Enhanced acetylcholinesterase staining in hippocampal area CA3 after lesion of granule cells by infusion of colchicine

Unilateral infusion of colchicine into the lateral ventricle produced relatively selective destruction of dentate granule cells in the ipsilateral dorsal hippocampal formation of the rat. Timms silver sulfide stain is markedly reduced in the mossy fiber layer on the colchicine treated side but is normal contralaterally. After colchicine treatment, an increase in acetylcholinesterase staining is apparent in the apical dendritic zone of CA3 pyramidal cells. This enhanced staining is localized in the proximal apical dendritic layer of CA3, a region normally occupied by the mossy fiber terminals of dentate granule cells. These results suggest that cholinergic fibers proliferate in CA3 after granule cell lesion and may participate in reinnervation of the denervated area.     

Cellular and connective organization of slice cultures of the rat hippocampus and fascia dentata

This study examined the cellular and connective organization of hippocampal tissue taken from 6-8-day-old rats and cultured by the roller tube technique for 3-6 weeks. In the cultures containing the fascia dentata and the hippocampus proper (CA1, CA3, CA4) the main cell and neuropil layers were organotypically organized when observed in ordinary cell stains. The normal distribution of smaller cell populations of AChE-positive neurons and somatostatin-reactive neurons was demonstrated by histochemical and immunohistochemical methods. Both cell types were mainly confined to str. oriens of CA3 and CA1 and the dentate hilus (CA4). Individual dentate granule cells and hippocampal pyramidal cells were injected with lucifer yellow and HRP, revealing great stability of the dendritic patterns of these cells in the culture condition. The same was found for the axonal branching and termination of HRP-filled mossy fibers arising from an HRP-injected granule cell. The preservation of organotypic afferent patterns in the cultures was also shown by Timm staining of the terminal distribution of the mossy fiber system. Mossy fiber terminals, with characteristic ultrastructural features verified in the electron microscope, were thus found in the hilus (CA4) and along the CA3 pyramidal cell layer onto the CA3-CA1 transition. Depending on the amount of dentate tissue relative to CA3 the terminals could stop before reaching CA1 (small fascia dentata) or take up additional intra and infrapyramidal locations along CA3 (small CA3). In cultures with a gap in the CA3 pyramidal cell layer some mossy fiber terminals were found in contact with the CA3 pyramidal cells beyond the gap. In all cultures there was an aberrant projection of supragranular mossy fibers. This projection is analogous to the one known from lesion and transplant studies to form in the absence of the entorhinal perforant path input to the dentate molecular layer. Also, in accordance with these studies the Timm staining pattern of the outer parts of the dentate molecular layer and the entire molecular layer of the hippocampus was altered corresponding to the spread of afferents normally confined to the inner zone of the dentate and str. radiatum of CA3 and CA1. Possibly as a consequence of the lack of normal targets for projections from CA1, this subfield contained an unusually dense Timm staining suggestive of autoinnervation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Growth of hippocampal mossy fibers: a lesion and coculture study of organotypic slice cultures

In hippocampal slice cultures, the mossy fibers from the dentate granule cells project as normally to cells in the dentate hilus (CA4) and the hippocampal CA3 pyramidal cells. After lesions in vivo and intracerebral transplantation, the mossy fibers can alter their normal distribution within CA3 and even contact CA1 pyramidal cells. The present study examined whether similar changes could be induced in the more simple, virtual two-dimensionally organized slice cultures. For this purpose slices of 7-day-old hippocampi were prepared and subjected to one of the two following manipulations: (1) transection of the mossy fiber layer in CA3 or (2) rearrangement of the geometrical relations between the dentate granule cells in their potential targets (CA3 and CA1) by coculturing dentate slices with CA3 or CA1 slices. Two to 8 weeks later the distribution of the mossy fiber system was visualized by histochemical Timm sulphide silver staining of the terminals. The distribution of the mossy fiber system observed in previous studies of ordinary hippocampal slice cultures was confirmed. In addition, mossy fibers were found to cross the cuts through the mossy fiber layer with formation of a reduced number of characteristic Timm-stained terminals in CA3 distal to the lesion. Close proximity and contiguity of the cut surfaces were important for such growth to occur. Significantly fewer mossy fiber terminals were found when separate slices of dentate and CA3 tissue were joined and grown as cocultures. Similar apposition of slices of dentate and CA1 tissue only rarely resulted in the ingrowth of mossy fibers into CA1. The Timm-stained mossy fiber terminals were then of subnormal size. The results show the potentials of the slice culture technique in supplementing lesion and transplant studies in situ. The growth of mossy fibers across a transection of their pathway is thus a new observation, difficult to demonstrate in the brain. The limited growth in the cocultures of aberrant mossy fibers into Ca1 does, on the other hand, emphasize the importance of close structural contact for the formation of nerve connections, and such contact is apparently more easily obtained in the brain. When the growth of the mossy fibers and that of the cholinergic septohippocampal fibers are compared, it is evident that the cholinergic axons grow better both in vitro and in vivo after lesions and transplantation.     

Changes in vesicular transporters for gamma-aminobutyric acid and glutamate reveal vulnerability and reorganization of hippocampal neurons following pilocarpine-induced seizures

The reorganizations of the overall intrinsic glutamatergic and gamma-aminobutyric acid (GABA)-ergic hippocampal networks as well as the time course of these reorganizations during development of pilocarpine-induced temporal lobe epilepsy were studied with in situ hybridization and immunohistochemistry experiments for the vesicular glutamate transporter 1 (VGLUT1) and the vesicular GABA transporter (VGAT). These transporters are particularly interesting as specific markers for glutamatergic and GABAergic neurons, respectively, whose expression levels could reflect the demand for synaptic transmission and their average activity. We report that 1) concomitantly with the loss of some subpopulations of VGAT-containing neurons, there was an up-regulation of VGAT synthesis in all remaining GABA neurons as early as 1 week after pilocarpine injection. This enhanced synthesis is characterized by marked increases in the relative amount of VGAT mRNAs in interneurons associated with increased intensity of axon terminal labeling for VGAT in all hippocampal layers. 2) There was a striking loss of mossy cells during the latent period, demonstrated by a long-term decrease of VGLUT1 mRNA-containing hilar neurons and associated loss of VGLUT1-containing terminals in the dentate gyrus inner molecular layer. 3) There were aberrant VGLUT1-containing terminals at the chronic stage resulting from axonal sprouting of granule and pyramidal cells. This is illustrated by a recovery of VGLUT1 immunoreactivity in the inner molecular layer and an increased VGLUT1 immunolabeling in the CA1-CA3 dendritic layers. These data indicate that an increased activity of remaining GABAergic interneurons occurs during the latent period, in parallel with the loss of vulnerable glutamatergic and GABAergic neurons preceding the reorganization of glutamatergic networks.     

Increased excitatory synaptic input to granule cells from hilar and CA3 regions in a rat model of temporal lobe epilepsy

One potential mechanism of temporal lobe epilepsy is recurrent excitation of dentate granule cells through aberrant sprouting of their axons (mossy fibers), which is found in many patients and animal models. However, correlations between the extent of mossy fiber sprouting and seizure frequency are weak. Additional potential sources of granule cell recurrent excitation that would not have been detected by markers of mossy fiber sprouting in previous studies include surviving mossy cells and proximal CA3 pyramidal cells. To test those possibilities in hippocampal slices from epileptic pilocarpine-treated rats, laser-scanning glutamate uncaging was used to randomly and focally activate neurons in the granule cell layer, hilus, and proximal CA3 pyramidal cell layer while measuring evoked EPSCs in normotopic granule cells. Consistent with mossy fiber sprouting, a higher proportion of glutamate-uncaging spots in the granule cell layer evoked EPSCs in epileptic rats compared with controls. In addition, stimulation spots in the hilus and proximal CA3 pyramidal cell layer were more likely to evoke EPSCs in epileptic rats, despite significant neuron loss in those regions. Furthermore, synaptic strength of recurrent excitatory inputs to granule cells from CA3 pyramidal cells and other granule cells was increased in epileptic rats. These findings reveal substantial levels of excessive, recurrent, excitatory synaptic input to granule cells from neurons in the hilus and proximal CA3 field. The aberrant development of these additional positive-feedback circuits might contribute to epileptogenesis in temporal lobe epilepsy.     

Kainic acid neurotoxicity toward hippocampal formation: Dependence on specific excitatory pathways

Rat hippocampal neurons are extremely sensitive to the neurotoxic action of the potent convulsant, kainic acid. It has been suggested that kainic acid destroys neurons through a specific interaction with excitatory glutamatergic afferent fibers. We have tested this hypothesis by making selective lesions of putatively glutamatergic or non-glutamatergic hippocampal afferent fibers three days prior to injecting kainic acid either intraventricularly or directly into the hippocampal formation.Both destruction of hippocampal mossy fibers with colchicine and transection of these fibers markedly reduced the subsequent toxicity of intraventricular kainic acid toward CA3 neurons, but degeneration of the mossy fibers conferred no protection against kainic acid injected locally. Conversely, removal of projections from the entorhinal cortex or medial septum protected dentate granule cells and all but the most medial CA1 pyramidal cells from destruction by locally injected kainic acid, but did not alter the hippocampal toxicity of intraventricular kainic acid. A commissurotomy little affected the hippocampal lesion made by either route of administration. Both intraventricularly and locally injected kainic acid destroyed neurons in extrahippocampal limbic regions. The pattern of damage could not be accounted for merely by diffusion of the toxin from the site of injection. All four types of hippocampal deafferentation markedly attenuated this extrahippocampal toxicity.These results emphasize the dependence of kainic acid neurotoxicity on specific excitatory circuitry. The identity of the critical circuit depends on the route by which kainic acid is administered, but not on the use of glutamate as a transmitter. We suggest that kainic acid destroys neurons indirectly, by initiating a prolonged status epilepticus that is lethal to seizure-sensitive neurons, such as the hippocampal pyramidal cells.     

Postnatal development of CA3 pyramidal neurons and their afferents in the Ammon's horn of rhesus monkeys

Previous studies described the postnatal development of CA3 pyramidal neurons and their afferents in the rat. However, the postnatal development of the primate hippocampus was not previously studied. Thus, pyramidal neurons of the CA3 area of the monkey hippocampus were analyzed postnatally in the present study. At birth, a few thorny excrescences, the complex spines postsynaptic to mossy fibers, were found on the proximal segments of both apical and basal dendrites, whereas distal dendrites displayed pedunculate spines. Thorny excrescences increased in number until the third month. A continuous increase in the number of spines per unit length along the distal dendrites was observed during the first 12 months. The ultrastructural features of somata and dendrites of pyramidal cells in newborn monkeys were similar to those of adults. The analysis of the afferents to the CA3 pyramidal neurons was limited to the development of mossy fibers, the axons of granule cells, and myelinated axons in the alveus, stratum oriens, and stratum lacunosum-moleculare. At birth, most mossy fiber terminals were densely packed with synaptic vesicles and formed mainly axospinous synapses with CA3 pyramidal cells. By 1 month of age, the number of mitochondria and embedded spines increased to mature amounts. In the first postnatal month, degenerating axons and axon terminals were frequently observed in the mossy fiber bundles in stratum lucidum. The proportion of myelinated axons increased simultaneously in all three examined layers. At birth most axons were unmyelinated, whereas at 7 months of age the proportion of myelinated axons was similar to that found in adults. The present study indicates that most pyramidal neurons of the CA3 region in monkeys are in an advanced stage of development at the time of birth. Thus, mossy fibers from granule cells in the dentate gyrus have established mature-looking synapses, and the thorny excrescences of pyramidal cells that are postsynaptic to mossy fibers are also adult-like. Nevertheless, several of the adult features, such as the spine density of distal dendrites of pyramidal neurons and the myelination of afferent axons, develop during an extended period of time in the first year. The significance of this early anatomical maturation in a brain region involved in memory function is consistent with recent behavioral data that show a rapid postnatal maturation of limbic-dependent recognition memory in rhesus monkeys. © 1995 Wiley-Liss, Inc.     

Coexistence of GABA and glutamate in mossy fiber terminals of the primate hippocampus: an ultrastructural study.

One of the links in the trisynaptic circuit of the hippocampus is the synapse between the mossy fibre terminals of dentate granule cells and CA3 pyramidal cells of Ammon's horn. This synapse has been physiologically characterized as excitatory, and there is pharmacological and immunohistochemical evidence that mossy fibre terminals utilize glutamate as a neurotransmitter. This study demonstrates the presence of GABA-immunoreactivity in mossy fibre axons and terminals of the monkey at the electron microscopic level. We combined Golgi impregnation to identify CA3 pyramidal neurones, with postembedding immunocytochemistry to characterize the inputs to the identified cells. GABA immunoreactivity was present in mossy fibre terminals that made synaptic contact with complex embedded spines of identified Golgi-impregnated CA3 pyramidal neurones. GABA immunoreactivity could be demonstrated in serial sections of the same mossy fibre terminals by using 3 different antisera raised against GABA. In serial sections, the mossy fibre terminals were shown to be immunoreactive for both glutamate and GABA. In contrast, glutamate immunoreactivity but not GABA immunoreactivity was found in other terminals that did not have the morphological characteristics of mossy fibre terminals. GABA immunoreactivity in mossy fibre terminals was also demonstrated in a human surgical specimen of hippocampus. The coexistence of an "excitatory" amino acid and of an "inhibitory" amino acid in the same "excitatory" nerve terminal raises the possibility of corelease of the two transmitters, suggesting that the control of hippocampal neural activity is more complex than hitherto suspected.     

GABA neurons in the superficial layers of the rat dorsal cochlear nucleus: light and electron microscopic immunocytochemistry

This article is an application of light and electron microscopic immunocytochemistry to the study of the neuronal circuit of the superficial layers in the rat dorsal cochlear nucleus (DCN). An antiserum against the intrinsic marker glutamate decarboxylase (GAD) is used to identify and map axon terminals and neurons that use gamma aminobutyric acid (GABA) as a neurotransmitter. It is demonstrated that layers 1 and 2 of the DCN contain a very high density of GABAergic boutons, matched only by the granule cell domains of the ventral cochlear nucleus, especially the superficial granule cell domain. These two layers also contain much higher concentrations of GABAergic cell bodies than all other magnocellular regions of the cochlear nuclear complex. Cartwheel and stellate neurons, and probably also Golgi cells, previously characterized in Golgi and electron microscopic investigations, appear immunostained and, therefore, are presumably inhibitory. The synaptic relations between parallel fibers, the axons of granule cells, and cartwheel and stellate neurons are confirmed. The present study also supports the conclusion that stellate cells are coupled to one another by gap junctions. Also scattered in layer 1 are large, GABAergic neurons that occur with irregular frequency and presumably represent displaced Purkinje cells, previously identified with a Purkinje-cell-specific marker. Granule neurons and pyramidal neurons remain unstained, even after topical injection of colchicine, which enhances immunostaining of the other glutamate-decarboxylase-positive cells, and therefore must use transmitters different from GABA. The possible analogies between the spiny cartwheel and the aspiny stellate cells of the DCN and the cerebellar Purkinje and stellate/basket cells are discussed in the light of data from Golgi, electron microscopy, and transmitter imunocytochemistry.     

Lesion-induced rerouting of hippocampal mossy fibers in developing but not in adult rats

The organization of the hippocampal mossy fiber system which projects from the granule cells of fascia dentata to the pyramidal cells of the hippocampal regio inferior (CA3) was studied after chronic lesions had been applied to CA3 in neonatal (0–3 day old), 5 and 21 day old, and adult rats. The distribution of terminals was monitored by the histochemical Timm sulphide silver method, and the fibers were demonstrated by the original Nauta silver method. Complete transections of CA3 in neonatal rats induced a layer of aberrant, infrapyramidal mossy fiber terminals in CA3 up to 1,300 μm septal to the transection followed by a corresponding expansion of the suprapyramidal mossy fiber layer for at least 720 μm. At increasing distance above the lesion, the induced changes moved laterally in CA3, affecting more distal parts of the mossy fibers. Corresponding to the layer of aberrant infrapyramidal terminals were aberrant bundles of mossy fibers, with an abnormally ascending septal course. No aberrant mossy fibers or terminals were induced temporal to the complete transections. Partial CA3 lesions in neonates induced changes corresponding to those observed after complete transections septal to the lesions. In addition, a layer of aberrant infrapyramidal mossy fiber terminals was induced in CA3 as far as 900 μm temporal to the partial lesions, accompained by an expansion of the suprapyramidal layer. The infrapyramidal terminals were related to aberrant bundles of fibers which followed an abnormally steep, temporal course, from which they in turn leveled off to join the suprapyramidal bundles. Compared to neonatal lesions, hippocampal transections performed on day 5 induced a slightly less dense layer of aberrant infrapyramidal mossy fiber terminals in CA3, and although a transection on day 21 still induced aberrant infrapyramidal terminals, these were far less abundant than after lesions at day 5. Transections in adult rats induced no such changes at all, and additional denervation of CA3 by simultaneous removal of the commisural projection from the contralateral hippocampus did not have any effect. The lesion-induced, but age-dependent redistribution of mossy fibers to CA3 is discussed in terms of reactive reinnervation following partial deafferentation, and compensatory sprouting and rerouting due to pruning-like effects of the lesions. A rerouting of developing, not fully matured mossy fibers is found to be most likely: Deprived of normal target areas, the fibers have been forced to grow in abnormal directions, ending up hyperinnervating adjacent, accessible levels through the formation of aberrant infrapyramidal terminals and expansion of the suprapyramidal zone.     

GABA plasma membrane transporters,GAT-1 and GAT-3, display different distributions in the rat hippocampus

This study evaluates the distribution of two high affinity gamma-aminobutyric acid (GABA) transporters (GAT-1 and GAT-3) in the rat hippocampus using immunocytochemistry and affinity purified antibodies. GAT-1 immunoreactivity was prominent in punctate structures and axons in all layers of the dentate gyrus. In Ammon's horn, immunoreactive processes were concentrated around the somata of pyramidal cells, particularly at their basal regions. The apical and basal dendritic fields of pyramidal cells also displayed numerous GAT-1 immunoreactive punctate structures and axons. The zone of termination of the mossy fibers that includes both the hilus of the dentate gyrus and stratum lucidum of the CA3 area was the lightest immunolabeled region of the hippocampal complex. Electron microscopic preparations demonstrated that GAT-1 immunoreactive axon terminals form symmetric synapses with somata, axon initial segments, and dendrites of granule and pyramidal cells in the dentate gyrus and Ammon's horn, respectively. Immunoreactivity was localized to the plasma membrane and the cytoplasm of axon terminals. The somata of previously described local circuit neurons in the dentate gyrus and Ammon's horn contained GAT-1 immunoreactivity associated with the Golgi complex. Light, diffuse GAT-3 immunoreactivity was present throughout the hippocampal formation. Thin, astrocytic glial processes displayed GAT-1 and GAT-3 immunoreactivity. This localization of GAT-1 and GAT-3 indicates that they are involved in the uptake of GABA from the extracellular space into GABAergic axon terminals and astrocytes. © 1996 Wiley-Liss, Inc.     

Connections of the hippocampal formation in humans: I. The mossy fiber pathway

The hippocampal formation has been one of the most extensively studied cortical regions in rats, yet little is known about the anatomical connections of the hippocampus in primates, especially humans. With the use of an antibody against the calcium-binding protein, calbindin-D28K, in normal autopsy tissue and the neuronal tracers biocytin or biotinylated dextrans in in vitro slice preparations from tissue removed during surgery for intractable epilepsy, we examined the human hippocampal mossy fiber pathway. The injections of biocytin into the dentate granule cell layer labeled neurons in a Golgi-like manner, revealing the presence of basal dendrites on about 30% of the granule cells. The granule cell axons, the mossy fibers, initially formed a diffuse plexus of fibers in the polymorphic layer before organizing into fiber fascicles in the hilar pyramidal region. These fiber fascicles were much more prominent rostrally than caudally. Within the hilus and proximal portions of the extrahilar CA3 field, the mossy fibers ran through the pyramidal cell layer, and while near the transition to field CA2, the fibers turned superficially and crossed the pyramidal layer to run in the stratum lucidum. All of these features, seen following injections of tracer into hippocampal slices from the brains of epileptics, were confirmed by calbindin-staining of mossy fibers in normal brains. Biocytin-labeled mossy fiber axons revealed two characteristic types of enlargements: small varicosities and larger expansions. The expansions were found throughout the neuropil and were highly irregular, diaminobenzidine-dense profiles that had pleiomorphic modes of attachment to the parent axon. Electron microscopic images of these biocytin labeled expansions revealed that they were large synaptic boutons bearing asymmetric synapses. This study indicates that the human mossy fiber pathway shows some minor deviations from the rodent brain but little difference from monkeys. We argue that these changes mirror a phylogenetic growth of the CA3 pyramidal neurons (subfield CA3c) into the hilus rather than an evolutionary change of the mossy fiber pathway. This growth of subfield CA3c and the increase in mossy fibers running through the pyramidal layer (and a presumed accompanying increase in proximal basal dendritic contacts) may reflect a growing role of the projection from the dentate granule cells to subfield CA3c and from there to field CA1 in the primate hippocampus. J. Comp. Neurol. 385:325–351, 1997. © 1997 Wiley-Liss, Inc.     

Ultrastructural description of taurine-like immunoreactive cells and processes in the rat hippocampus

A monoclonal antibody against taurine conjugated to KLH was used to identify and describe taurine-like immunoreactive processes in the rat hippocampus. Tissue from perfused rats was processed for immunohistochemical visualization of taurine and embedded for electron microscopy. Representative tissue samples from three regions, the dentate gyrus, CA3, and CA1, were sectioned, examined, and photographed. In the dentate gyrus, both granule cells and pyramidal basket cells were taurine-like immunoreactive. Some axon terminals in the dentate gyrus molecular layer as well as some mossy fiber boutons in the hilus were also taurine-like immunoreactive. In the CA3 region both pyramidal neurons and glial cells were taurine-like immunoreactive A few small-diameter axon terminals in stratum radiatum and some mossy fiber boutons in stratum lucidum were taurine-like immunoreactive. In CA1, pyramidal neurons and some glia were intensely taurine-like immunoreactive. A few immunoreactive axon terminals were seen in stratum radiatum and stratum oriens. In all regions, dendritic staining predominated. Our results support the hypothesis that while taurine may act as a neurotransmitter in a small portion of hippocampal terminals, its main function is probably as a neuromodulator or ionic regulator.     

Stimulation-induced status epilepticus: role of the hippocampal mossy fibers in the seizures and associated neuropathology

A study of seizure activity and neuronal cell death produced by intracerebroventricular kainic acid had suggested that seizures conveyed by the hippocampal mossy fibers are more damaging to CA3 pyramidal cells than seizures conveyed by other pathways. To test this idea, the effects of a unilateral mossy fiber lesion were determined on seizure activity and neuronal degeneration provoked by repetitive electrical stimulation of the hippocampal fimbria in unanesthetized rats. Fimbrial stimulation resulted in self-sustained status epilepticus accompanied by neuronal degeneration in several brain regions, including area CA3 of the hippocampal formation. A unilateral mossy fiber lesion more readily attenuated the electrographic and behavioral seizures provoked by fimbrial stimulation than those provoked by kainic acid. If status epilepticus developed in the presence of a mossy fiber lesion, denervated CA3 pyramidal cells were still destroyed, although similar lesions protect these neurons from kainic acid-induced status epilepticus. Thus the two models of status epilepticus employ somewhat different seizure circuitries and neurodegenerative mechanisms. Seizures which involve the mossy fiber projection are not necessarily more damaging to CA3 pyramidal cells than seizures which do not.     

Ultrastructural localization of neurotransmitter immunoreactivity in mossy cell axons and their synaptic targets in the rat dentate gyrus

Electrophysiologically identified and intracellularly biocytin-labeled mossy cells in the dentate hilus of the rat were studied using electron microscopy and postembedding immunogold techniques. Ultrathin sections containing a labeled mossy cell or its axon collaterals were reacted with antisera against the excitatory neurotransmitter glutamate and against the inhibitory neurotransmitter γ-aminobutyric acid (GABA). From single- and double-immunolabeled preparations, we found that 1) mossy cell axon terminals made asymmetric contacts onto postsynaptic targets in the hilus and stratum moleculare of the dentate gyrus and showed immunoreactivity primarily for glutamate, but never for GABA; 2) in the hilus, glutamate-positive mossy cell axon terminals targeted GABA-positive dendritic shafts of hilar interneurons and GABA-negative dendritic spines; and 3) in the inner molecular layer, the mossy cell axon formed asymmetric synapses with dendritic spines associated with GABA-negative (presumably granule cell) dendrites. The results of this study support the view that excitatory (glutamatergic) mossy cell terminals contact GABAergic interneurons and non-GABAergic neurons in the hilar region and GABA-negative granule cells in the stratum moleculare. This pattern of connectivity is consistent with the hypothesis that mossy cells provide excitatory feedback to granule cells in a dentate gyrus associational network and also activate local hilar inhibitory elements. Hippocampus 1997;7:559–570. © 1997 Wiley-Liss, Inc.     

Early loss of interneurons and delayed subunit-specific changes in GABA(A)-receptor expression in a mouse model of mesial temporal lobe epilepsy

Unilateral injection of kainic acid (KA) into the dorsal hippocampus of adult mice induces spontaneous recurrent partial seizures and replicates histopathological changes observed in human mesial temporal lobe epilepsy (MTLE) (Bouilleret V et al., Neuroscience 1999; 89:717-729). Alterations in pre- and postsynaptic components of GABAergic neurotransmission were investigated immunohistochemically at different time points (1-120 days) in this mouse model of MTLE. Markers of GABAergic interneurons (parvalbumin, calbindin-D28k, and calretinin), the type-1 GABA transporter (GAT1), and major GABA(A)-receptor subunits expressed in the hippocampal formation were analyzed. Acutely, KA injection produced a profound loss of hilar cells but only limited damage to CA1 and CA3 pyramidal cells. In addition, parvalbumin and calbindin-D28k staining of interneurons disappeared irreversibly in CA1 and dentate gyrus (DG), whereas calretinin staining was spared. The prominent GABA(A)-receptor alpha1 subunit staining of interneurons also disappeared after KA treatment, suggesting acute degeneration of these cells. Likewise, GAT1 immunoreactivity revealed degenerating terminals at 24 h post-KA in CA1 and DC and subsided almost completely thereafter. Loss of CA1 and, to a lesser extent, CA3 neurons became evident at 7-15 days post-KA. It was more accentuated after 1 month, accompanied by a corresponding reduction of GABA(A)-receptor staining. In contrast, DC granule cells were markedly enlarged and dispersed in the molecular layer and exhibited a prominent increase in GABA(A)-receptor subunit staining. After 4 months, the dorsal CA1 area was lost almost entirely, CA3 was reduced, and the DG represented most of the remaining dorsal hippocampal formation. No significant morphological alterations were detected contralaterally. These results suggest that loss of hilar cells and GABAergic neurons contributes to epileptogenesis in this model of MTLE. In contrast, long-term degeneration of pyramidal cells and granule cell dispersion may reflect distinct responses to recurrent seizures. Finally, GABA(A)-receptor upregulation in the DG may represent a compensatory response persisting for several months in epileptic mice.     

Comparative localization of enkephalin and cholecystokinin immunoreactivities and heavy metals in the hippocampus

The present study is concerned with the cellular origins and identities of the hippocampal enkephalin and CCK-immunoreactive fibers and terminals. In the hippocampus of the rat, the guinea pig and the European hedgehog a system of enkephalin immunoreactive nerves emerges in the hilus of area dentata and can be followed to the apical dendrites of the hippocampal regio inferior pyramidal cells. This pattern of immunoreactive nerves corresponds to the hippocampal mossy fiber system as visualized by the Timm staining. Cholecystokinin immunoreactive nerve fibers and terminals reveal the same distribution in the guinea pig and the European hedgehog whereas in the rat the mossy fiber zone contains little or no cholecystokinin immunoreactivity. In the guinea pig degeneration of the mossy fibers after stereotactic lesions of the mossy fibers causes a complete loss of both enkephalin and cholecystokinin immunoreactivity in the mossy fiber zone. Only a few enkephalin immunoreactive cell bodies were scattered throughout the granular cell layer of area dentata, but inhibition of the axoplasmic transport by colchicine dramatically increased the number of enkephalin immunoreactive granule cell bodies. Enkephalin immunoreactive cell bodies were also detected in the hilus, throughout the pyramidal cell layer as well as in the stratum radiatum and stratum moleculare. Cholecystokinin immunoreactive cell bodies were seen in the hilus of the area dentata and in the stratum oriens, stratum pyramidale and stratum radiatum and the cell-rich layer of subiculum. No cholecystokinin immunoreactive cell bodies were observed in the granular cell layer of area dentata. Even after colchicine treatment the granule cells were devoid of cholecystokinin immunoreactivity. In the rat a system of nerves displaying enkephalin immunoreactivity was also observed in the superficial one-third of the molecular layer of area dentata, a zone which corresponds to the termination of the lateral perforant path. Another observation was that in the rat, but not in the guinea pig and the hedgehog, the terminal zone of both the medial perforant path and the zone of commissural and associational fibers of area dentata contained cholecystokinin immunoreactive molecules. In summary, our data show: (1) that the hippocampal mossy fibers contain enkephalin immunoreactive molecules; (2) that the cholecystokinin immunoreactivity in the mossy fiber zone is most likely also localized in the mossy fibers per se, although the granule cells seem devoid of cholecystokinin immunoreactivity; (3) zinc, here visualized as a Timm-positive substance, is also localized in the mossy fiber terminals; further, (4) other intrinsic cell bodies than the granule cells may contribute to both the enkephalin and cholecystokinin immunoreactive terminals within the hippocampus; (5) in the rat the lateral perforant path may be enkephalinergic; and (6) both the terminal zone of the medial perforant path and the associational and commissural fibers of the rat contain cholecystokinin immunoreactivity.     

Selective death of hippocampal CA3 pyramidal cells with mossy fiber afferents after CRH-induced status epilepticus in infant rats

Previous studies of CRH-induced status epilepticus in infant rats demonstrated neuronal loss in several limbic structures, including the CA3 region of the hippocampus. The goal of the present study was to identify the neurons affected by CRH-induced seizures and determine whether they formed synapses with afferent axon terminals. Clusters of neurons in the CA3 region of the hippocampus were osmiophilic when viewed in thick sections. Semi-thin 2-μ sections of the pyramidal cell layer contained dark, shrunken neurons with apical and basal dendrites among normal appearing pyramidal cells. Electron microscopy revealed degenerating pyramidal cells with intact cell membranes and electron dense nuclei and cytoplasm. The shrunken dendrites of these cells had spines and were postsynaptic to large immature-appearing mossy fibers. Thus, CA3 pyramidal neurons that are linked via mossy fibers to the tri-synaptic excitatory hippocampal circuit die subsequent to CRH-induced status epilepticus. The shrunken appearance and selective loss of these neurons are incompatible with necrosis as the mechanism of degeneration.     

Secretoneurin: A marker in rat hippocampal pathways

Secretoneurin is a 33-amino acid peptide, generated in brain by proteolytic processing of secretogranin II. The distribution of secretoneurin-like immunoreactivity and secretogranin II mRNA was investigated in the hippocampus of the rat. Secretogranin II mRNA was found in high concentrations throughtout the granule cell and pyramidal cell layers and in many local neurons, notably in the hilus of the dentate gyrus. The general distributional pattern of secretoneurin-like immunoreactivity was characterized by a prominent staining in the area of the terminal field of mossy fibers with an obvious staining in the infrapyramidal area of CA3 and a strongly immunopositive band in the inner third of the molecular layer of the dentate gyrus. Lesions of the granule cells by local injection of colchicine significantly reduced secretoneurin-like immunoreactivity in the terminal field of mossy fibers, but not in the inner molecular layer of the dentate gyrus. On the other hand, destruction of interneurons of the dentate gyrus (mossy cells and certain γ-aminobutyric acid-ergic interneurons) by kainic acid—induced seizures was associated with a reduction of secretoneurin-like immunoreactivity in the inner molecular layer of the dentate gyrus. However, 30 days after kainic acid—induced seizures, a strongly secretoneurin-immunoreactive band reappeared in this area, which at this late time point is due to sprouting of mossy fibers collaterals. Our experiments suggest a widespread distribution of secretoneurin-like immunoreactivity in neurons of the hippocampal formation with a preferential localization in excitatory pathways including associational/commissural fibers originating from secretoneurin-containing mossy cells. J. Comp. Neurol. 377:29-40, 1997. © 1997 Wiley-Liss, Inc.