studied intracellularly in vivo by stimulating the contralateral dentate gyrus. The most prominent synaptic responses in both subicular and entorhinal neurons were inhibitory postsynaptic potentials (IPSPs). IPSPs were generated in combination with antidromic spikes and/or excitatory postsynaptic potentials (EPSPs) and orthodromic spikes. No dependency between any two response types were found. Commissurally projecting subicular neurons (identified by the presence of antidromic spikes evoked by contralateral stimulation) were found, extending previous anatomical studies. Commissurally projecting entorhinal neurons were found in layer II, confirming previous anatomical studies. Positive correlations between antidromic spike latency and depth of recording sites supported the interpretation that axons projected along the fiber bundles of the hippocampal commissures and angular bundle to distribute to their targets. Possible circuits that could have mediated the excitatory and inhibitory responses of these retrohippocampal neurons are considered.     

Synaptic connections of neuropeptide Y (NPY) immunoreactive neurons in the hilar area of the rat hippocampus

Synaptic connections and fine structural characteristics of neuropeptide Y-immunoreactive (NPY-i) neurons in the fascia dentata were studied using an antiserum against NPY. Normal and colchicine pretreated rats were examined to study the synaptic connections of NPY-i neurons in the normal fascia dentata. The perforant pathway and fimbria fornix were transected to label afferent fibers to NPY-positive cells. Horseradish peroxidase conjugated with wheat germ agglutinin (HRP-WGA) was injected into the contralateral hippocampus to study commissural projections of hippocampal NPY-i neurons, and to search for NPY-i synaptic contacts on immunonegative commissural cells. Since earlier reports have shown that at least half of the NPY-i neurons also contain somatostatin (SS), the distribution of NPY-i neurons in the hilar area was determined and compared with that of SS-i neurons. Four types of dentate NPY-i neurons were distinguished: Type 1: large multipolar cells in the deep hilus (9%). Type 2: medium-sized multipolar and fusiform hilar neurons with dendrites occasionally reaching the outer molecular layer (64%). Type 3: pyramidal shaped cells in the granule cell layer with long apical dendrites reaching the outer molecular layer (20%). Type 4: small multipolar NPY-i cells located in the molecular layer (7%). Our results indicate two overlapping but not identical cell populations of NPY-i and SS-i neurons. Light and electron microscopic analysis of the normal fascia dentata demonstrated that the majority of NPY-i terminals are located in the outer molecular layer of the dentate gyrus, where they establish symmetric synaptic contacts on dendritic shafts and occasionally on spines of granule cells. A moderate number of NPY-i synapses were also found on dendrites in the inner molecular layer and on the cell body of granule cells. Numerous symmetric NPY-i synapses were found on dendrites and somata of neurons in the hilar area. Some NPY-i dendrites in the hilar area received mossy axon collateral input. After transection of the perforant pathway degenerated axon terminals could be found in synaptic contact with NPY-i dendrites in the outer molecular layer. Commissurotomy revealed direct commissural input to NPY-i dendrites in the inner molecular layer and in the hilus. After injection of HRP-WGA into the contralateral hippocampus 2% of hilar NPY-i neurons were retrogradely labeled and symmetric NPY-i synapses were found on the cell bodies and dendrites of unstained HRP-WGA labeled neurons.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ipsilateral associational pathway in the dentate gyrus: An excitatory feedback system that supports N-methyl-D-aspartate—dependent long-term potentiation

Axons from granule cells in the dentate gyrus of the rat hippocampus project to cells in the hilar region, including mossy cells, which project along the longitudinal axis of the hippocampus and synapse in the inner (proximal) one-third of the molecular layer of the dentate gyrus. To study this feedback system, multiple recording electrodes were located along the longitudinal (septo-temporal) axis in the dorsal leaf of the dentate gyrus in urethane-anesthetized rats. Single pulse electrical stimuli delivered to the hilar region evoked negative-going, monosynaptic field potentials that were largest in the inner one-third of the molecular layer (commissural zone). These evoked field potentials (EFPs) were recorded simultaneously at three to five locations. The latency to onset and peak amplitude of the EFP varied linearly with distance from point of stimulation, and EFPs were elicited in both directions along the longitudinal axis. The transmission speed was estimated to be 1.4 m/s. Tetanic stimulation of the hilar region potentiated the EFP slopes (mean= 26%). Potentiation lasted at least 2 hours and was specific to responses from the tetanized stimulating electrode; the responses to other stimulating electrodes in the hilus and the angular bundle of the perforant path changed less than 4%. Combined stimulation of the hilus and the medial perforant path increased the magnitude of recorded field potentials and population spikes, demonstrating that both pathways are excitatory. NMDA antagonist NPC-17742 blocked potentiation of EFP slopes in both the medial perforant path and hilus pathways. The results suggest that the ipsilateral associational system of the dentate gyrus is excitatory and capable of supporting long-lasting, NMDA-dependent, synapse-specific plasticity. © 1994 Wiley-Liss, Inc.     

Ultrastructure of commissural neurons of the hilar region in the hippocampal dentate gyrus

Previous studies have described the polymorph neurons in the hilus of the dentate gyrus at the light microscopic level and have indicated that many of those neurons are the cells of origin for both ipsilateral associational and commissural projections to the dentate gyrus. Because previous studies have not described the ultrastructural characteristics of the hilar neurons, we identified these features of the commissural neurons in the hilus. The method of retrograde transport of horseradish peroxidase (HRP) was utilized with a silver staining technique for HRP intensification. Two populations of labeled commissural neurons were observed in electron microscopic preparations of the contralateral hilus. One type consisted of cells with somata that exhibited round or oval nuclei with no intranuclear inclusions and formed symmetric axosomatic synapses. The main dendrites of those neurons were thick and tapering. In contrast, the other type of labeled neuronal soma had infolded nuclei containing intranuclear rods or sheets, displayed both symmetric and asymmetric axosomatic synapses, and had dendrites that were less thick and generally aspinous. In those same preparations, labeled commissural axon terminals formed synapses with dendrites and dendritic spines in the hilus and molecular layer and iwth somata in the granule cell layer. From the results of this study it appears that there are two distinct populations of commissural hilar neurons: one type resembles the morphology of the spiny CA3 pyramidal neuron, a type of excitatory projection cell, and the other type is similar to the dentate gyrus basket cell, a local circuit neuron associated with GABAergic inhibition. This latter cell type provides further support for the notion that some commissural neurons are inhibitory.     

Commissurally projecting inhibitory interneurons of the rat hippocampal dentate gyrus: a colocalization study of neuronal markers and the retrograde tracer Fluoro-gold.

Improved methods for detecting neuronal markers and the retrograde tracer Fluoro-Gold (FG) were used to identify commissurally projecting neurons of the rat hippocampus. In addition to the dentate hilar mossy cells and CA3 pyramidal cells shown previously to transport retrograde tracers after injection into the dorsal hippocampus, FG-positive interneurons of the dentate granule cell layer and hilus were detected in numbers greater than previously reported. FG labeling of interneurons was variable among animals, but was as high as 96% of hilar somatostatin-positive interneurons, 84% of parvalbumin-positive cells of the granule cell layer and hilus combined, and 33% of hilar calretinin-positive cells. By comparison, interneurons of the dentate molecular layer and all hippocampal subregions were conspicuously FG-negative. Whereas hilar mossy cells and CA3 pyramidal cells were FG-labeled throughout the longitudinal axis, FG-positive interneurons exhibited a relatively homotopic distribution. "Control" injections of FG into the neocortex, septum, and ventral hippocampus demonstrated that the homotopic labeling of dentate interneurons was injection site-specific, and that the CA1-CA3 interneurons unlabeled by contralateral hippocampal FG injection were nonetheless able to transport FG from the septum. These data suggest a hippocampal organizing principle according to which virtually all commissurally projecting hippocampal neurons share the property of being monosynaptic targets of dentate granule cells. Because granule cells innervate their exclusively ipsilateral target cells in a highly lamellar pattern, these results suggest that focal granule cell excitation may result in commissural inhibition of the corresponding "twin" granule cell lamella, thereby lateralizing and amplifying the influence of the initiating discharge.     

Electrophysiology of dentate granule cells after kainate-induced synaptic reorganization of the mossy fibers.

Morphological data from humans with temporal lobe epilepsy and from animal models of epilepsy suggest that seizure-induced damage to dentate hilar neurons causes granule cells to sprout new axon collaterals that innervate other granule cells. This aberrant projection has been suggested to be an anatomical substrate for epileptogenesis. This hypothesis was tested in the present study with intra- and extracellular recordings from granule cells in hippocampal slices removed from rats 1-4 months after kainate treatment. In this animal model, hippocampal cell loss leads to sprouting of mossy fiber axons from the granule cells into the inner molecular layer of the dentate gyrus. Unexpectedly, when slices with mossy fiber sprouting were examined in normal medium, extracellular stimulation of the hilus or perforant path evoked relatively normal responses. However, in the presence of the GABAA-receptor antagonist, bicuculline, low-intensity hilar stimulation evoked delayed bursts of action potentials in about one-quarter of the slices. In one-third of the bicuculline-treated slices with mossy fiber sprouting, spontaneous bursts of synchronous spikes were superimposed on slow negative field potentials. Slices from normal rats or kainate-treated rats without mossy fiber sprouting never showed delayed bursts to weak hilar stimulation or spontaneous bursts in bicuculline. These data suggest that new local excitatory circuits may be suppressed normally, and then emerge functionally when synaptic inhibition is blocked. Therefore, after repeated seizures and excitotoxic damage in the hippocampus, synaptic reorganization of the mossy fibers is consistently associated with normal responses; however, in some preparations, the mossy fibers may form functional recurrent excitatory connections, but synaptic inhibition appears to mask these potentially epileptogenic alterations.     

Cholinergic innervation of hippocampal GAD- and somatostatin-immunoreactive commissural neurons

This study describes the cholinergic innervation of chemically defined nonpyramidal neurons in the hilar region of the rat hippocampus. Cholinergic terminals were identified by immunocytochemistry employing a monoclonal antibody against choline acetyltransferase (ChAT), the acetylcholine-synthesizing enzyme, and the avidin-biotin-peroxidase (ABC) technique. Nonpyramidal neurons in the hilar region were characterized by immunostaining with antibodies against glutamate decarboxylase (GAD), the gamma aminobutyric acid (GABA)-synthesizing enzyme, and somatostatin (SS). The immunoreactivity to these antibodies was detected by using biotinylated secondary antibodies and avidinated ferritin as an electron-dense marker. This electron microscopic double immunostaining procedure enabled us to demonstrate that immunoperoxidase-labeled ChAT-immunoreactive terminals established symmetric synaptic contacts on the ferritin-labeled GAD- and SS-immunoreactive hilar cells. In additional experiments at least some of the GAD- and SS-immunoreactive hilar neurons were further characterized as commissural neurons by retrograde filling with horseradish peroxidase (HRP) following an injection of the tracer into the contralateral hilus. From these triple labeling experiments, we concluded that at least some GABAergic and somatostatin-containing neurons in the hilar region, which are postsynaptic to cholinergic terminals, project to the contralateral hippocampus. Together with previous studies on the cholinergic innervation of the hippocampus and fascia dentata, our present results thus demonstrate that different types of hippocampal cells, including GABAergic and peptidergic commissural neurons in the hilar region, receive a cholinergic input.     

Differences in synaptic transmission between medial and lateral components of the perforant path

The differences between the potentials recorded in the hilus of the dentate gyrus following test shocks applied separately to the medial perforant path (MPP) and the lateral perforant path (LPP) have been ascribed to the greater length of dendrite over which the LPP potentials are electrotonically conducted to the somata of the granule cells. We tested this hypothesis by recording MPP and LPP evoked potentials in the hilus and in the molecular layer of both in vivo and in vitro preparations. Analysis of field potential and current source density depth profiles in vivo indicated that different waveshapes occurred not only in the hilus but at the sites of synaptic contact in the molecular layer as well. In the in vitro study, paired stimulating and recording electrodes were stepped through the molecular layer and revealed a relatively sudden waveshape change around 225 micron from the cell layer, where the transitional zone between MPP and LPP terminal fields was expected to be located. Quantitative analysis of the differences between the potentials recorded in the molecular layer and the hilus revealed that electrotonic decay accounts for approximately 20% of the difference seen in the hilus between the MPP and LPP potentials. Our data therefore suggest that the differences between MPP and LPP hilar potentials are due mostly to differences between the two pathways in their properties of synaptic transmission and are due relatively little to the different sites of synaptic contact on the dendritic tree.     

Properties of antidromically activated callosal neurons and neurons responsive to callosal input in rabbit binocular cortex

Extracellular spikes were recorded from the cell bodies of antidromically activated callosal axons in the binocular visual cortex of unanesthetized, unparalyzed rabbits. Callosal axons were stimulated near their terminals in the contralateral cortex. Recordings were also obtained from neurons which responded synaptically to contralateral cortical stimulation. The primary method for differentiating antidromic from synaptic activation was the test for collision of impulses. Additional tests provided further confirmation of antidromic activation. Units which sent an axon across the corpus callosum (callosal neurons) were thereby distinguished from units which responded synaptically to callosal input. Eighteen percent of units sampled sent an axon across the corpus callosum. The median conduction velocity of callosal axons was less than 2 m/sec. An additional 18% of units encountered were synaptically activated by contralateral cortical stimulation. Callosal neurons were found to differ from synaptically activated units in three distinct ways. Callosal neurons had very low spontaneous firing rates (median =< 1.0 spike/sec), responded with a single spike to contralateral cortical stimulation and never responded to diffuse flash illumination. In contrast, most synaptically activated units demonstrated high spontaneous firing rates (median = 10.2 spikes/sec), responded with a burst of spikes to contralateral cortical stimulation and were also driven by diffuse flash illumination.     

Morphology and synaptic connections of crossed corticostriatal neurons in the rat

The neurons of origin of the bilateral corticostriatal projection arising from the medial agranular cortical field in rats were identified by antidromic activation from contralateral neostriatal stimulation. The same cells were tested for antidromic activation from the contralateral neocortex and for orthodromic responses to stimulation of neocortex of the contralateral hemisphere or ipsilateral rostral thalamus. The neurons were then stained by intracellular injection of horseradish peroxidase. The laminar distribution of these neurons was compared to that of cortical cells stained retrogradely after injection of wheat germ agglutinin/HRP in the ipsilateral or contralateral neostriatum. The morphological features of physiologically identified corticostriatal neurons, their laminar organization, and their responses to stimulation were examined and compared with crossed corticocortical and brainstem-projecting cells. Crossed corticostriatal cells of the medial agranular cortical field were medium-sized pyramidal neurons found in the superficial part of layer V and in the deep part of layer III. Their basilar dendritic fields and initial intracortical axon collateral arborizations were coextensive with the layer defined by the distribution of corticostriatal neurons. The apical dendrites were thin and sparsely branched but consistently reached layer I, where they made a small arborization. These morphological features were shared by cortical neurons projecting to contralateral neocortex but not responding antidromically to stimulation of contralateral neostriatum, but they were not shared by brainstem-projecting cortical cells. Orthodromic responses to contralateral cortical stimulation consisted of brief excitatory postsynaptic potentials that were followed by powerful and longer-lasting inhibitory postsynaptic potentials. Corticostriatal cells also exhibited small excitatory postsynaptic potentials in response to thalamic stimulation. Many crossed corticostriatal neurons were also commissural corticocortical neurons. The results of reciprocal collision tests showed that this was due to the existence of two separate axonal branches, one projecting to contralateral neocortex and one to contralateral neostriatum. Intracellular staining of these neurons revealed ipsilateral axonal projections to the neostriatum and cortex.     

Dentate hilar cells with dendrites in the molecular layer have lower thresholds for synaptic activation by perforant path than granule cells

Neurons in the dentate hilus or area CA3c of rat hippocampal slices were recorded intracellularly with electrodes containing the fluorescent dye Lucifer yellow. Stimulation of perforant path fibers in the molecular layer of the fascia dentata strongly excited most hilar neurons, with a much lower threshold for action potential generation than granule cells and area CA3c pyramidal cells that were recorded in the same area of the slice. Examination of dye-filled hilar neurons with a confocal microscope showed that hilar cells with a low threshold were morphologically heterogeneous: some were spiny "mossy" cells, and others were aspiny interneurons. However, all hilar cells with low thresholds possessed dendrites that penetrated the granule cell layer and passed into the molecular layer, often reaching the outer molecular layer. The few hilar cells that had a threshold similar to, or greater than, granule cells did not possess visible dendrites in the molecular layer. The results suggest that the circuitry of the dentate region allows for (1) excitation of both granule cells and hilar cells by perforant path stimuli, and (2) strong excitation of most hilar cells when most granule cells are subthreshold for action potential generation. Given that hilar neurons project to many different sites in the ipsilateral and contralateral fascia dentata (Blackstad, 1956; Zimmer, 1971; Swanson et al., 1978; Laurberg and S?rensen, 1981), it is quite likely that hilar neurons are involved in the processing of information passing from entorhinal cortex to hippocampus.     

Crossed sacculo-ocular pathway via the deiters' nucleus in cats

Single unit recordings were made in the Deiters' nucleus of cats in response to electrical stimulation of the superior area of the contralateral saccule and the ipsilateral oculomotor (IIIrd) nuclear complex. Correct placements of the stimulating and recording electrodes were identified by upward movements of the eyeballs associated with characteristic field potentials in the Deiters' nucleus. Stimulation of the contralateral saccule induced a negative N wave followed by positive P₁ and P₂ potentials. One hundred twenty-two units responded to contralateral saccular stimulation with a mean latency of 2.48 ± 0.06 msec (SEM). Of these, only the responses of 31 cells could be made to collide with antidromic spikes evoked from ipsilateral IIIrd nuclear stimulation. This implies that the crossed sacculo-ocular pathway would involve at least four neurons with one commissural cell interposing between the bilateral vestibular nuclei.     

Evidence for commissurally projecting parvalbumin-immunoreactive basket cells in the dentate gyrus of the rat.

The fluorescent retrograde tracer, fluorogold, was used to identify commissurally projecting neurons in the hippocampus and dentate gyrus. After injection of fluorogold into the hippocampus, the contralateral hippocampus was evaluated for fluorogold-immunoreactive or fluorescent neurons. In addition to observing labeled hilar neurons and CA3 pyramidal cells that previously have been reported to send commissurally projecting axons to the contralateral hippocampus, the authors unexpectedly found a population of fluorogold-labeled cells in the granule cell layer with the morphology and location of GABA-immunoreactive basket cells. Immunocytochemical staining revealed that all fluorogold-labeled cells of the granule cell layer were immunoreactive for parvalbumin. However, not all parvalbumin cells, shown previously to be a subset of GABA neurons, were fluorogold-labeled. The association between fluorogold transport and parvalbumin immunoreactivity was unique for these cells of the granule cell layer. In the adjacent hilus, relatively few of the many fluorogold-labeled cells were parvalbumin- or GABA-immunoreactive. These results (1) identify a population of presumed inhibitory neurons that apparently form commissural projections; (2) document that all of these cells contain the calcium-binding protein parvalbumin; and (3) indicate that the vast majority of commissurally projecting hilar neurons are neither parvalbumin- nor GABA-immunoreactive.     

The commissural pathway and cochlear nucleus bushy neurons: an in vivo intracellular investigation

A direct commissural connection formed between cochlear nuclei allows information from the contralateral ear to rapidly influence the processing of the ascending auditory signal. Among the neuronal groups proposed to both receive, and contribute to, commissural input is the bushy cell population in the ventral cochlear nucleus (VCN). In this in vivo electrophysiological study we examine the intracellular recordings of bushy neurons during electrical stimulation of the contralateral cochlear nucleus (CN) for evidence of both their contribution to, and input from commissural projections. Activation of the commissural pathway revealed short-latency fast hyperpolarisation in 19.5% of the 41 bushy neurons examined. The hyperpolarising potentials were small in amplitude, displayed a highly variable time course between neurons, and in some cases were eliminated with injection of depolarising current. There was no indication of antidromic activity, or short-latency excitatory potentials. These results suggest that i) bushy neurons do not contribute projections to the commissural connection, and ii) a small portion of bushy neurons are hyperpolarised following commissural stimulation.     

Differential NPY mRNA expression in granule cells and interneurons of the rat dentate gyrus after kainic acid injection

Using in situ hybridization histochemistry neuropeptide Y (NPY) mRNA expression was investigated after intraperitoneal injection of kainic acid (KA) and after local application of KA or quinolinic acid into the dentate gyrus of the rat. Enhanced concentrations of NPY mRNA were observed in interneurons of the hilus, including presumptive fusiform neurons and pyramidal-shaped basket cells already 4 hours after initiation of limbic seizures by KA (10 mg/kg, i.p.). IncreaseD NPY expression persisted in neurons resistant to seizure-induced cell death (6–48 h after i.p. KA). Exceptionally high hybridization signals were found in interneurons of the hilus and the CA1 and CA3 sectors 8 months after KA-induced limbic seizures. In the granule cell layer only a transient but pronounced increase in NPY mRNA was observed 12–24 h after injection. Only moderate changes were observed in this cell layer at later intervals. Anticonvulsant treatment with thiopental, after a brief period of generalized seizures, prevented the increase in NPY mRNA in granule cells but not in interneurons. No change in NPY message was found also in granule cells of rats which responded with mild “wet dog shake” behvior but not with motor seizures to KA injection. Local injections of low doses of KA (0.05–0.2 nmol) or quinolinic acid (6.5–100 nmol) into the dentate gyrus of the hippocampus under deep thiopental anesthesia, after 24 h, resulted in increased concentrations of NPY message in interneurons of the ipsilateral, but not of the contralateral hilus and not in granule cells. Higher doses of the excitatory amino acid analogs caused partial neurodegeneration at the injection site, but enhanced NPY expression in interneurons of the contralateral dentate. Only the highest dose of quinolinic acid (100 nmol), resulting in general neuronal cell loss at the injection area, induced enhanced NPY mRNA expression also in granule cells of the contralateral dentate gyrus. The experiments suggest different mechanisms for NPY mRNA expression in interneurons and in granule cells of the dentate gyrus. Whereas in the stratum granulosum NPY mRNA expression was only observed after generalized limbic seizures, in hilar interneurons it was augmented by only moderate neuronal stimulation or directly by KA. © 1994 Wiley-Liss, Inc.     

A High Degree of Spatial Selectivity in the Axonal and Dendritic Domains of Physiologically Identified Local-circuit Neurons in the Dentate Gyms of the Rat Hippocampus

The axonal and dendritic domains of neurons with extensive, locally arborizing axons were delineated in the dentate gyrus of the rat hippocampus. In horizontally cut slice preparations neurons were briefly recorded and subsequently filled with biocytin when one or several of the following physiological properties were observed: (i) high-amplitude short-latency spike afterhyperpolarization; (ii) lack of spike frequency adaptation; (iii) high firing rate in response to depolarizing current. In a sample of 14 neurons, sufficient dendritic and/or axonal detail was recovered to identify them as non-principal cells, i.e. non-granule, non-mossy cells. Five distinct types of cells were recognized, based on the spatial distribution of dendrites, presumably reflecting the availability of afferents, and on the basis of the highly selective distribution of their axon terminals, indicating synaptic target selectivity. They are: (1) the hilar cell forming a dense axonal plexus in the commissural and association pathway terminal field (HICAP cell; horizontal axon extent 1.6 mm) in the inner one-third of the molecular layer, and having dendrites extending from the hilus to the top of the molecular layer; (2) the hilar cell with its axon ramifying in the perforant path terminal field (HIPP cell, horizontal axon extent 2.0 mm) in the outer two-thirds of the molecular layer, whereas its spiny dendrites were restricted to the hilus; (3) the molecular layer cell with its dendritic and axonal domains confined to the perforant path terminal zone (MOPP cell, horizontal extent of axon 2.0 mm); (4) the dentate basket cell (horizontal axon extent 0.9 mm) had most of its axon concentrated in the granule cell layer, the remainder being localized in the inner molecular layer and hilus; (5) the hilar chandelier cell, or axo-axonic cell (horizontal axon extent 1.1 mm), densely innervating the granule cell layer with fascicles of radially orientated terminal rows, and also forming an extensive plexus in the hilus. The three cell types having their somata in the hilus projected to granule cells at the same septo-temporal level where their cell bodies were located. The results demonstrate that there is a spatially selective innervation of the granule cells by at least five distinct types of dentate neurons, which terminate in several instances in mutually exclusive domains. Their dendrites may have access to all (HICAP cell) or only a few (e.g. HIPP and MOPP cell) of the hippocampal afferents. This arrangement provides a framework for independent interaction between the output of local circuit neurons and subsets of excitatory afferents providing input to principal cells.     

Inhibition of lateral vestibular nucleus neurons by 5-hydroxytryptamine derived from the dorsal raphe nucleus

Electrophysiological studies were performed to elucidate the effect of 5-hydroxytryptamine (5-HT) originating in the dorsal raphe nucleus (DR) on neuronal activity in the lateral vestibular nucleus (LVN) neurons, using cats anesthetized with alpha-chloralose. LVN neurons were classified into monosynaptic and polysynaptic neurons according to their responses to vestibular nerve stimulation. Conditioning stimuli applied to the DR inhibited orthodromic spikes elicited by vestibular nerve stimulation predominantly in polysynaptic neurons of the LVN. The iontophoretic application of 5-HT also inhibited orthodromic spikes of the LVN neurons. A close correlation was observed between the effects of DR conditioning stimulation and iontophoretically applied 5-HT in the same neurons. These inhibitions with both treatments were antagonized during the application of methysergide, a 5-HT antagonist. In the majority of LVN polysynaptic neurons that responded to antidromic stimulation of the ipsilateral or contralateral abducens nucleus, orthodromic spikes elicited by vestibular nerve stimulation were inhibited by DR conditioning stimulation and the iontophoretic application of 5-HT. In contrast, LVN neurons that responded to antidromic stimulation of the vestibulospinal tract were rarely affected by these treatments. These results indicate that 5-HT derived from the DR inhibits the synaptic transmission of LVN polysynaptic neurons ascending to the abducens nucleus, and suggest that 5-HT derived from the DR is involved in the regulation of the vestibulo-ocular reflex.     

Rubrospinal tract of the cat: superposition of antidromic responses and changes in axonal excitability following orthodromic activity

Activity was recorded from rubrospinal neurons (RSNs) in anesthetized, paralyzed, artificially ventilated cats. Multiple-unit microelectrodes were used to simultaneously record the activity of neighboring RSNs. When antidromically activated, the RSNs responded forming 'stacks' of superimposed spikes. By using appropriate collision tests, it was found that the spikes forming a stack arose from different neurons. In addition, single extracellular and intracellular recordings were obtained from RSNs. The changes in the axonal excitability of rubrospinal axons were tested following synaptically evoked (by contralateral interpositus (IP) stimulation) and/or directly evoked (by injection of current through the intracellular electrode) action potentials at different postspike delays. Subthreshold stimuli for antidromic activation in absence of orthodromic activity were well suprathreshold for most fibers in a wide range of postspike delays. The supernormal axonal periods were longer-lasting when tested after synaptic spikes (up to an average delay of 100.4 ms; range, 10-500 ms) than after directly evoked spikes (mean delay, 78.8 ms; range, 10-296 ms). If synaptic stimulation fires more RSNs than direct stimulation, then the longer-lasting supernormal periods might be due to the activity of adjacent fibers. An additional increase in external potassium concentration in the vicinity of the axon would explain these results.     

Kindling with stimulation of the dentate gyrus. II. Effects on evoked field potentials

Once daily for 60 days, male hooded rats received unilateral high-frequency stimulation in the hilus of the dentate gyrus (DG), at an intensity sufficient to evoke afterdischarge (AD). Every 2nd day, evoked potentials were recorded from the hilus following stimulation of the PP with single 0.1 ms pulses at 6 current intensities. Changes in synaptic excitability of the dentate granule cells were monitored by measuring the amplitudes of the population spikes; changes in the strength of excitatory synaptic transmission were monitored by measuring the slopes of the excitatory postsynaptic potentials (EPSPs). Control rats, which were not given kindling stimulation, were tested for changes in synaptic transmission and excitability in the same way, at comparable times. In general, hilar stimulation resulted in a large decrease in population spike amplitudes to below baseline and control levels, accompanied by a paradoxical potentiation of EPSPs. Population spike amplitudes decreased more in rats that developed generalized stage-5 seizures (Generalized group) than in rats that did not progress beyond partial seizures despite 60 days of stimulation (Partial group). Conversely, EPSP slopes increased more in the Partial group than in the Generalized group. These results suggest that kindling stimulation may potentiate responsiveness of the directly activated dentate granule cells to inputs from the PP, but at the same time suppress the output of the granule cells resulting from this input. Furthermore, the results indicate that kindling is more closely allied to the suppression of output than to the potentiation of responsiveness to input.     

Electrophysiological diversity of pyramidal-shaped neurons at the granule cell layer/hilus border of the rat dentate gyrus recorded in vitro

In the rat dentate gyrus, pyramidal-shaped cells located on the border of the granule cell layer and the hilus are one of the most common types of γ-aminobutyric acid (GABA)-immunoreactive neurons. This study describes their electrophysiological characteristics. Membrane properties, patterns of discharge, and synaptic responses were recorded intracellularly from these cells in hippocampal slices. Each cell was identified as pyramidal-shaped by injecting the marker Neurobiotin intracellularly (n =17). In several respects the membrane properties of the sampled cells were similar to “fast-spiking” cells (putative inhibitory interneurons) that have been described in other areas of the hippocampus. For example, input resistance was high (mean 91.3 megohms), the membrane time constant was short (mean 7.7 ms), and there was a large afterhyperpolarization following a single action potential (mean 10.5 mV at resting potential). However, the action potentials of most pyramidal-shaped cells were not as brief (mean 1.2 ms total duration) as those of most previously described fast-spiking cells. Many pyramidal-shaped neurons had strong spike frequency adaptation relative to other fast-spiking cells. Although these latter two characteristics were apparent in the majority of the sampled cells, there were exceptional pyramidal-shaped neurons with fast action potentials and weak adaptation, demonstrating the electrophysiological variability of pyramidal-shaped cells. Responses to outer molecular layer stimulation were composed primarily of excitatory postsynaptic potentials (EPSPs) rather than inhibitory postsynaptic potentials (IPSPs), and were usually small (EPSPs evoked at threshold were often less than 2 mV), and brief (less than 30 ms). There was variability, because in a few cells EPSPs evoked at threshold were much larger. However, regardless of EPSP amplitude, suprathreshold stimulation (up to 4 times the threshold stimulus strength) rarely evoked more than one action potential in any cell. The results suggest that stimulation of perforant path axons produces limited excitatory synaptic responses in pyramidal-shaped neurons. This may be one of the reasons why they are relatively resistant to prolonged perforant path stimulation. The pyramidal-shaped neurons located at the base of the granule cell layer have been associated historically with a basket plexus around granule cell somata, and have been called pyramidal “basket” cells. However, basket-like endings were rare and axon collaterals outside the granule cell layer were common. Many axon collaterals were as far from the granule cell layer as the outer molecular layer and the central hilus, and antidromic action potentials could be recorded in some cells in response to weak stimulation of these areas. Taken together with the electrophysiological variability, the results indicate that these cells are physiologically heterogeneous. © 1995 Wiley-Liss, Inc.