Axonal Anatomy Optimizes Spatial Encoding in the Rat Entorhinal-Dentate System: A Computational Study

OBJECTIVE

The network architecture connecting neural regions is defined by the organization and anatomical properties of the projecting axons, but its contributions to neural encoding and system function are difficult to study experimentally.

METHODS

Using a large-scale, spiking neuronal network model of rat dentate gyrus, the role of the anatomy of the entorhinal-dentate axonal projection was evaluated in the context of spatial encoding by incorporating grid cell activity to provide physiological, spatially-correlated input. The dorso-ventral extents of the entorhinal axon terminal fields were varied to generate different feedforward architectures, and the resulting spatial representations and spatial information scores of the network were evaluated. Position was decoded from the population activity using a point process filter to investigate the contributions of network architecture on spatial encoding.

RESULTS

The model predicted the emergence of anatomical gradients within the dentate gyrus for place field size and spatial information along its dorso-ventral axis, which were dependent on the extents of the entorhinal axon terminal fields. The decoding results revealed an optimal performance at an axon terminal field extent of 2 mm that lies within the biological range.

CONCLUSION

The axonal anatomy mediates a tradeoff between encoding multiple place field sizes or achieving a high spatial information score, and the combination of both properties is necessary to maximize spatial encoding by a network.

SIGNIFICANCE

In total, this paper establishes a mechanistic neuronal network model that, in concert with information-theoretic and statistical methods, can be used to investigate how lower level properties contribute to higher level function.

The role of topography in the transformation of spatiotemporal patterns by a large-scale, biologically realistic model of the rat dentate gyrus

A large-scale, biologically realistic, computational model of the rat hippocampus is being constructed to study the input-output transformation that the hippocampus performs. In the initial implementation, the layer II entorhinal cortex neurons, which provide the major input to the hippocampus, and the granule cells of the dentate gyrus, which receive the majority of the input, are modeled. In a previous work, the topography, or the wiring diagram, connecting these two populations had been derived and implemented. This paper explores the consequences of two features of the topography, the distribution of the axons and the size of the neurons' axon terminal fields. The topography converts streams of independently generated random Poisson trains into structured spatiotemporal patterns through spatiotemporal convergence achievable by overlapping axon terminal fields. Increasing the axon terminal field lengths allowed input to converge over larger regions of space resulting in granule activation across a greater area but did not increase the total activity as a function of time as the number of targets per input remained constant. Additional simulations demonstrated that the total distribution of spikes in space depends not on the distribution of the presynaptic axons but the distribution of the postsynaptic population. Analyzing spike counts emphasizes the importance of the postsynaptic distribution, but it ignores the fact that each individual input may be carrying unique information. Therefore, a metric should be created that relates and tracks individual inputs as they are propagated and integrated through hippocampus.

Running induces widespread structural alterations in the hippocampus and entorhinal cortex

Physical activity enhances hippocampal function but its effects on neuronal structure remain relatively unexplored outside of the dentate gyrus. Using Golgi impregnation and the lipophilic tracer DiI, we show that long-term voluntary running increases the density of dendritic spines in the entorhinal cortex and hippocampus of adult rats. Exercise was associated with increased dendritic spine density not only in granule neurons of the dentate gyrus, but also in CA1 pyramidal neurons, and in layer III pyramidal neurons of the entorhinal cortex. In the CA1 region, changes in dendritic spine density are accompanied by changes in dendritic arborization and alterations in the morphology of individual spines. These findings suggest that physical activity exerts pervasive effects on neuronal morphology in the hippocampus and one of its afferent populations. These structural changes may contribute to running-induced changes in cognitive function.

Plasticity of synaptopodin and the spine apparatus organelle in the rat fascia dentata following entorhinal cortex lesion

Synaptopodin is an actin-associated molecule essential for the formation of a spine apparatus in telencephalic spines. To study whether synaptopodin and the spine apparatus organelle are regulated under conditions of lesion-induced plasticity, synaptopodin and the spine apparatus were analyzed in granule cells of the rat fascia dentata following entorhinal denervation. Confocal microscopy was employed to quantify layer-specific changes in synaptopodin-immunoreactive puncta densities. Electron microscopy was used to quantify layer-specific changes in spine apparatus organelles. Within the denervated middle and outer molecular layers, the layers of deafferentation-induced spine loss, synaptogenesis, and spinogenesis, the density of synaptopodin puncta and the number of spine apparatuses decreased by 4 days postlesion and slowly recovered in parallel with spinogenesis by 180 days postlesion. Within the nondenervated inner molecular layer, the zone without deafferentation-induced spine loss, a rapid loss of synaptopodin puncta and spine apparatuses was also observed. In this layer, spine apparatus densities recovered by 14 days postlesion, in parallel with plastic remodeling at the synaptic level and the postlesional recovery of granule cell activity. These data demonstrate layer-specific changes in the distribution of synaptopodin and the spine apparatus organelle following partial denervation of granule cells: in the layer of spine loss, spine apparatus densities follow spine densities; in the layer of spine maintenance, however, spine apparatus densities appear to be regulated by other signals.

Feedforward inhibition regulates perirhinal transmission of neocortical inputs to the entorhinal cortex: ultrastructural study in guinea pigs

The rhinal cortices constitute the main route for impulse traffic to and from the hippocampus. Tracing studies have revealed that the perirhinal cortex forms strong reciprocal connections with the neo- and entorhinal cortex (EC). However, physiological investigations indicate that perirhinal transmission of neocortical and EC inputs occurs with a low probability. In search of an explanation for these contradictory findings, we have analyzed synaptic connections in this network by combining injections of the anterograde tracer Phaseolus vulgaris-leucoagglutinin (PHAL) into the neocortex, area 36, or area 35 with gamma-aminobutyric acid (GABA) immunocytochemistry and electron microscopic observations. Within area 36, neocortical axon terminals formed only asymmetric synapses, usually with GABA-negative spines (87%), and less frequently with GABA-immunopositive (GABA+) dendrites (13%). A similar synaptic distribution was observed within area 35 except that asymmetric synapses onto GABA+ dendrites were more frequent (23% of synapses). Examination of the projections from area 36 to area 35 and from both regions to the EC revealed an even higher incidence of asymmetric synapses onto GABA+ dendrites (35 and 32%, respectively) than what was observed in the neocortical projection to areas 36 and 35. Furthermore, some of the neocortical and perirhinal terminals containing PHAL and GABA immunolabeling formed symmetric synapses onto GABA-negative dendrites in their projection sites (neocortex to area 35, 16%; area 36 to 35, 7%; areas 36-35 to EC, 12%). Taken together, these findings suggest that impulse transmission through the rhinal circuit is subjected to strong inhibitory influences, reconciling anatomical and physiological data about this network.

Status Epilepticus in 12-day-old Rats Leads to Temporal Lobe Neurodegeneration and Volume Reduction: A Histologic and MRI Study

PURPOSE

Whether status epilepticus (SE) in early infancy, rather than the underlying illness, leads to temporal lobe neurodegeneration and volume reduction remains controversial.

METHODS

SE was induced with LiCl-pilocarpine in P12 rats. To assess acute neuronal damage, brains (five controls, five with SE) were investigated at 8 h after SE by using silver and Fluoro-Jade B staining. Some brains from the early phase were processed for electron microscopy. To assess chronic changes, brains from nine controls and 13 rats with SE at P12 were analyzed after 3 months by using histology and magnetic resonance imaging (MRI).

RESULTS

MRI analysis of the temporal lobe of adult animals with SE at P12 indicated that 23% of the rats had hippocampal, 15% had amygdaloid, and 31% had perirhinal volume reduction. Histologic analysis of sections from the MR-imaged brains correlated with the MRI data. Analysis of neurodegeneration 8 h after SE by using both silver and Fluoro-Jade B staining revealed degenerating neurons located in the same temporal lobe regions as the volume reduction in chronic samples. Electron microscopic analysis revealed irreversible ultrastructural alterations. As with the chronic histologic and MRI findings, interanimal variability was seen in the distribution and severity of acute damage.

CONCLUSIONS

Our data indicate that SE at P12 can cause acute neurodegeneration in the hippocampus as well as in the adjacent temporal lobe. It is likely that acute neuronal death contributes to volume reduction in temporal lobe regions that is detected with MRI in a subpopulation of animals in adulthood.

A novel population of calretinin-positive neurons comprises reelin-positive Cajal-Retzius cells in the hippocampal formation of the adult domestic pig

Calretinin-containing neurons in the hippocampal formation, including the subiculum, presubiculum, parasubiculum, and entorhinal cortex, were visualized with immunocytochemistry. Calretinin immunoreactivity was present exclusively in non-principal cells. The largest immunoreactive cell population was found in the outer half of the molecular layer of the dentate gyrus and in the stratum lacunosum-moleculare of Ammon's horn. A proportion of these cells were also immunoreactive for reelin, a Cajal-Retzius cell marker. Similar calretinin-positive cells were found in the molecular layer of the subicular complex and entorhinal cortex. In the parasubiculum, a few immunoreactive bipolar and multipolar cells could be observed in the superficial and deep pyramidal cell layers. In the entorhinal cortex, bipolar and multipolar calretinin-positive cells were frequent in layer II, and large numbers of multipolar cells in layer V were immunoreactive. Electron microscopic analysis showed that somata of calretinin-positive cells contained either round nuclei with smooth nuclear envelopes or nuclei with multiple deep infoldings. Immunoreactive dendrites were smooth varicose, and the apposing axon terminals formed both symmetric and asymmetric synapses. Zonula adherentia were observed between calretinin-positive dendrites. Calretinin-positive axon terminals formed two types of synapses. Axon terminals with asymmetric synapses were found close to the hippocampal fissure, whereas axon terminals forming symmetric synapses innervated spiny dendrites in both the molecular layer of the dentate gyrus and in stratum lacunosum-moleculare of Ammon's horn. Calretinin-positive axon terminals formed both symmetric and asymmetric synapses with calretinin-positive dendrites. In conclusion, calretinin-positive neurons form two major subpopulations in the adult domestic pig hippocampus: (1) a gamma-aminobutyric acid (GABA)ergic subpopulation of local circuit neurons that innervates distal dendrites of principal cells in both the dentate gyrus and in Ammon's horn; and (2) Cajal-Retzius type cells close to the hippocampal fissure, as well as in the molecular layer of the subicular complex and entorhinal cortex.

Input from the presubiculum to dendrites of layer-V neurons of the medial entorhinal cortex of the rat

The entorhinal cortex (EC) and the hippocampus are reciprocally connected. Neurons in the superficial layers of EC project to the hippocampus, whereas deep entorhinal layers receive return connections. In the deep layers of EC, pyramidal neurons in layer V possess apical dendrites that ascend towards the cortical surface through layers IIII and II. These dendrites ramify in layer I. By way of their apical dendrites, such layer-V pyramidal cells may be exposed to input destined for the superficial entorhinal neurons. A specific and dense fiber projection that typically ends in superficial entorhinal layers of the medial EC originates in the presubiculum. To investigate whether apical dendrites of deep entorhinal pyramidal neurons indeed receive input from this projection, we injected the anterograde tracer PHA-L in the presubiculum or we lesioned the presubiculum, and we applied in the same experiments the tracer Neurobiotin trade mark pericellularly in layer V of the medial EC of 17 rats. PHA-L labeled presubiculum axons in the superficial layers apposing apical segments of Neurobiotin labeled layer-V cell dendrites were studied with a confocal fluorescence laserscanning microscope. Axons and dendrites were 3D reconstructed from series of confocal images. In cases in which the presubiculum had been lesioned, material was investigated in the electron microscope. At the confocal fluorescence microscope level we found numerous close contacts, i.e. appositions of boutons on labeled presubiculum fibers with identified dendrites of layer-V neurons. In the electron microscope we observed synapses between degenerating axon terminals and spines on dendrites belonging to layer-V neurons. Hence we conclude that layer-V neurons receive synaptic contacts from presubiculum neurons. These findings indicate that entorhinal layer-V neurons have access to information destined for the superficial layers and eventually the hippocampal formation. At the same time, they have access to the hippocampally processed version of that information.

Morphological and numerical analysis of synaptic interactions between neurons in deep and superficial layers of the entorhinal cortex of the rat

Neurons providing connections between the deep and superficial layers of the entorhinal cortex (EC) constitute a pivotal link in the network underlying reverberation and gating of neuronal activity in the entorhinal-hippocampal system. To learn more of these deep-to-superficial neurons and their targets, we applied the tracer Neurobiotin pericellularly in layer V of the medial EC of 12 rats. Labeled axons in the superficial layers were studied with light and electron microscopy, and their synaptic organization recorded. Neurobiotin-labeled layer V neurons displayed "Golgi-like" staining. Two major cell types were distinguished among these neurons: (1) pyramidal neurons with apical spiny dendrites traversing all layers and ramifying in layer I, and (2) horizontal neurons with dendrites confined to the deep layers. Labeled axons ramified profusely in layer III, superficially in layer II and deep in layer I. Analysis of labeled axon terminals in layers I-II and III showed that most synapses (95%) were asymmetrical. Of these synapses, 56% occurred with spines (presumably belonging to principal neurons) and 44% with dendritic shafts (presumably interneurons). A small fraction of the synapses (5%) was of the symmetrical type. Such synapses were mainly seen on dendritic shafts. We found in two sections a symmetrical synapse on a spine. These findings suggest that the deep to superficial projection is mainly excitatory in nature, and that these fibers subserve both excitation and feed-forward inhibition. There is an additional, much weaker, inhibitory component in this projection, which may have a disinhibitory effect on the entorhinal network in the superficial layers.

The effects of combined fluid percussion traumatic brain injury and unilateral entorhinal deafferentation on the juvenile rat brain

The current study was designed to address the effects of traumatic brain injury (TBI) on plasticity and reorganization in the juvenile brain. Given that two of the major pathological sequelae of TBI involve a generalized neuroexcitation insult and diffuse axonal injury, we have employed models of these pathologies, delivered either independently or in combination, to examine their effects on injury-induced synaptic reorganization of the dentate gyrus in the developing rat. Postnatal day 28 rats received either sham, central fluid percussion traumatic brain injury (TBI), unilateral entorhinal cortical lesion (UEC), or TBI+UEC (TUEC) injury. Cognitive performance was assessed in the Morris water maze (MWM) between 11 and 15 days post-injury and the brains were processed for synaptophysin immunohistochemistry and routine electron microscopy. The MWM results revealed that TBI or UEC lesions delivered independently do not produce significant morbidity in P28 rats. However, when these injuries are combined, they reveal significant deficits in the MWM, accompanied by measurable changes in the distribution of presynaptic synaptophysin immunoreactivity over the deafferented dentate molecular layer. These observations are further supported by qualitative ultrastructural alterations in synaptic architecture in the same subregions of the dentate neuropil. The present findings show that the resilience of the immature brain following TBI is reduced when neuroexcitatory insult is combined with deafferentation. Moreover, when deafferented tissue is assessed morphologically, evidence exists for aberrant plasticity and abnormal synaptic reorganization in the juvenile brain.

Animal model of dementia induced by entorhinal synaptic damage and partial restoration of cognitive deficits by BDNF and carnitine

A rat dementia model with cognitive deficits was generated by synapse-specific lesions using botulinum neurotoxin (BoNTx) type B in the entorhinal cortex. To detect cognitive deficits, different tasks were needed depending upon the age of the model animals. Impaired learning and memory with lesions were observed in adult rats using the Hebb-Williams maze, AKON-1 maze and a continuous alternation task in T-maze. Cognitive deficits in lesioned aged rats were detected by a continuous alternation and delayed non-matching-to-sample tasks in T-maze. Adenovirus-mediated BDNF gene expression enhanced neuronal plasticity, as revealed by behavioral tests and LTP formation. Chronic administration of carnitine over time pre- and post-lesions seemed to partially ameliorate the cognitive deficits caused by the synaptic lesion. The carnitine-accelerated recovery from synaptic damage was observed by electron microscopy. These results demonstrate that the BoNTx-lesioned rat can be used as a model for dementia and that cognitive deficits can be alleviated in part by BDNF gene transfer or carnitine administration.

[Argyrophilic grain disease (AgD), a frequent and largely underestimated cause of dementia in old patients]

Argyrophilic grain disease (AgD) is a late-onset dementia morphologically characterized by abundant neuropil grains (ArGs). ArGs are mainly found in the CA1 subfield of the cornu ammonis, entorhinal and transentorhinal cortices, the amygdala and the hypothalamic lateral tuberal nuclei. We have recently shown that abnormally phosphosphorylated tau protein is the main protein constituent of ArGs and that tau is hyperphosphorylated in up to 80p.100 of nerve cels in areas rich in ArGs. We could demonstrate that at least a subset of grains are formed within dendrites and dendritic side-branches of neurons containing hyperphosphylated tau. Morphology of dendrites containing grains suggests that a process of progressive dendritic shrinkage is taking place in neurons bearing ArGs. Furthermore it became apparent that the presence of ArGs is not necessarily associated with a cognitive decline. Our studies on AgD cases with and without dementia suggest that AgD is a progressive neurodegenerative disorder with early subclinical lesions in anterior part of the hippocampal formation. At later stages involvement of more caudal parts of the hippocampal formation generally results in a cognitive decline. Thus, one possible explanation for the dementia observed in some subjects with AgD is that there is a more widepread loss of postsynaptic structures, including synaptic contacts, throughout the hippocampus-entorhinal/parahippocampal complex and the amygdaloid nuclei. Most of the reported AgD cases are associated with neurofibrillary lesions (e.g. neurofibrillary tangles) which are also typical of Alzheimer's disease (AD). However, neurofibrillary changes do not exceed early (entorhinal and limbic) Braak stages which generally are not associated with a cognitive decline. Additional neuropathological features of AgD include oligodendroglial tau filamentous inclusions ( coiled bodies ), ballooned neurons and astrocytic tau pathology. The clinical features of AgD are poorly understood. However, preliminary data from retrospective studies suggest that in AgD behavioural disturbances will precede memory failure and memory decline. Furthermore, it has been shown that the ApoEe4 allele does not constitute a risk factor for the development of AgD. In conclusion it seems very likely that AgD is a distinct dementing disorder of old age that has to be distinguished from other tauopathies, e.g. AD, by both morphological and genetic criteria.

Differential synaptic localization of GluR2 and EAAC1 in the macaque monkey entorhinal cortex: a postembedding immunogold study

The synaptic distribution of alpha-amino-3-hydroxy-5-methyl-4-isoxazole-propionic acid receptor subunit GluR2 and neuronal glutamate transporter subunit EAAC1 were studied using immunogold in layer II of the macaque monkey entorhinal cortex. Immunoreactivity for EAAC1 and GluR2 was frequent at asymmetric synapses and their associated membrane. The synaptic localization of EAAC1 differed considerably from that of GluR2, in that GluR2 immunolabelling was most commonly located within the postsynaptic density, but EAAC1 localization was more heterogeneous and was predominant at the edge of postsynaptic densities and perisynaptic zones. Since EAAC1 may play an important role in clearing glutamate from the synaptic cleft and intercellular spaces, the high perisynaptic expression of EAAC1 in these neurons could presumably offer a powerful mechanism through which high concentrations of glutamate could be efficiently removed from the synapses following release and interaction with glutamate receptors. The distribution of EAAC1 may also offer protection for these neurons against excessive glutamatergic stimuli that may occur under certain pathological conditions.

Transient accumulation of Gallyas-Braak-positive and phosphorylated tau-immunopositive substances in neuronal lipofuscin granules in the amygdala, hippocampus and entorhinal cortex of rats during long-term chloroquine intoxication

Long-term chloroquine (CQ) intoxication of normal and groggy mutant rats resulted in transient accumulation of Gallyas-Braak (G-B) -positive and phosphorylated tau (AT8) -immunopositive substances in neuronal lipofuscin granules in the amygdala, hippocampus and entorhinal cortex. In the facial nuclei of normal rats, the neuronal lipofuscin granules were only AT8-immunopositive but G-B-negative, throughout CQ intoxication, while in groggy rats, the granules were positive by both staining methods irrespective of CQ intoxication. The results indicate that there are different mechanisms in the production of G-B-positive substances in neuronal lipofuscin granules between CQ-intoxicated rats and untreated groggy mutant rats.

Calretinin in the entorhinal cortex of the rat: distribution, morphology, ultrastructure of neurons, and co-localization with gamma-aminobutyric acid and parvalbumin

Calretinin is a marker that differentially labels neurons in the central nervous system. We used this marker to distinguish subtypes of neurons within the general population of neurons in the entorhinal cortex of the rat. The distribution, morphology, and ultrastructure of calretinin-immunopositive neurons in this cortical area were documented. We further analyzed the co-localization of the marker with gamma-aminobutyric acid (GABA) and studied whether calretinin-positive neurons project to the hippocampal formation. Methods used included single-label immunocytochemistry at the light and electron microscopic level, retrograde tracing combined with immunocytochemistry, and double-label confocal laser scanning microscopy (CLSM). The entorhinal cortex contained calretinin-positive cells in a scattered fashion, in all layers except layer IV (lamina dissecans). Bipolar and multipolar dendritic configurations were present, displaying smooth dendrites. Bipolar cells had a uniform morphology whereas the multipolar calretinin cell population consisted of large neurons, cells with long ascending dendrites, horizontally oriented neurons, and small spherical cells. Retrograde tracing combined with immunocytochemistry showed that calretinin is not present in cells projecting to the hippocampus. Few synapic contacts between calretinin-positive axon terminals and immunopositive cell bodies and dendrites were seen. Most axon terminals of calretinin fibers formed asymmetrical synapses, and immunopositive axons were always unmyelinated. Results obtained in the CLSM indicate that calretinin co-exists in only 18-20% of the GABAergic cell population (mostly small spherical and bipolar cells). Thus, the entorhinal cortex contains two classes of calretinin interneurons: GABA positive and GABA negative. The first class is presumably a classical, GABAergic inhibitory interneuron. The finding of calretinin-immunoreactive axon terminals with asymmetrical synapses suggests that the second class of calretinin neuron is a novel type of a (presumably excitatory) interneuron.

Regionally selective changes in brain lysosomes occur in the transition from young adulthood to middle age in rats

The possibility that brain aging in rats exhibits regional variations of the type found in humans was studied using lysosomal chemistry as a marker. Age-related (two vs 12months; male Sprague-Dawley) differences in cathepsin D immunostaining were pronounced in the superficial layers of entorhinal cortex and in hippocampal field CA1, but not in neocortex and field CA3. Three changes were recorded: an increase in the intraneuronal area occupied by labeled lysosomes; clumping of immunopositive material within neurons; more intense cytoplasmic staining. Western blot analyses indicated that the increases involved the active forms of cathepsin D rather than their proenzyme. Shrinkage of cathepsin-D-positive neuronal cell bodies was observed in entorhinal cortex but not in neocortical sampling zones. Age-related lysosomal changes as seen with cathepsin B immunocytochemistry were considerably more subtle than those obtained with cathepsin D antibodies. In contrast, a set of glial and/or vascular elements located in a distal dendritic field of the middle-aged hippocampus was much more immunoreactive for cathepsin B than cathepsin D. The areas exhibiting sizeable changes in the present study are reported to be particularly vulnerable to aging in humans. The results thus suggest that aspects of brain aging common to mammals help shape neurosenescence patterns in humans.

Dopamine innervation of monkey entorhinal cortex: postsynaptic targets of tyrosine hydroxylase-immunoreactive terminals

Dopamine (DA) has been demonstrated to play an important role in regulating cortical activity in both neocortical and periallocortical regions. However, marked differences between these two types of cortices in the laminar pattern of DA axons, the types and distribution of DA receptors, and the postnatal development of the DA innervation suggest that DA may have region-specific effects. Such regional specialization may also include the types of cortical cells apposed to DA terminals. In neocortical regions, such as the prefrontal and motor cortices, the majority of structures apposed to DA terminals appear to be the dendritic spines and shafts of pyramidal cells, and a minority are dendrites immunoreactive for gamma-amino butyric acid (GABA). However, the identity of the neural elements apposed to DA terminals in the entorhinal cortex, a periallocortical region, is unknown. In this study, we used immunocytochemical techniques and antibodies against tyrosine hydroxylase (TH) and GABA, visualized with preembedding immunoperoxidase and immunogold-silver labels, respectively, to examine DA terminals and their targets with electron microscopy. In the superficial layers of the monkey entorhinal cortex, TH-immunoreactive (IR) terminals varied greatly in size and formed thin, symmetric synapses. The majority of dendritic structures apposed to these TH-terminals were not GABA-IR, and included both dendritic shafts (64%) and spines (14%). A minority (22%) of the apposed dendrites were GABA-IR. A similar distribution of targets was observed for the subset of TH-IR terminals with identifiable synaptic specializations. In addition, the proportions of GABA-labeled and unlabeled dendrites apposed to TH terminals did not differ from those previously reported for monkey prefrontal cortex. These findings indicate that DA terminals provide direct input to both excitatory and inhibitory cells in the monkey entorhinal cortex and suggest that the effects of DA are mediated through a set of targets that are common to both neo- and periallocortex.

Ultrastructural characterizations of olfactory pathway neurons in layer II of the entorhinal cortex in monkey

The somatic size, shape, dendritic and axonal morphology, and synaptology of representative neurons in layer II of the primate entorhinal cortex (EC) were analyzed. Layer II "islands" contained large spinous multipolar cells with triangular somata and local circuit axons in addition to multipolar neurons with large, radially arrayed, aspinous, primary processes and thick tapering axons. Small pyramidal neurons with a single, spinous, apical primary segment that bifurcated a short distance from the somata were also found in layer II. Subsequent spinous segments of these neurons with long terminal segments exhibited a paucity of branching in addition to having thick axons tapering into subjacent layers. The importance of providing these additional axonal, dendritic, and synaptic characterizations lies in the contextual role these neurons play in the connectional patterns of the EC with regard to olfaction, olfactory memory, and pathological variations.

Seizure-induced cell death produced by repeated tetanic stimulation in vitro: possible role of endoplasmic reticulum calcium stores

Seizures may cause brain damage due to mechanisms initiated by excessive excitatory synaptic transmission. One such mechanism is the activation of death-promoting intracellular cascades by the influx and the perturbed homeostasis of Ca2+. The neuroprotective effects of preventing the entry of Ca2+ from voltage-dependent Ca2+ channels, NMDA receptors, and non-NMDA receptors, is well known. Less clear is the contribution to excitotoxicity of Ca2+ released from endoplasmic reticulum (ER) stores. We produced epileptiform discharges in combined entorhinal cortex/hippocampus slices using repeated tetanic stimulation of the Schaffer collaterals and assessed cell death after 1, 3, or 12-14 h with gel electrophoresis of genomic DNA and immunohistologically using terminal deoxynucleotidyl transferase (TdT)-mediated deoxyuridine 5'-triphosphate (dUTP) nick end labeling (TUNEL) staining. We manipulated ER Ca2+ stores using two conventional drugs, dantrolene, which blocks the Ca2+ release channel, and thapsigargin, which blocks sarco-endoplasmic reticulum Ca2+-ATPases resulting in depletion of ER Ca2+ stores. To monitor epileptogenesis, and to assess effects attributable to dantrolene and thapsigargin on normal synaptic transmission, extracellular potentials were recorded in stratum pyramidale of the CA1 region. Repeated tetanic stimulation reliably produced primary afterdischarge and spontaneous epileptiform discharges, which persisted for 14 h, the longest time recorded. We did not observe indications of cell death attributable to seizures with either method when assessed after 1 or 3 h; however, qualitatively more degraded DNA always was observed in tetanized slices from the 12- to 14-h group compared with time-matched controls. Consistent with these data was a significant, fourfold, increase in the percentage of TUNEL-positive cells in CA3, CA1, and entorhinal cortex in tetanized slices from the 12- to 14-h group (16. 5 +/- 4.4, 33.7 +/- 7.1, 11.6 +/- 2.1, respectively; means +/- SE; n = 7) compared with the appropriate time-matched control (4.1 +/- 2.2, 7.3 +/- 2.0, 2.8 +/- 0.9, respectively; n = 6). Dantrolene (30 microM; n = 5) and thapsigargin (1 microM; n = 4) did not affect significantly normal synaptic transmission, assessed by the amplitude of the population spike after 30 min of exposure. Dantrolene and thapsigargin also were without effect on the induction or the persistence of epileptiform discharges, but both drugs prevented seizure-induced cell death when assessed with gel electrophoresis. We suggest that Ca2+ entering a cell from the outside, in addition to the Ca2+ contributed from ryanodine-sensitive stores (i.e., Ca2+-induced Ca2+ release), may be necessary for seizure-induced cell death.

Ultrastructure and immunocytochemical distribution of GABA in layer III of the rat medial entorhinal cortex following aminooxyacetic acid-induced seizures

Layer III of the entorhinal cortex (EC) is lesioned in patients with temporal lobe epilepsy (TLE). A similar neuropathology is also present in different animal models of TLE. For example, injection of the "indirect" excitotoxin aminooxyacetic acid (AOAA) into the EC of rats causes behavioral seizures and preferential loss of neurons in layer III of the medial EC. The animals also develop hyperexcitability of the EC and the hippocampal region CA1. To further explore the neuropathological changes within the EC, the ultrastructure and distribution of GABA-like immunoreactivity were assessed in layer III, 28 days after an intraentorhinal AOAA injection. At this time point, light microscopic preparations revealed that a large proportion of pyramidal (putative excitatory) neurons in layer III of the medial EC had degenerated, whereas GABA-immunoreactive neurons had survived. In immunogold-labeled ultrathin sections, the lesioned neuropil was found to contain morphologically intact GABA-containing neurons and nerve terminals. Pathologically swollen dendrites and electron-dense neuronal profiles were present in the lesioned sector as well. The majority of the electron-dense profiles was identified as degenerating dendritic spines that were closely apposed to strongly glutamate-immunopositive axon terminals. Thus, the entorhinal chemoarchitecture is dramatically altered following an episode of AOAA-induced epileptic seizures. One possible consequence of this pathology is a reduced "drive" of the surviving layer III GABA neurons, which in turn may cause hyperexcitability of the EC and the hippocampus. These findings may be of relevance for the genesis and spread of temporal lobe seizures.

Reelin regulates the development and synaptogenesis of the layer-specific entorhino-hippocampal connections

Here we examine the role of Reelin, an extracellular protein involved in neuronal migration, in the formation of hippocampal connections. Both at prenatal and postnatal stages, the general laminar and topographic distribution of entorhinal projections is preserved in the hippocampus of reeler mutant mice, in the absence of Reelin. However, developing and adult entorhinal afferents show severe alterations, including increased numbers of misrouted fibers and the formation of abnormal patches of termination from the medial and lateral entorhinal cortices. At perinatal stages, single entorhinal axons in reeler mice are grouped into thick bundles, and they have decreased axonal branching and decreased extension of axon collaterals. We also show that the number of entorhino-hippocampal synapses is lower in reeler mice than in control animals during development. Studies performed in mixed entorhino-hippocampal co-cultures combining slices from reeler and wild-type mice indicate that these abnormalities are caused by the lack of Reelin in the target hippocampus. These findings imply that Reelin fulfills a modulatory role during the formation of layer-specific and topographic connections in the hippocampus. They also suggest that Reelin promotes maturation of single fibers and synaptogenesis by entorhinal afferents.

Dendritic changes in Alzheimer's disease and factors that may underlie these changes

It seems likely that the Alzheimer disease (AD)-related dendritic changes addressed in this article are induced by two principally different processes. One process is linked to the plastic response associated with deafferentation, that is, long-lasting transneuronally induced regressive changes in dendritic geometry and structure. The other process is associated with severe alterations of the dendritic- and perikaryal cytoskeleton as seen in neurons with the neurofibrillary pathology of AD, that is, the formation of paired helical filaments formed by hyperphosphorylated microtubule-associated protein tau. As the development of dendritic and cytoskeletal abnormalities are at least mediated by alterations in signal transduction, this article also reviews changes in signal pathways in AD. We also discuss transgenic approaches developed to model and understand cytoskeletal abnormalities.

Tracing of the entorhinal-hippocampal pathway in vitro

In vitro tract tracing allowing for continuous observation of the perforant path is a crucial prerequisite for experimental studies on the entorhinal-hippocampal interaction in an organotypic slice culture containing the entorhinal cortex, the perforant path, and the dentate gyrus (OEHSC). We prepared horizontal slices of the temporal entorhinal-hippocampal region of the rat on a vibratome, and the perforant path axons were traced by application of the fluorescent tracer Mini Ruby on the entorhinal cortex. After 2 days in vitro (div), the perforant path became visible in most cultures. Entorhinal neurons and single perforant fibers could be followed to the outer molecular layers of the dentate gyrus by in vitro fluorescence microscopy and it was possible to monitor the perforant path directly over a period of 25 div. Moreover, ultrastructural analysis proved the existence of traced perforant path boutons forming synapses with spines and dendritic shafts in the outer molecular layers of the dentate gyrus. Transsection of the prelabelled perforant path in vitro resulted in anterograde degeneration and subsequent phagocytosis of axonal material by activated microglial cells in the zone of denervation. In conclusion, in vitro tracing demonstrates the maintenance of the entorhinal-hippocampal pathway in OEHSCs and permits monitoring of dynamic changes in the prelabeled perforant path after various lesion paradigms, e.g., transsection or neurotoxin treatment. This approach permits further studies on the efficacy of neuroprotectants, cytokines, and growth factors in the treatment of lesion-induced neuronal degeneration.

Morphological characteristics of layer II projection neurons in the rat medial entorhinal cortex

The entorhinal cortex receives inputs from a variety of neocortical regions. Neurons in layer II of the entorhinal cortex originate one component of the perforant path which conveys this information to the dentate gyrus and hippocampus. The current study extends our previous work on the electro-responsive properties of layer II neurons of the medial entorhinal cortex in which we distinguished two categories of layer II neurons based on their electrophysiological attributes (Alonso and Klink [1993] J Neurophysiol 70: 128-143). Here we report on the morphological features of layer II projection neurons, as revealed by in vitro intracellular injection of biocytin. We now report that the two electrophysiologically distinct types of neurons correspond to morphologically distinct types of cells. All neurons (65% of the total cells recorded) that developed sustained, subthreshold, sinusoidal membrane potential oscillations were found to have a stellate appearance. Neurons that did not exhibit oscillatory behavior had either a pyramidal-like (32%) or a horizontal cell morphology (3%). Stellate cells had multiple, thick, primary dendrites. Their widely diverging upper dendritic domain expanded mediolaterally over a distance of around 500 microns close to the pial surface. This mediolateral extent was more than double that of the pyramidal-like cells. Dendrites of stellate cells demonstrated long dendritic appendages, and their dendritic spines had a more complex morphology than those of nonstellates. The stellate cell axons emerged from a primary dendrite and were more than double the thickness (approximately 1.4 microns) of the axons of nonstellate cells. Recurrent axonal collaterization appeared more extensive in axons arising from stellate cells than from pyramidal-like cells.

Dystrophic neurites are associated with early stage extracellular neurofibrillary tangles in the parkinsonism-dementia complex of Guam

We found tangle-associated neuritic clusters (TANCs), previously reported as being present in Alzheimer's disease (AD), to be common in early and mild cases of the parkinsonism-dementia complex of Guam (PDC, bodig disease). These entities were observed around extracellular neurofibrillary tangles (eNFTs), apparently as a transient phenomenon. They were not observed around normal neurons, or neurons with intracellular neurofibrillary tangles (iNFTs). They were also not observed around late stage eNFTs. The TANCs contained both type 1 (elongated) and type 2 (globular) dystrophic neurites, as well as small, granular structures. The type 1 dystrophic neurites in TANCs were immunostained by antibodies to neuroskeletal proteins, while type 2 dystrophic neurites were immunostained by antibodies to amyloid precursor protein (APP). The eNFTs surrounded by TANCs were almost all immunopositive for amyloid P, while only some were immunopositive for C4d, and only a minority had beta-amyloid protein (A beta) associated with them. We hypothesize that the eNFTs are a source of complement activation which results in destruction of surrounding neurites. We further hypothesize that the degenerating neurites are a source of A beta which forms long-term deposits around eNFTs.

Topographical organization of projections from the entorhinal cortex to the striatum of the rat

The efferent projections of the entorhinal cortex to the striatum were studied with retrograde (horseradish peroxidase wheat germ agglutinin) and anterograde (biocytin and biotinylated dextran amine) tracing methods. The bulk of the entorhinal cortical fibres were found to project to the nucleus accumbens in the ventral striatum, but the caudate putamen is only sparsely and diffusely innervated, rostrally, along its dorsal and medial borders. Fibres arising from neurons in the lateral entorhinal cortex project throughout the rostrocaudal extent of the nucleus accumbens but are most abundant in the core and lateral shell of that nucleus. The rostral neurons of the medial entorhinal cortex were found to project sparsely to the striatum, whereas caudal neurons provide a dense input to the rostral one-third of the nucleus accumbens, especially to the rostral pole, where they concentrate more in the core than in the shell. Contralateral entorhinal projections, which are very sparse, were found in the same parts of the nucleus accumbens and the caudate-putamen as the ipsilateral terminal fields. The present observations that entorhinal inputs to the nucleus accumbens are regionally aligned suggest that disruption of these connections could produce site-specific deficits with, presumably, specific behavioural consequences.

Evidence for recovery of spatial learning following entorhinal cortex lesions in mice

The influence of entorhinal cortex lesions on behaviour and concommitant changes in synaptophysin immunoreactivity (IR) in the denervated dentate gyrus was assessed. Male, C57/B6 mice received either bilateral (BI), unilateral (UNI), or no lesion (SHAM) to the entorhinal cortex. At various stages post-lesion the animals were evaluated in tests to examine neurological and cognitive (spatial and cued learning, Morris water maze) function. UNI lesioned animals from 6-36 days post-lesion showed no neurological nor marked cued learning deficit, yet a profound spatial learning deficit. However by 70 days post-lesion, spatial learning ability was clearly evident. In contrast, BI lesioned animals showed severe spatial learning deficits throughout the test period (6-70 days), cued learning was also impaired. In parallel groups of UNI lesioned mice, 6-36 days post-lesion there was a marked reduction (-40%) in synaptophysin IR in the dentate gyrus molecular layer. However by 70 days post-lesion a clear increase in this measure was noted. Changes in the expression of the growth associated protein, GAP43, were also noted over this period. Taken together, the present results suggest some recovery of spatial learning following unilateral entorhinal cortex lesions in mice. This behavioural recovery of a hippocampally dependant task may be associated with a recovery of function related to the synaptic remodelling and elevation of synapse number in the denervated hippocampus, as evidenced by changes in synaptophysin and GAP43 IR.

The alvear pathway of the rat hippocampus

Neurons of the entorhinal cortex project to the hippocampus proper and dentate gyrus. This projection is called the "perforant pathway" because it perforates the subiculum; current usage applies this term to all entorhino-hippocampal fibers. However, entorhinal fibers also reach Ammon's horn via the alveus ("alvear pathway"), an alternative route first described by Cajal. The anterograde tracer Phaseolus vulgaris leucoagglutinin (PHAL) was used in order to analyze the contribution of this pathway to the temporo-ammonic projection. In the temporal portion of the rat hippocampus, most of the entorhinal fibers reach Ammon's horn after perforating the subiculum (classical perforant pathway). At more septal levels, the number of entorhinal fibers that take the alvear pathway increases; in the septal portion of the hippocampal formation, most of the entorhinal fibers to hippocampal subfield CA1 reach this subfield via the alveus. These fibers make sharp right-angle turns in the alveus, perforate the pyramidal cell layer, and finally terminate in the stratum lacunosum-moleculare. The crossed temporo-ammonic fibers reach their termination area in the stratum lacunosum-moleculare of CA1 almost exclusively via the alveus. These data indicate that the alveus is a major route by which entorhinal fibers reach their targets in CA1.

Reciprocal entorhinal-hippocampal connections established by human fetal midgestation

Little is known about the timing or sequence of genesis of connections between different areas of the developing human cerebral cortex. It has been shown that connections between areas V1 and V2 of the visual isocortex are established at about 37 weeks of gestation (Burkhalter [1993] Cerebr. Cortex 3:476-487), suggesting that cortico-cortical connections appear late in the 40-week human gestational period. However, there are indications from other studies that connections between subdivisions of the hippocampal formation may be established much earlier, by about 20 weeks of human gestation. To investigate this possibility, the lipophilic bidirectional tracer 1,1' dioctadecyl-3,3,3',3-tetramethylindocarbocyanine perchlorate (DiI) was used to study connections between the entorhinal cortex, hippocampus, and temporal lobe neocortex in paraformaldehyde-fixed postmortem fetal tissue. The DiI transport revealed robust reciprocal connections between the entorhinal cortex, hippocampus, and subiculum, which were consistently present at 19 weeks of gestation (the earliest age studied), and which were anatomically similar to those in adult primates. Specifically, projections to the hippocampus and subiculum originated from neurons in the entorhinal cortex (EC) layers 2 and 3, whereas reciprocal projections to the EC originated from pyramidal neurons in the cornu ammonis region CA1 and the subiculum. In contrast, the perforant pathway projection from EC to the dentate gyrus, and all connections with the neocortex, reached only rudimentary stages of development by 22 weeks of gestation (the latest age studied). These findings suggest that hippocampal pathways develop prior to isocortical pathways, and that reciprocal entorhinal-hippocampal projections may be among the first cortico-cortical connections to be established in the human brain.

Long-lasting transneuronal changes in rat dentate granule cell dendrites after entorhinal cortex lesion. A combined intracellular injection and electron microscopy study

Following entorhinal cortex lesion, inhibitory hippocampal neurons show a persistent rarefication of those dendrites formally receiving entorhinal input. Physiological data indicate a long lasting disequilibrium of inhibition and excitation in the de-entorhinated hippocampus. We analyzed the intracellularly-stained dendritic tree of de-entorhinated excitatory rat granule cells. Granule cells of controls and animals surviving 2, 8, 60 and 270 days after unilateral entorhinal cortex lesion were impaled. Dendrites of control cells were of typical shape, traced to the hippocampal fissure and a complete dye filling of dendrites was ascertained by EM-analysis. Conversely, 60 and 270 days following lesioning, dendrites were only rarely seen to extend into the outer portions of the molecular layer and the dendritic architecture became significantly rarefied. Sixty days post-lesion, intracellularly filled dendrites extending to the middle molecular layer were surrounded by cell clusters resembling glia. Some of these contained the neuronally applied dye, suggesting a close association of the cytosolic compartments with the altered dendrites. These observed alterations exceed the process of sprouting and de novo synaptogenesis of remaining afference for long periods of time. The dendritic morphology of both inhibitory and excitatory neurons seems to require specific input from the entorhinal cortex. Moreover, sprouting of remaining afferents is apparently not sufficient to compensate for this loss of input.

A novel entorhinal projection to the rat dentate gyrus: direct innervation of proximal dendrites and cell bodies of granule cells and GABAergic neurons

Entorhinal fibers to the fascia dentata originating from layer II stellate neurons are known to terminate exclusively in the outer two thirds of the molecular layer, where they innervate distal dendritic portions of dentate neurons. Using anterograde tracing with Phaseolus vulgaris leucoagglutinin, we unraveled a previously unknown entorhinal projection that directly innervates proximal dendritic portions and somata of granule cells and GABAergic neurons. This projection originates from neurons located in entorhinal layers IV-VI of the medial entorhinal area. These fibers enter the outer two thirds of the molecular layer, traverse the inner molecular layer (IML) and granule cell layer, where they form numerous boutons, and finally arborize subjacent to the granule cells. Correlated light and electron microscopy revealed that the boutons formed by these fibers establish asymmetric synapses on dendrites in the IML, on spines and somata of granule cells, and on spineless dendrites subjacent to the granule cell layer. Postembedding immunogold staining indicates that this entorhino-dentate projection is not GABAergic and that it also terminates on GABAergic inhibitory neurons. These data demonstrate that not all entorhino-dentate fibers display a similar high laminar specificity for the outer molecular layer (OML). Although fibers from the superficial layers of the entorhinal cortex terminate exclusively in the OML, entorhinal fibers arising from deeper layers are not confined to laminar boundaries. Finally, the possibility that these supposedly excitatory entorhinal afferents may monosynaptically activate proximal dendrites and somata of dentate neurons needs to be incorporated into contemporary concepts of the hippocampal network.

In Alzheimer's disease the Golgi apparatus of a population of neurons without neurofibrillary tangles is fragmented and atrophic

Recent immunocytochemical and morphometric studies in amyotrophic lateral sclerosis, Alzheimer's disease (AD), and aging indicate that the neuronal Golgi apparatus is a reliable index of activity or degeneration. To further evaluate a possible role of the Golgi apparatus in the pathogenesis of AD, we examined by double labeling the neuronal Golgi apparatus, neurofibrillary tangles (NFTs), and senile plaques (SPs) in the hippocampus of six cases of AD, and in 13 controls including three cases of a rare form of dementia lacking distinctive histopathological features. The Golgi apparatus was visualized with a polyclonal antiserum against MG-160, a membrane sialoglycoprotein of the organelle, and NFTs and SPs were visualized with biotinylated basic fibroblast growth factor (bFGF). Only a rare SP contained a few small immunostained elements of the Golgi apparatus. Neurons with intracellular NFTs, labeled with biotinylated bFGF, contained intensely labeled but deformed Golgi apparatus, which was displaced by the NFTs and coalesced into larger irregular granules. In contrast, a population of neurons without NFTs displayed fragmentation of the Golgi apparatus, ie, the organelle appeared in the form of small round, disconnected, and dispersed elements instead of the normal perinuclear network of irregular or linear profiles which often extended into the proximal segments of dendrites. In addition, the fragmented neuronal Golgi apparatus was atrophic as the percentage of the cell surface area occupied by the organelle was 4.4 +/- 0.6% SD, whereas in neurons with a normal Golgi apparatus the percentage of the cell surface area occupied by the organelle was 10.3 +/- 0.3% SD. The results of this study suggest that in AD the Golgi apparatus of a population of neurons without NFTs is involved in the pathogenesis of the disease. Considering the role of the Golgi apparatus in the processing of polypeptides destined for fast axoplasmic transports, the fragmentation of the organelle may be associated with functional and structural impairments of axons and presynaptic terminals.

Sprouting of crossed entorhinodentate fibers after a unilateral entorhinal lesion: anterograde tracing of fiber reorganization with Phaseolus vulgaris-leucoagglutinin (PHAL)

Fibers from the contralateral entorhinal cortex (EC) to the dentate gyrus partially replace the input lost after an ipsilateral EC lesion. To study the morphology and course of single sprouted crossed entorhinodentate fibers, the anterograde tracer Phaseolus vulgaris-leucoagglutinin (PHAL) was used. Rats that survived for 4 to 8 weeks after a unilateral entorhinal lesion received PHAL deposits into the entorhinal cortex contralateral to the lesion. Control animals received a similar PHAL deposit. Single PHAL-labeled fibers in the molecular layer of the contralateral (EC lesion) fascia dentata were drawn with a camera lucida, and an axon-branching index (branch points/100 microns axon length) was calculated for these crossed entorhinodentate fibers in controls and operated animals. In animals with EC lesions, the density of PHAL-labeled crossed entorhinodentate fibers had increased remarkably. Single crossed entorhinodentate axons showed significantly more axon branch points in experimental than in control animals. In addition, some axon segments displayed high densities of small axonal extensions. Frequently, tanglelike structures were observed in the denervated outer molecular layer. These tangles consisted of one or more PHAL-labeled axons that intertwined and formed an axon tangle filled completely with branches, extensions, and boutons. Our data indicate that crossed EC fibers sprout by forming additional collaterals, axonal extensions, and tangles. Abnormal neurite formations are a characteristic feature of plaques in Alzheimer's disease. Future studies must be done to show whether or not there is a close relationship between axonal tangles and plaques in Alzheimer's disease, which, like the present lesion paradigm, severely affects entorhinal projection neurons.

Domoic acid-induced neuronal degeneration in the primate forebrain revealed by degeneration specific histochemistry

Domoic acid is a potent excitotoxin produced by diatoms which is subsequently passed along the marine food chain. Its chemical structure and toxicological properties are similar to kainic acid. Like kainic acid, exposure results in extensive hippocampal degeneration. The effect of domoic acid on other primate brain structures, however, is less resolved. In an attempt to clarify this issue, the present study applied a degeneration specific histochemical technique (de Olmos' cupric-silver method) to reveal degeneration within the brains of domoic acid-dosed cynomolgus monkeys. Degenerating neuronal cell bodies and terminals were found not only within the hippocampus, but also within a number of other 'limbic' structures including the entorhinal cortex, the subiculum, the piriform cortex, the lateral septum, and the dorsal lateral nucleus of the thalamus. Although the hippocampus is a component of the original limbic circuit of Papez, other components such as the mammillary bodies, the anterior nucleus of the thalamus and the cingulate cortex contained no degeneration, while a number of more recently documented efferent targets of the hippocampal formation revealed extensive degeneration. The pattern of degeneration generally correlated with those regions containing high densities of kainate receptors.

Failure of axon regeneration in postnatal rat entorhinohippocampal slice coculture is due to maturation of the axon, not that of the pathway or target

Horizontal slices which included the entorhinal area in continuity with the hippocampus were taken from the ventral levels of the cerebral hemispheres of rat pups from two age groups, from the 6th to the 8th postnatal days ('young') and the 12th to the 15th days ('old'). The slices were divided into an entorhinal part and a hippocampal part (which consisted of the hippocampus proper, dentate gyrus and subiculum) by a knife cut passing through the deep white matter of the entorhinal area. The slices were recombined in their normal orientation by matching the cut edges in the following age combinations: young/young, old/old, young/old and old/young. After 14 days in culture, crystals of biocytin were placed on the superficial layers of the entorhinal area. In the young/young combination the same placement of biocytin simultaneously labelled projections passing in both directions across the interface, i.e. (i) orthograde transport of biocytin taken up by entorhinal projection neurons resulted in labelling of axons passing from the entorhinal area across the interface between the cocultures to reach the correct terminal zone in the outer molecular layer of the dentate gyrus, and (ii) retrograde transport of biocytin taken up by axons and their terminals in the entorhinal area labelled the slender subicular and adjacent hippocampal field CA1 pyramidal cells whose axons project to the entorhinal area. In the old/old cocultures there were no projections in either direction. In the mixed age combinations, young entorhinal cortical tissue projected correctly across the interface to old dentate gyrus, but old entorhinal tissue did not project to young dentate gyrus.(ABSTRACT TRUNCATED AT 250 WORDS)

Electron microscopy of cell islands in layer II of the primate entorhinal cortex

An electron microscopic analysis of cell islands in layer II of the entorhinal cortex from rhesus monkeys was made to determine the ultrastructural features of these unique neuronal clusters. The rostral, intermediate, and caudal divisions of the entorhinal cortex were selected for electron microscopic examination. In the rostral division, neurons were grouped together in prominent clusters, often with 10 or more contiguous somata. Somatic and dendrosomatic appositions were frequent, without intervening cellular processes or specialized junctions. Somata were relatively small, typically 10-15 microns in diameter, with oval or circular nuclei that were euchromatic and contained nucleoli. Small nuclear infoldings were commonly seen. A thin shell of perikaryal cytoplasm contained numerous organelles. Axosomatic synapses were infrequent, with a mean of only 1.0 synapse per neuron per thin section. The neuropil contained numerous synapses, and myelinated axons were seen infrequently. In the intermediate division, somatic appositions were rarely observed. Somata were relatively large, typically 15-20 microns in diameter, and displayed a moderate amount of cytoplasm. Axosomatic synapses were relatively common, with a mean of 3.3 synapses per neuron per thin section. In the caudal division, neurons were typically grouped in clusters of two to three contiguous somata. Neurons were about 15 microns in diameter and displayed a moderate amount of cytoplasm. Axosomatic synapses were of moderate frequency, with a mean of 2.5 synapses per neuron per thin section. The neuropil in the caudal division displayed a relatively high frequency of myelinated axons. Our analysis of three regions of the entorhinal cortex revealed significant differences in the frequency of somatic appositions and axosomatic synapses, and in certain ultrastructural features of the somata and neuropil. These results showed that cell islands in layer II of the entorhinal cortex display regional morphologic differences. The paucity of symmetric axosomatic synapses in the rostral division may correlate with this region's vulnerability in certain diseases.

Lamina-specific synaptic connections of hippocampal neurons in vitro

By using slice cultures as a model, we demonstrate here that different target selectivities exist among the various afferent fibers to the hippocampus. As in intact animals, septohippocampal cholinergic fibers, provided by a slice culture of septum, innervate a co-cultured slice of hippocampus diffusely, that is, without forming distinct layers of termination. As in vivo, the septal cholinergic fibers establish synapses with a variety of target cells. Conversely, fibers from an entorhinal slice co-cultured to a hippocampal slice display their normal laminar specificity. They preferentially terminate in the outer molecular layer of the fascia dentata, thereby selectively contacting peripheral dendrites of the granule cells. This preferential termination on peripheral dendritic segments is remarkable, since these fibers do not have to compete with commissural fibers, hypothalamic fibers, and septal afferents for dendritic space under these culture conditions. Moreover, in triplet cultures in which first two hippocampal slices were co-cultured and then, with a delay of 5 days, an entorhinal slice was added, the fibers from the entorhinal slice and those from the hippocampal culture terminated in their appropriate layers in the hippocampal target culture. However, in this approach the normal sequence of ingrowth of these two afferents was reversed. In normal ontogenetic development, entorhinal afferents arrive in the hippocampus before the commissural fibers. The results show that there are different degrees of target selectivity of hippocampal afferents and that the characteristic lamination of certain afferent fibers in the hippocampus is not determined by their sequential ingrowth during development.

Quantitative morphological analysis of subicular terminals in the rat entorhinal cortex

In the present report, we describe a morphological and quantitative analysis of subicular synapses in layer V of the lateral entorhinal cortex (LEA) of the rat. Projections from the dorsal subiculum were labeled anterogradely, and areas in LEA showing high terminal density were randomly selected for ultrathin sectioning. More than 400 terminals in LEA were photographed in the electron microscope, and synapse types and postsynaptic targets were identified and, subsequently, quantified with the unbiased disector method. Most subicular terminals appeared to form asymmetrical synapses. A majority of asymmetrical synapses terminated on spines (67.5%), whereas a smaller fraction of asymmetrical synapses (23.5%) terminated on dendritic shafts. A small fraction of the terminals (7%) had symmetrical features. These symmetrical synapses had an almost equal percentage of spines and dendritic shafts as postsynaptic elements. Labeled synapses on somata or axons were never observed. The findings of this study in conjunction with relevant electrophysiological observations (Jones [1987] Neurosci Left 81:209-214) leads to the conclusion that the subiculo-entorhinal pathway comprises a large excitatory and a smaller inhibitory projection, both making synaptic contacts with presumed principal neurons and interneurons in the entorhinal cortex.

Loss of synaptophysin-like immunoreactivity in the hippocampal formation is an early phenomenon in Alzheimer's disease

We studied a synatophysin-like immunoreactivity in the hippocampal formation of patients with definite Alzheimer's disease, multi-infarct dementia, patients with no evidence of clinical dementia with neuropathological findings fulfilling the criteria of possible Alzheimer's disease, and age-matched nondemented controls. Possible Alzheimer's disease cases were of special interest because they were considered to represent early Alzheimer's disease. We also studied the spatial relationship of synaptophysin-like immunopositivity with amyloid-beta-protein immunopositive senile plaques and anti-paired helical filament immunopositive degenerating neurons locally as well as considering the intrinsic circuits in the hippocampal formation. The synaptophysin-like immunoreactivity was decreased in the hippocampus and the entorhinal cortex in patients with definite and possible Alzheimer's disease but not in multi-infarct dementia patients compared to controls. Equal loss of synapses in possible and definite Alzheimer's disease patients supports the hypothesis that synaptic loss is an early phenomenon in Alzheimer's disease. Unchanged synaptophysin-like immunopositivity in patients with multi-infarct dementia suggests that the loss of synapses is centrally involved in the pathogenesis of Alzheimer's disease and not dementia per se. There was no spatial correlation between loss of synapses and amyloid-beta-protein positive senile plaques. Moreover, we could not find a strict spatial relationship between senile plaques and degenerating neurons. Our results do not support the amyloid cascade hypothesis of Alzheimer's disease that local accumulation of amyloid-beta-protein leads to the loss of synapses.

The substantia nigra pars reticulata, seizures and Fos expression

The induction of the proto-oncogene c-fos has been used extensively to identify spatially distributed neural systems activated by seizures. The substantia nigra pars reticulata (SNpr) has been implicated as a critical structure in neural networks involved in the modulation of seizure expression, yet the SNpr has not been reported to express Fos following seizures induced in a variety of seizure paradigms. In this study we determined whether (1) the temporal characteristics of Fos induction in the SNpr were different than those of other brain areas following kindled seizures, (2) neurons in the SNpr possess the cellular machinery to express Fos, (3) Fos can be induced in SNpr by direct electrical stimulation, and (4) Fos expression is induced in the SNpr following kainate or pilocarpine-induced status epilepticus. Results indicate that Fos is not induced in SNpr at any time point (1-12 h) after kindled seizures, and that serum response factor, a constitutively expressed nuclear protein necessary for Fos expression, is present in SNpr neurons. Results further indicate that Fos expression in the SNpr is induced following either direct electrical stimulation or pilocarpine status, but not status elicited by kainate. We conclude that, in so far as the SNpr represents a critical structure for modulating seizure expression, seizure activity does not represent a sufficient stimulus to induce Fos in SNpr neurons. Further, the neural networks defined by Fos expression following seizure may be incomplete, and should be interpreted conservatively.

Sprouting of central noradrenergic fibers in the dentate gyrus following combined lesions of its entorhinal and septal afferents

Virtually all of the afferents to the hippocampal formation undergo collateral sprouting after removal of adjacent afferent systems. However, the central noradrenergic (NA) afferents, which demonstrate a remarkable propensity for regeneration and sprouting in other regions of the brain, have not been found to sprout in the denervated hippocampal formation. The present study was designed to determine if the pattern of innervation by NA fibers in the dentate gyrus of adult rats can be altered by interruption of the other major afferents. The innervation pattern of NA fibers was examined in the dentate gyrus 4 weeks after removal of the ipsilateral and/or contralateral entorhinal afferents and/or transection of the fimbria-fornix and supracallosal stria. The noradrenergic identity of the fibers was indicated by immunoreactivity for dopamine beta hydroxylase (DBH) and peripheral sympathetic fibers were demonstrated by immunoreactivity for nerve growth factor receptor (NGFr), which did not stain cholinergic fibers in this application. In control brains, the noradrenergic innervation of the dentate molecular layer was light and uniform across the width of the layer. Transection of the perforant path (ipsilateral entorhinal afferents) or ventral hippocampal commissure (contralateral entorhinal afferents) resulted in a significant increase in innervation density in the outer half of the molecular layer, and the combination of these two lesions produced the greatest increase. In those brains with transection of the ipsilateral and contralateral entorhinal afferents, the denervated dentate gyrus had a nearly twofold increase in density of DBH-immunoreactive fibers within the outer half of the molecular layer. These fibers tended to course parallel to the pial surface rather that perpendicular as in control sections. Transection of the fimbria-fornix alone had no affect on the innervation pattern of DBH-ir fibers in the molecular layer. When the fimbria-fornix was transected in combination with both of the other lesions, an overall increase in innervation density occurred, but there was no further increase in the difference between the inner and outer halves of the molecular layer. No NGFr-immunoreactive fibers were observed in the molecular layer in any of the brains, indicating that the DBH-immunoreactive fibers in this region were not of peripheral origin. It is concluded that removal of the ipsi- and contralateral entorhinal afferents to the dentate gyrus results in the sprouting of central NA fibers in the outer half of the molecular layer.

Rapid expression and transport of embryonic N-CAM in dentate gyrus following entorhinal cortex lesion: ultrastructural analysis

Neural cell adhesion molecules are known to be important in axon guidance and synapse formation in the developing brain. The embryonic form of neural cell adhesion molecule (eN-CAM) is reexpressed in the outer molecular layer (OML) of the dentate gyrus following entorhinal cortex (ERC) lesion. Ultrastructural analysis revealed localization of eN-CAM to the membrane of granule-cell dendritic membranes and occasionally axons within the denervated zone. Because eN-CAM is expressed rapidly (within 2 days) after ERC lesion, we were interested in the temporal sequence of expression. Denervated hippocampi (12, 15, 24, and 48 hours post-ERC lesion) were stained with anti-eN-CAM and processed for immunoelectron microscopy. At 12 hours, there was no evidence of staining for eN-CAM. By 15 hours after lesion, membranes of both dendrites and axons throughout the molecular layer exhibited moderate eN-CAM staining, and dendritic cytoplasm was heavily labeled. Twenty-four hours following lesion, plasma membrane staining of eN-CAM on both axons and dendrites had increased in intensity within the OML, whereas membrane eN-CAM staining was diminished in the inner molecular layer (IML), and the intradendritic cytoplasmic staining disappeared. By 48 hours after lesion, eN-CAM staining had disappeared from the IML but remained intense and widely distributed in the OML. These findings suggest a rapid transport of de novo synthesized protein. A generalized reaction appears to occur immediately following denervation, and eN-CAM is up-regulated in the complete expanse of the dendritic membrane, despite the fact that only the OML is denervated.(ABSTRACT TRUNCATED AT 250 WORDS)

Ultrastructural identification of entorhinal cortical synapses in CA1 stratum lacunosum-moleculare of the rat

The goal of the present study was to identify and characterize, at the electron microscopic level, the synapses formed by entorhinal cortical (EC) axons in the hippocampal CA1 stratum lacunosum-moleculare of the adult rat. Phaseolus vulgaris leucoagglutinin was ionotophoresed at various loci throughout the mediolateral and dorsoventral extent of the EC to label EC-CA1 synapses. Virtually all labeled synapses were asymmetric and axospinous. EC axons did not preferentially synapse with any particular type of dendritic spine; rather, EC axons formed synapses with the range of dendritic spine morphologies observed in CA1 s. lacunosum-moleculare. Spines with either perforated or nonperforated postsynaptic densities were contacted by EC axons. Occasionally both a labeled and an unlabeled axon synapsed on a single dendritic spine head. The data are discussed in relation to the morphology of other afferent systems synapsing in s. lacunosum-moleculare and to the physiology of the EC-CA1 system.