The distribution of serotonin binding sites in the hippocampal region of the rat brain. An autoradiographic study

The distribution of serotonin binding sites was studied in the rat hippocampal region by using contact-film autoradiography after in vitro incubations of brain sections with 5-[3H]hydroxytryptamine, [3H]spiperone, and [3H]ketanserin, respectively. Biochemical studies of the 5-[3H]hydroxytryptamine binding to sections cut through the hippocampal region showed that at saturating concentrations of 5-[3H]hydroxytryptamine (2-2.5 nM) the specific binding was at least 50% of the total. The 5-[3H]hydroxytryptamine binding sites were found to be heterogeneously distributed within the hippocampal region with the highest densities present in the following parts: layers I and II and layers IV through VI of the entorhinal area, the radial layer of the subiculum and subfield CA1 of the Ammon's horn and the molecular layer of the area dentata. Moderate to low densities of binding was observed in layer III of the entorhinal area, the pre- and parasubiculum, the stratum pyramidale of the Ammon's horn, and the granular cell layer of the area dentata. Removal of the 5-hydroxytryptamine nerve terminals by systemic injections of the 5-hydroxytryptamine neurotoxin parachloroamphetamine resulted in no detectable reductions of 5-[3H]hydroxytryptamine binding in any brain region. Lesions of hippocampal cell bodies by intrahippocampal injections of ibotenic acid prevented the binding of 5-[3H]hydroxytryptamine within the area of the cell loss. Comparisons between the distribution of 5-hydroxytryptamine immunoreactive nerve terminals and the 5-[3H]hydroxytryptamine binding sites showed that in some areas of sparse 5-hydroxytryptamine innervation the 5-[3H]hydroxytryptamine binding was close to background (e.g. the pyramidal cell layer, the stratum lucidum) whereas in areas with little 5-[3H]hydroxytryptamine binding (e.g. layer III of the lateral entorhinal area, the presubiculum) a very dense 5-hydroxytryptamine innervation was found. The hippocampal 5-[3H]hydroxytryptamine binding was displaced neither by ketanserin (1 microM) nor by spiperone (1 microM), two drugs that bind to cortical 5-hydroxytryptamine2 receptors in the rat brain. Furthermore, the pattern of hippocampal [3H]spiperone binding differed considerably from that of 5-[3H]hydroxytryptamine. The [3H]ketanserin binding in the hippocampal region did not exceed background levels, except in the hilus of area dentata in the ventral hippocampus and entorhinal layer VI at the same level, where moderate binding was found.(ABSTRACT TRUNCATED AT 400 WORDS)     

Zinc-positive afferents to the rat septum originate from distinct subpopulations of zinc-containing neurons in the hippocampal areas and layers

The purpose of the present study was to examine whether zinc-positive and zinc-negative hippocampal neurons in rats differed with respect to their projections to the septum. By combining retrograde axonal transport of the fluorescent tracer Fluoro-Gold with histochemical demonstration of zinc selenide complexes in zinc-containing neurons after intraperitoneal injection of sodium selenite, we were able to visualize the distribution of retrogradely Fluoro-Gold labeled neurons and zinc-containing neurons in the same sections. After unilateral injection of Fluoro-Gold into the rat septum a few retrogradely labeled cells were observed in layer IV of the ipsilateral medial entorhinal area, and numerous labeled cells were observed mainly in the superficial layers of the ipsilateral subicular areas and throughout the CA1 and CA3 pyramidal cell layers, as well as in the contralateral CA3 pyramidal cell layer. Zinc-containing neurons were observed in layers IV–VI of the medial entorhinal area, layers II and III of the parasubiculum, layers II, III and V of presubiculum, and in the superficial CA1 and deep CA3 pyramidal cell layers. Cells double-labeled with Fluoro-Gold and zinc selenide complexes were primarily located in distal (relative to the area dentata) parts of the superficial CA1 pyramidal cell layer and distal parts of the deep CA3 pyramidal cell layer and in layers II and III of presubiculum. Only a very few double-labeled cells were seen in the contralateral CA3. The result demonstrates that the hippocampo-septal projection of rats is a mixture of zinc-positive and zinc-negative fibers. Where-as zinc-negative fibers originate from neurons throughout the hippocampal and retrohippocampal areas, zinc-positive fibers originate from distinct subgroups of zinc-containing cells in different areas and layers.     

Autoradiographic localization of [3H]neurotensin-binding sites in the hippocampal region of the rat and primate brain

The distribution of binding sites for the neuropeptide neurotensin was studied in the hippocampal region of the rat, monkey and human brain by using the method of in vitro receptor autoradiography. Biochemical studies of [3H]neurotensin binding to homogenates or sections of the rat hippocampal region showed it to be saturable, reversible and of high specificity. Displacement studies showed that neurotensin-(1-13) and neurotensin-(8-13) were active, while neurotensin-(1-6) and (1-8) were inactive in blocking the specific binding of [3H]neurotensin to hippocampal sections. The autoradiographic studies showed a highly heterogeneous pattern of [3H]neurotensin binding in the hippocampal region: the highest density was present in the entorhinal area while little binding was found in the Ammon's horn. In the rat most of the [3H]neurotensin binding was found in layer II of the medial entorhinal area and in the parasubiculum, while the lateral entorhinal area contained fewer [3H]neurotensin-binding sites. The laminar distribution of binding remained the same throughout the longitudinal axis of the entorhinal area. The pattern of [3H]neurotensin binding in the monkey resembled that seen in the rat inasmuch as the medial was rich and the lateral entorhinal area was poor in [3H]neurotensin-binding sites. In the medial entorhinal area most binding was found in layers I-IV. Unlike in the rat, the hilus of the monkey contained moderate and the molecular layer of the area dentata few [3H]neurotensin-binding sites. In the human brain the outer three layers of both the medial and the lateral entorhinal area contained binding sites for [3H]neurotensin. Binding sites for [3H]neurotensin were found also in the parasubiculum and in the molecular layer of the area dentata of the human brain. The present autoradiographic studies show that the hippocampal region of the rat and primate brain is rich in binding sites for [3H]neurotensin, that a majority of these are situated in the entorhinal area and that despite some differences in the regional distribution of these binding sites within the hippocampal region, some principal similarities may exist between these species.     

The substance P innervation of the rat hippocampal region

Summary The distribution of substance P (SP) immunoreactive nerve cell bodies and preterminal processes was studied in the rat brain by using several anti-SP-antibodies in combination with immunohistochemical techniques. In normal rats and in rats pretreated with colchicine, SP immunoreactive preterminal processes were found in the hippocampal region, but SP positive cellbodies could be detected only after colchicine pretreatment. Medium-sized to large, multipolar cells immunoreactive for SP were found in stratum oriens of the hippocampal subfield CA3 and in the hilus of the area dentata. Medium-sized to small, round or fusiform cells were detected in the pyramidal layer of the ventral subiculum and in layers III–VI of the ventral entorhinal area. The SP stained preterminal processes were of two types. Numerous fine, varicose axons were stained in different parts of Ammon's horn, while in the retrohippocampal structures, the SP immunoreactivity was present in small distinctly stained puncta. These frequently formed pericellular arrangements around unstained cells, indicative of axosomatic contacts between SP terminals and cells in the hipocampus. In Ammon's horn, the densest SP innervation was found in strata oriens, radiatum and moleculare of subfields CA3a and CA2. Scattered fibers were also present in the stratum oriens of CA3a-c and in the hilus, in particular at ventral levels. In retrohippocampal structures, the SP innervation predominated in the deep pyramidal layer of the subiculum, the second layer of the presubiculum and in layers VI and IV of the medial and lateral entorhinal area. Many of these terminals may arise from local interneurons as well as from sources outside the hippocampal region.Taken together, these studies demonstrate a far more extensive innervation by SP, or a closely related peptide, of the rat hippocampal region than was previously recognized. This suggests that SP may play an important role in neurotransmission within the hippocampal region.Stephen Davies was supported by Travel grants from the Wellcome Trust and the Gurantors of Brain.     

Dopamine D2 receptors in the rat, monkey and the post-mortem human hippocampus. An autoradiographic study using the novel D2-selective ligand 125I-NCQ 298.

The distribution of dopamine D2 receptors in the hippocampal region of the rat, monkey and the postmortem human brain was studied with in vitro receptor autoradiography using the selective salicylamide ligand 125I-NCQ 298. Specific binding was defined in the presence of the D2-selective compound raclopride. In all 3 species, higher densities of specifically bound 125I-NCQ 298 was found in the retrohippocampal structures than in the hippocampus proper. In the rat, layers 1 and 3 of the entorhinal cortex and layer 2 of the presubiculum were found to be rich in specific binding sites. In the monkey, the highest densities were detected in the deep layers (4 through 6) of the entorhinal cortex (EC) and in layer 2 of the presubiculum. Relatively high density of binding was found in the granule cell layer of area dentata. In the human brain, less specific binding was seen as compared to the other two species; the highest densities occurred in the outer layers of the presubiculum and in the hilus of area dentata. These findings show that D2 receptors are present in the hippocampal region and that the retrohippocampal region, including the entorhinal cortex, is enriched in dopamine D2 receptors.     

Terminal distribution of projections from the retrosplenial area to the retrohippocampal region in the rat, as studied by anterograde transport of biotinylated dextran amine

The terminal distribution of projections from the retrosplenial area to the retrohippocampal region was examined in the rat with anterograde transport of biotinylated dextran amine. Projections from the retrosplenial granular area (RSG) to the retrohippocampal region terminate predominantly ipsilaterally in layers I, III, V and VI of the presubiculum, layers I and IV–VI of the parasubiculum, the molecular and pyramidal cell layers of the subiculum, and layers I, III, V and VI of the entorhinal area. On the other hand, projections from the retrosplenial agranular area (RSA) terminate predominantly ipsilaterally in layers I and III of the presubiculum and layers V and VI of the entorhinal and perirhinal areas, and ipsilaterally in layers IV–VI of the parasubiculum. The results show that projections from the RSG to the retrohippocampal region are as massive as those from the RSA, and that each retrosplenial area has distinct projection fields in the retrohippocampal region. This suggests that each retrosplenial area may play some distinct functional roles in memory and learning processes such as spatial behavioral learning.     

Intrinsic and commissural connections within the entorhinal cortex. An anterograde and retrograde tract-tracing study in the cat

Intrinsic and commissural connections within the entorhinal cortex (EC) were examined in the cat by the anterograde and retrograde tract-tracing methods with Phaseolus vulgaris leucoagglutinin and cholera toxin B subunit. Intrinsic axons to the superficial layers (layers I-III) arose mainly from layers II, III, Vd (deep part of layer V), and VI, were distributed more widely in the superficial layers than in the deep layers, and terminated progressively more densely in more superficial layers; most densely in layer I. In the medial entorhinal area (MEA) and the ventromedial and the ventrolateral divisions of the lateral entorhinal area (VMEA and VLEA), the longitudinal connections through the intrinsic fibers to the superficial layers is often more restricted in rostral direction than in caudal direction. In the dorsolateral division of the lateral EC (DLEA), the longitudinal connections through the intrinsic fibers to the superficial layers extended distantly in both rostral and caudal directions. Intrinsic fibers to the deep layers (layers IV-VI) originated mainly from layers IV and Vs (superficial part of layer V) and were distributed rather sparsely and diffusely; they were distributed more widely in the deep layers than in the superficial layers. Commissural axons to the homotopic EC regions originated from layers II and III of the MEA and DLEA and terminated in all EC layers, most densely in layer I.     

Somatostatin and vasoactive intestinal polypeptide-like immunoreactive cells and terminals in the retrohippocampal region of the rat brain

The retrohippocampal region of the rat brain was analyzed by using immunohistochemistry with specific antibodies against somatostatin (SOM) and vasoactive intestinal polypeptide (VIP). Specifically immunoreactive neurons and terminal processes were labeled with either the anti-SOM or anti-VIP antiserum and they were referred to as SOM-like immunoreactive (SOM-LI) or VIP-like immunoreactive (VIP-LI) neurons and processes, respectively. The retrohippocampal region was rich in neuronal cell bodies and terminal processes showing immunoreactivity for SOM and VIP. In the entorhinal area SOM-LI neurons were located mainly in layers IV through VI and the VIP-LI neurons were found mainly in layers I through III. Thick (70-120 microns) sections treated with the immunoperoxidase method to achieve a Golgi-like staining pattern showed that cytological differences existed between SOM- and VIP-positive neurons. SOM-LI neurons were usually multipolar, fusiform, or occasionally pyramidal while VIP-LI neurons were usually bipolar, stellate, or fusiform. SOM-LI and VIP-LI axons and preterminal processes were differentially distributed within the laminae of the retrohippocampal region. VIP-LI terminals were found throughout all layers except layer I. SOM-LI terminals were found primarily in the molecular layers of all areas, layer IV of the medical and lateral entorhinal areas, and in the angular bundle. Thus, SOM-LI and VIP-LI neurons are distinguished by their morphology and their different distribution within the cortical layers and areas of the retrohippocampal region.     

Autoradiographic evidence that septohippocampal fibers reinnervate fascia dentata denervated by entorhinal lesion during development

Summary the projection from the ventromedial septum to the fascia dentata was investigated autoradiographically in normal adult rats and in adult rats whose entorhinal cortex had been removed unilaterally at the age of 11 days. In the fascia dentata of normal rats and in the fascia dentata contralateral to the entorhinal lesion septohippocampal fibers and terminals were distributed just below and, to a lesser extent, just above the granular layer. The molecular layer above the supragranular zone was lightly and more or less uniformly innervated. Ipsilateral to the entorhinal lesion, however, the outer part of the dentate molecular layer received an anomalously dense septal projection (average of 3–4 times the contralateral projection). The entorhinal lesion did not consistently affect the density of this projection in any other lamina. These results confirm that septohippocampal fibers increase their density of innervation when synaptic sites are made available by degeneration of lateral perforant path fibers during development. This represents a net increase in total septal innervation of the fascia dentata, not merely a change in the distribution of the projection among its target zones.     

Electrophysiological analysis of the hippocampal projections to the entorhinal area

Responses evoked in the entorhinal area by impulse volleys originating in the ipsilateral hippocampus were analysed in the guinea-pig by means of field potential analysis. Perforant path volleys, synaptically elicited by stimulation of the dorsal psalterium of one side, were used to activate the hippocampal lamellar circuit of the same side and, through interhippocampal impulses, the hippocampal pyramidal neurons of the contralateral side. Discharge of the hippocampal pyramidal neurons was followed by a response, a fast negative deflection preceded and followed by slow waves, in the dorsal third of the ipsilateral entorhinal area. Laminar distribution of the fast negative deflection and of the time-locked unit activity suggested that excitatory synaptic effects followed by neuron discharge were generated in neurons of layers VI-II of the entorhinal area. The increasing latency of the fast negative deflection and of unit firing over the cortical depth suggested that these synaptic effects were generated in temporal sequence, going from layer VI to layer II. The entorhinal response disappeared after a lesion at the caudal border of the hippocampus interrupting the caudally-directed hippocampal efferents. The anatomy of the hippocampal and subicular projections to the entorhinal area in the guinea-pig, together with electrophysiological data obtained in recordings from the ipsilateral subiculum, suggested that the hippocampal impulses were relayed to layers VI-V of the entorhinal area by the subiculum. The delayed activation of layers IV-II was possibly mediated by intracortical connections. Double-shock experiments showed that impulses of hippocampal origin inhibited the response to dorsal psalterium volleys of entorhinal neurons giving origin to perforant path fibers. The data show that the hippocampal output activates the deep layers of the entorhinal area from which it is possibly relayed to numerous cortical and subcortical regions. Moreover, the inhibitory effects exerted on neurons originating perforant path fibers give evidence of a negative feedback control system operating in the hippocampal region.     

Neurons and terminals in the retrohippocampal region in the rat''s brain identified by anti-gamma-aminobutyric acid and anti-glutamic acid decarboxylase immunocytochemistry

Summary The distribution of gamma-aminobutyric acid (GABA) containing nerve cells and terminals was studied at the light and electron microscopic levels in the retrohippocampal region of the rat by using anti-glutamic acid decarboxylase (GAD) and anti-GABA antibodies in immunocytochemistry. Large numbers of GAD and GABA stained cells were found in all retrohippocampal structures. At the ultrastructural level, the immunoreactivity against GABA and against the synthesizing enzyme GAD was localized to cytoplasmic structures, including loose clumps of rough endoplasmic reticulum, ribosomal arrays, outer mitochondrial surfaces and in axonal boutons.The GAD- and GABA-immunorective(-i) cells were found in all subfields of the retrohippocampal region (e.g., the subicular complex, the entorhinal area). Within the entorhinal area a slightly larger number of immunoreactive cells could be detected in layers II and III than in the other layers. In the subiculum, pre- and parasubiculum the GAD and GABA-i cells were present in relatively large numbers in all layers, except the molecular layer, which contained only a small number of GABA cells. Within the entorhinal area, GAD and GABA stained cells ranged in size from small (13 m in diameter) to large (22 m in diameter). A large number of different morphological classes of cells were found, except pyramidal and stellate cells. In the pre- and parasubiculum, on the other hand, the GABA cells were generally small to medium in size and morphologically more homogeneous than in the subiculum and entorhinal area.The entire retrohippocampal region was densely innervated by GABA preterminal processes, with little variation in the regional density of innervation. Within the entorhinal area, presubiculum and subiculum, a clear difference was found in the laminar pattern of innervation. In all three subfields the densest innervation was in layer II. In the entorhinal area both GAD- and GABA-i axons form palisades of fibers around the somata of neurons, which are tightly packed together in this layer. In the electron microscope both GAD-i and GABA-i were demonstrated in these axons. Axosomatic synaptic contacts were common between axons and the stellate neurons and other cells of this layer. Layers IV and VI appeared less dense in GAD-i terminals but appeared more densely innervated than layers III and V. The lamina dessicans was relatively poor in GAD-i. In the subiculum and presubiculum, as well as all other subfields of the hippocampal region, the innervation is dominated by axo-somatic innervation of layer II cells. The outer third of the molecular layer was more densely innervated than the inner part. Taken together, the present study has shown that the retrohippocampal region is rich in GABAergic neurons as well as axon terminals, some of which form numerous synapic contacts with cells of the region. GABAergic neurotransmission is an important mechanism in retrohippocampal circuits not only for the resident interneuronal population but in the surround as well.     

Lesion-induced plasticity of central neurons: sprouting of single fibres in the rat hippocampus after unilateral entorhinal cortex lesion

In response to a central nervous system trauma surviving neurons reorganize their connections and form new synapses that replace those lost by the lesion. A well established in vivo system for the analysis of this lesion-induced plasticity is the reorganization of the fascia dentata following unilateral entorhinal cortex lesions in rats. After general considerations of neuronal reorganization following a central nervous system trauma, this review focuses on the sprouting of single fibres in the rat hippocampus after entorhinal lesion and the molecular factors which may regulate this process. First, the connectivity of the fascia dentata in control animals is reviewed and previously unknown commissural fibers to the outer molecular layer and entorhinal fibres to the inner molecular layer are characterized. Second, sprouting of commissural and crossed entorhinal fibres after entorhinal cortex lesion is described. Single fibres sprout by forming additional collaterals, axonal extensions, boutons, and tangle-like axon formations. It is pointed out that the sprouting after entorhinal lesion mainly involves unlesioned fibre systems terminating within the layer of fibre degeneration and is therefore layer-specific. Third, molecular changes associated with axonal growth and synapse formation are considered. In this context, the role of adhesion molecules, glial cells, and neurotrophic factors for the sprouting process are discussed. Finally, an involvement of sprouting processes in the formation of neuritic plaques in Alzheimer's disease is reviewed and discussed with regard to the axonal tangle-like formations observed after entorhinal cortex lesion.     

Morphology of spiny neurons in the human entorhinal cortex: intracellular filling with lucifer yellow

The present study was designed to investigate the morphology of spiny neurons in the human entorhinal cortex. Coronal entorhinal slices (n = 67; 200 microm thick) were obtained from autopsies of three subjects. Spiny neurons (n = 132) filled with Lucifer Yellow were analysed in different subfields and layers of the entorhinal cortex. Based on the shape of the somata and primary dendritic trees, spiny neurons were divided into four morphological categories; (i) classical pyramidal, (ii) stellate, (iii) modified stellate, and (iv) horizontal tripolar cells. The morphology of filled neurons varied more in different layers than in the different subfields of the entorhinal cortex. In layer II, the majority (81%) of spiny neurons had stellate or modified stellate morphology, but in the rostromedial subfields (olfactory subfield and rostral subfield) there were also horizontal tripolar neurons. Dendritic branches of layer II neurons extended to layer I (94%) and to layer III (83%). Unlike in layer II, most (74%) of the filled neurons in layers III, V and VI were classical pyramidal cells. The majority of pyramidal cells in the superficial portion of layer III had dendrites that extended up to layer II, occupying the space between the neuronal clusters. Some dendrites reached down to the deep portion of layer III. Apical dendrites of layer V and VI pyramidal cells traveled up to the deep portion of layer III.Our data indicate that the morphology of spiny neurons in different layers of the human entorhinal cortex is variable. Vertical extension of dendritic branches to adjacent layers supports the idea that inputs terminating in a specific lamina influence target cells located in various entorhinal layers. There appears to be more overlap in the dendritic fields between superficial layers II and III than between the superficial (II/III) and deep (V/VI) layers, thus supporting the idea of segregation of information flow targeted to the superficial or deep layers in the human entorhinal cortex.     

The anatomical organization of the rat fascia dentata: new aspects of laminar organization as revealed by anterograde tracing with Phaseolus vulgaris-Leucoagglutinin (PHAL)

The rat fascia dentata is characterized by a simple cytoarchitecture and characteristic lamination of afferents. Entorhinal afferents are believed to terminate exclusively in the outer two thirds of the molecular layer, whereas commissural fibers are believed to terminate exclusively in the inner molecular layer of the fascia dentata. A sharp border divides these two major afferent fiber systems and is regarded as the main boundary of the fascia dentata. This concept of a highly laminated brain structure has made the fascia dentata attractive for studies analyzing normal or pathological processes of the brain. Recently, entorhinal as well as commissural fibers have been identified which do not follow the classical lamination of the fascia dentata. Using anterograde tracing with Phaseolus vulgaris-Leucoagglutinin, an entorhino-dentate projection to the molecular layer, granule cell layer, and hilus of the fascia dentata was described. With the same technique, GABAergic commissural fibers to the outer molecular layer of the fascia dentata were revealed and a previously unknown heterogeneity of the commissural projection was demonstrated. These previously unknown fiber systems complicate the interpretation of lesion effects in this brain region and have to be taken into account as possible sources of sprouting fibers following the partial denervation of the fascia dentata.     

The distribution of tyrosine hydroxylase-immunoreactive fibers in the human entorhinal cortex

The entorhinal cortex plays an important role in learning and memory, and it has been implicated as a site of dysfunction in some neuropsychiatric disorders such as schizophrenia. The organization of many components of the neural circuitry of this region, including dopaminergic afferents, has not been studied in detail. Using immunohistochemical techniques, we examined the density and laminar distribution of axons immunoreactive for tyrosine hydroxylase, the rate limiting enzyme in catecholamine biosynthesis, in the entorhinal cortex of eight control human brains. The density of tyrosine hydroxylase-containing axons decreased from rostral to caudal regions of entorhinal cortex. In addition, there was a prominent medial to lateral gradient of increasing fiber density. This gradient extended into the adjacent transentorhinal cortex, which contained the highest density of labeled axons of the regions studied. The laminar distribution of tyrosine hydroxylase-containing fibers also differed among the subdivisions of the entorhinal cortex. A bilaminar pattern of labeled axons in layers deep I-superficial II and in deep layer VI was present in the intermediate and caudal subdivisions of entorhinal cortex. In contrast, the olfactory and rostral subdivisions, as well as portions of the transentorhinal region, contained a trilaminar pattern, with a high density of tyrosine hydroxylase-immunoreactive axons in layers deep I-superficial II, deep III–IV and deep VI. In addition, radially-oriented bands of labeled fibers were observed extending between deep layer I and layer III, particularly in the rostral subdivision of the entorhinal cortex. In summary, tyrosine hydroxylase-containing afferents to the human entorhinal cortex are distributed in a characteristic regional and laminar pattern, and the lateral regions of the entorhinal cortex and the adjacent transentorhinal cortex are particularly densely innervated.

These data contribute to the understanding of the normal circuitry of the human entorhinal cortex, and are of potential relevance to the pathophysiology of certain neuropsychiatrie disorders, such as schizophrenia.     

Distribution of [3H]cholecystokinin octapeptide binding sites in the hippocampal region of the rat brain as shown by in vitro receptor autoradiography

The distribution of binding sites for the neuropeptide cholecystokinin octapeptide in the rat hippocampal region was studied by using quantitative in vitro receptor autoradiography. Biochemical analysis of [3H]cholecystokinin octapeptide binding to tissue sections of the hippocampal region showed it to be of high affinity, to be saturable and approximately 50% specific at saturating concentrations. The binding of [3H]cholecystokinin octapeptide to hippocampal sections was dose-dependently blocked by cholecystokinin octapeptide, cholecystokinin and by pentagastrin. The autoradiographic analysis showed high densities of [3H]cholecystokinin octapeptide binding sites in the hilus of the area dentata, the outer three layers of the retrosplenial area and the presubiculum, layer 3 of the medial, but not the lateral, entorhinal area and the deep and superficial parts of layer 1 and 2, respectively of both the medial and the lateral entorhinal area. Medium binding densities were found in the parasubiculum and remaining layers of the entorhinal area and low densities occurred in the subiculum and in all subfields of Ammon's horn. The angular bundle and fornix-fimbria lacked specific [3H] cholecystokinin octapeptide binding sites. A very similar pattern of binding densities was found for [3H]pentagastrin. Comparisons of the cholecystokinin octapeptide receptor distribution with the cholecystokinin octapeptide innervation of the hippocampal region suggest that there exists a relatively good concordance in some hippocampal subfields such as the presubiculum and the entorhinal area between binding sites for [3H]cholecystokinin octapeptide and cholecystokinin-immunoreactive afferent input.     

Distribution of neuropeptide Y receptors in the rat hippocampal region

The distribution of binding sites for neuropeptide Y (NPY) was studied in the rat hippocampal region by using [3H]NPY together with quantitative in vitro receptor autoradiography. The highest density of specifically bound [3H]NPY was found in regio superior and regio inferior of Ammon's horn. Within these fields, stratum oriens, stratum pyramidale and stratum radiatum harboured the highest densities of [3H]NPY binding while stratum moleculare was relatively poor in [3H]NPY binding sites. In area dentata, the highest density of [3H]NPY binding was found in the inner one third of the molecular layer. In the presubiculum and in the entorhinal area, the outer two layers were slightly more enriched in [3H]NPY binding sites than were the deep layers. In all hippocampal subfields a clear gradient of increased [3H]NPY binding was found at successively more ventral levels.     

Synchronous discharges in the rat entorhinal cortex in vitro: site of initiation and the role of excitatory amino acid receptors

A slice preparation was used to study the spread of epileptiform activity in the rat entorhinal cortex. Interictal-like discharges were induced in the medial entorhinal cortex by blocking synaptic inhibition mediated via GABAA-receptors. Recorded intracellularly, these discharges consisted of an initial paroxysmal depolarizing shift followed by a variable number of afterdischarges. There was no apparent difference between these events whether they were recorded in isolated cortical slices or in slices where the hippocampus and subicular complex remained attached. The events were also unaffected by droplets of a xylocaine solution applied to sites in the hippocampus, subicular complex or superficial layers of the entorhinal cortex but applications to layer IV/V, lateral or medial to the recording site could reduce the number of afterdischarges without affecting the initial paroxysmal shift. Simultaneous intracellular recordings from neurons in layer IV/V and layer II of the medial entorhinal cortex showed that the paroxysmal depolarizing shift and all afterdischarges in the deeper layer always preceded those recorded in the superficial layer, and these events invariably occurred on a one-to-one basis. This was true whether the events were evoked or occurred spontaneously. The delay varied between 2 and 11 ms but was consistent for a given cell pair. A similar relationship existed between discharges recorded simultaneously in layer IV/V neurons and layer VI neurons, events in the layer IV/V cells preceding those in the deeper layer. Discharges recorded simultaneously in pairs of layer IV/V neurons showed more complex relationships. Paroxysmal depolarizing shifts were always recorded in both cells and the discharge could occur at the more medial site before the more lateral, or vice versa. For a given pair the temporal relationship was invariable. It was often the case, however, that the temporal relationship between afterdischarges was reversed with respect to the initial paroxysmal shift. This relationship was also invariable in a given pair of cells. Interictal-like discharges in layers II or IV/V neurons could be abolished by perfusion with 6-cyano-7-nitro-quinoxaline-2,3-dione which is an antagonist for the non-N-methyl-D-aspartate (i.e. quisqualate/kainate) subtype of excitatory amino acid receptor. The afterdischarges associated with the events were abolished in an all-or-none fashion whereas the blockade of the paroxysmal depolarizing shift was progressive. Antagonists of N-methyl-D-aspartate receptors also abolished afterdischarges but only reduced the initial paroxysmal shift. It is concluded that the interictal-like discharges arise intrinsically within the cortex and are not influenced by input from hippocampal or subicular structures.(ABSTRACT TRUNCATED AT 400 WORDS)     

Degree of hyperinnervation of area dentata by locus coeruleus in the presence of septum or entorhinal cortex as studied by sequential intraocular triple transplantation

Summary In situ area dentata receives a sparse noradrenergic innervation from locus coeruleus. Embryonic area dentata co-transplanted with locus coeruleus to the anterior eye chamber receives an abundant ingrowth of nerves from the noradrenergic neurons of the locus graft. We sought to identify restrictive forces acting on coeruleo-dentate axons by arranging for the innervation of area dentata transplants by either entorhinal cortex or septal nuclei transplants prior to locus coeruleus transplantation. The noradrenergic hyperinnervation was not inhibited when locus coeruleus transplants were placed on the opposite side of area dentata from the entorhinal or septal transplant. Noradrenergic innervation of area dentata was restricted when the locus coeruleus transplant was placed in contact with the septal transplant. This inhibitory interaction seemed to take place between the septal and locus coeruleus transplants rather than in the area dentata neuropil. This type of interaction points towards one means by which axonal growth may be inhibited during development or in the adult.